Status: Revised Effective Date: 04/14/2024
Doc ID: RBM07-0424.1 Last Review Date: 07/18/2023
Approval and implementation dates for specific health plans may vary. Please consult the applicable health plan for more details.
Clinical Appropriateness Guidelines
Advanced Imaging
Appropriate Use Criteria: Oncologic Imaging
Proprietary
© 2024 Carelon Medical Benefits Management, Inc. All rights reserved.
Table of Contents
Description and Application of the Guidelines
Clinical Appropriateness Framework
Simultaneous Ordering of Multiple Diagnostic or Therapeutic Interventions
Repeat Diagnostic Intervention
Repeat Therapeutic Intervention
Bladder and Urothelial Cancers
Brain and Spinal Cord Malignancy
Cancers of Unknown Primary / Cancers Not Otherwise Specified
Esophageal and Gastroesophageal Junction Cancers
Hepatocellular and Biliary Tract Cancers
Lymphoma – Non-Hodgkin and Leukemia
Penile, Vaginal, and Vulvar Cancers
Cancers of the Pleura, Thymus, Heart, and Mediastinum
Description and Application of the Guidelines
The Carelon Clinical Appropriateness Guidelines (hereinafter “the Carelon Clinical Appropriateness Guidelines” or the “Guidelines”) are designed to assist providers in making the most appropriate treatment decision for a specific clinical condition for an individual. The Guidelines establish objective and evidence-based criteria for medical necessity determinations, where possible, that can be used in support of the following:
- To establish criteria for when services are medically necessary
- To assist the practitioner as an educational tool
- To encourage standardization of medical practice patterns
- To curtail the performance of inappropriate and/or duplicate services
- To address patient safety concerns
- To enhance the quality of health care
- To promote the most efficient and cost-effective use of services
The Carelon guideline development process complies with applicable accreditation and legal standards, including the requirement that the Guidelines be developed with involvement from appropriate providers with current clinical expertise relevant to the Guidelines under review and be based on the most up-to-date clinical principles and best practices. Resources reviewed include widely used treatment guidelines, randomized controlled trials or prospective cohort studies, and large systematic reviews or meta-analyses. Carelon reviews all of its Guidelines at least annually.
Carelon makes its Guidelines publicly available on its website. Copies of the Guidelines are also available upon oral or written request. Additional details, such as summaries of evidence, a list of the sources of evidence, and an explanation of the rationale that supports the adoption of the Guidelines, are included in each guideline document.
Although the Guidelines are publicly available, Carelon considers the Guidelines to be important, proprietary information of Carelon, which cannot be sold, assigned, leased, licensed, reproduced or distributed without the written consent of Carelon.
Carelon applies objective and evidence-based criteria, and takes individual circumstances and the local delivery system into account when determining the medical appropriateness of health care services. The Carelon Guidelines are just guidelines for the provision of specialty health services. These criteria are designed to guide both providers and reviewers to the most appropriate services based on a patient’s unique circumstances. In all cases, clinical judgment consistent with the standards of good medical practice should be used when applying the Guidelines. Guideline determinations are made based on the information provided at the time of the request. It is expected that medical necessity decisions may change as new information is provided or based on unique aspects of the patient’s condition. The treating clinician has final authority and responsibility for treatment decisions regarding the care of the patient and for justifying and demonstrating the existence of medical necessity for the requested service. The Guidelines are not a substitute for the experience and judgment of a physician or other health care professionals. Any clinician seeking to apply or consult the Guidelines is expected to use independent medical judgment in the context of individual clinical circumstances to determine any patient’s care or treatment.
The Guidelines do not address coverage, benefit or other plan specific issues. Applicable federal and state coverage mandates take precedence over these clinical guidelines, and in the case of reviews for Medicare Advantage Plans, the Guidelines are only applied where there are not fully established CMS criteria. If requested by a health plan, Carelon will review requests based on health plan medical policy/guidelines in lieu of the Carelon Guidelines. Pharmaceuticals, radiotracers, or medical devices used in any of the diagnostic or therapeutic interventions listed in the Guidelines must be FDA approved or conditionally approved for the intended use. However, use of an FDA approved or conditionally approved product does not constitute medical necessity or guarantee reimbursement by the respective health plan.
The Guidelines may also be used by the health plan or by Carelon for purposes of provider education, or to review the medical necessity of services by any provider who has been notified of the need for medical necessity review, due to billing practices or claims that are not consistent with other providers in terms of frequency or some other manner.
General Clinical Guideline
Clinical Appropriateness Framework
Critical to any finding of clinical appropriateness under the guidelines for a specific diagnostic or therapeutic intervention are the following elements:
- Prior to any intervention, it is essential that the clinician confirm the diagnosis or establish its pretest likelihood based on a complete evaluation of the patient. This includes a history and physical examination and, where applicable, a review of relevant laboratory studies, diagnostic testing, and response to prior therapeutic intervention.
- The anticipated benefit of the recommended intervention is likely to outweigh any potential harms, including from delay or decreased access to services that may result (net benefit).
- Widely used treatment guidelines and/or current clinical literature and/or standards of medical practice should support that the recommended intervention offers the greatest net benefit among competing alternatives.
- There exists a reasonable likelihood that the intervention will change management and/or lead to an improved outcome for the patient.
Providers may be required to submit clinical documentation in support of a request for services. Such documentation must a) accurately reflect the clinical situation at the time of the requested service, and b) sufficiently document the ordering provider’s clinical intent.
If these elements are not established with respect to a given request, the determination of appropriateness will most likely require a peer-to-peer conversation to understand the individual and unique facts that would justify a finding of clinical appropriateness. During the peer-to-peer conversation, factors such as patient acuity and setting of service may also be taken into account to the extent permitted by law.
Simultaneous Ordering of Multiple Diagnostic or Therapeutic Interventions
Requests for multiple diagnostic or therapeutic interventions at the same time will often require a peer-to-peer conversation to understand the individual circumstances that support the medical necessity of performing all interventions simultaneously. This is based on the fact that appropriateness of additional intervention is often dependent on the outcome of the initial intervention.
Additionally, either of the following may apply:
- Current literature and/or standards of medical practice support that one of the requested diagnostic or therapeutic interventions is more appropriate in the clinical situation presented; or
- One of the diagnostic or therapeutic interventions requested is more likely to improve patient outcomes based on current literature and/or standards of medical practice.
Repeat Diagnostic Intervention
In general, repeated testing of the same anatomic location for the same indication should be limited to evaluation following an intervention, or when there is a change in clinical status such that additional testing is required to determine next steps in management. At times, it may be necessary to repeat a test using different techniques or protocols to clarify a finding or result of the original study.
Repeated testing for the same indication using the same or similar technology may be subject to additional review or require peer-to-peer conversation in the following scenarios:
- Repeated diagnostic testing at the same facility due to technical issues
- Repeated diagnostic testing requested at a different facility due to provider preference or quality concerns
- Repeated diagnostic testing of the same anatomic area based on persistent symptoms with no clinical change, treatment, or intervention since the previous study
- Repeated diagnostic testing of the same anatomic area by different providers for the same member over a short period of time
Repeat Therapeutic Intervention
In general, repeated therapeutic intervention in the same anatomic area is considered appropriate when the prior intervention proved effective or beneficial and the expected duration of relief has lapsed. A repeat intervention requested prior to the expected duration of relief is not appropriate unless it can be confirmed that the prior intervention was never administered. Requests for on-going services may depend on completion of previously authorized services in situations where a patient’s response to authorized services is relevant to a determination of clinical appropriateness.
Oncologic Imaging
General Information/Overview
Scope
These guidelines address advanced imaging for oncologic conditions in both adult and pediatric populations. For interpretation of the Guidelines, and where not otherwise noted, “adult” refers to persons age 19 and older, and “pediatric” refers to persons age 18 and younger. Where separate indications exist, they are specified as Adult or Pediatric. Where not specified, indications and prerequisite information apply to persons of all ages. In addition, these guidelines for oncologic conditions will address the following aspects of the care continuum:
- Screening for cancer
- Diagnosis of breast and prostate cancer
- Diagnostic workup, management, and surveillance of documented malignancy: typically requires biopsy unless imaging findings are an accepted alternative to biopsy (hepatobiliary cancer, brain cancer or spinal cord cancer) OR are highly suspicious for cancer when biopsy is contraindicated or non-diagnostic.
For all other imaging related to tumor evaluation, please refer to the Carelon Guidelines for Advanced Imaging of the anatomic region of concern.
See the Coding section for a list of modalities included in these guidelines.
Technology Considerations
Advanced imaging for oncologic conditions includes both anatomic and functional modalities. Judicious use of advanced imaging is important to minimize risk and to avoid duplication of information. Testing should be performed in a stepwise fashion, with follow-up imaging studies performed based on the need for information not provided by the initial study.
Computed tomography (CT) and magnetic resonance imaging (MRI) are the most widely used modalities to visualize anatomic detail. CT provides rapidly obtained, high-resolution images that yield information on lesion morphology, size, and location. CT is less prone to motion artifact than MRI, and is useful for evaluation of bones and soft tissue. Improved techniques such as multi-slice technology and enhanced image processing refine image quality and resolution. Helical CT may be preferable to conventional axial CT for oncologic imaging due to increased speed of image acquisition and ability to perform computed tomography angiography (CTA), which is useful to assess vascular structures associated with tumors. Disadvantages of CT include exposure to ionizing radiation and risks associated with infusion of iodinated contrast media, including allergic reactions or renal compromise. MRI provides similar information to CT; however, image acquisition is slower and thus more prone to motion artifact. MRI has higher resolution and is better able to detect subtle abnormalities in soft tissue. For this reason, it is often preferable for visualizing infiltrative tumors. The term MRI spine in these guidelines specifically references MRI cervical spine, thoracic spine, and/or lumbar spine. Magnetic resonance angiography (MRA) is the MR analog of CTA and is also useful to assess tumor blood supply. The presence of implantable devices such as pacemakers or defibrillators, a potential need for sedation in pediatric patients, and claustrophobia are the main limitations of MRI. Infusion of gadolinium may also confer an unacceptable risk in persons with advanced renal disease.
Multiparametric MRI (mpMRI) of the prostate utilizes detailed anatomical imaging (T2-weighted imaging) as well as at least two functional imaging sequences (diffusion-weighted imaging, diffusion weighted imaging with apparent diffusion coefficient, and/or dynamic intravenous contrast-enhanced imaging) for detailed visualization and characterization of the prostate.
Magnetic resonance spectroscopy (MRS) provides a biochemical profile of metabolic constituents in tissues and may be used as an adjunct in cases where standard MRI fails to distinguish between diseased and healthy tissue. In oncologic imaging, it is used primarily to differentiate between residual brain tumor and necrotic tissue following treatment.
Positron emission tomography (PET) or positron emission tomography with computed tomography (PET-CT) (collectively PET/CT) provide functional information about metabolic activity.
PET imaging requires the use of radiotracers. Carelon guidelines cover PET imaging performed with any Food and Drug Administration (FDA) approved radiotracer. The most common radiotracer is fluorodeoxyglucose (FDG) and all references to PET or PET-CT in this guideline assume use of FDG. PET imaging is sometimes performed using non FDG radiotracers.
PET utilizes a radiotracer, typically 2-(fluorine-18) fluoro-2-deoxy-D-glucose (fluorodeoxyglucose or FDG), which accumulates in areas of high metabolic activity such as tumor cells. The utility of PET may be improved by overlaying the areas of high uptake with CT images in order to provide anatomic detail (PET-CT). PET/CT is most useful in detecting tumors with a high metabolic rate; tumors that are indolent or slow-growing are less likely to be detected using this modality. The lack of specificity for oncologic processes also results in FDG uptake occurring in benign etiologies such as physiologic lymphoid tissue uptake, infection, and benign tumors. Therefore, radiotracers have been in development that target cancer-specific cell surface transporters. 11C-choline and 18F-fluciclovine (Axumin) were approved by the U.S. Food and Drug Administration (FDA) in 2012 and 2016, respectively, for the detection of suspected prostate cancer recurrence. 68Ga-dotatate (NETSPOT) was approved by the FDA in 2016 as the first in-class PET/CT radiotracer for detection of well-differentiated neuroendocrine tumors (NET).
Where evidence based specific criteria for a particular non-FDG radiotracer exists, it will be called out in the Carelon guidelines as a modifier to PET or PET-CT. See, for example, 18F Fluciclovine PET/CT or 11C Choline PET/CT.
Where evidence based specific criteria for a particular non-FDG radiotracer does not exist, the medical necessity criteria to be applied in adjudicating the use of the non-FDG radiotracer will be the Clinical Appropriateness Framework.
There are many radiotracers currently under development which target specific tumor types, and several are already in clinical use. As these continue to be evaluated in clinical practice, the use of this technology is expected to evolve and grow.
Definitions
Phases of the care continuum are broadly defined as follows:
- Screening – testing in the absence of an established or clinically suspected diagnosis
- Diagnosis – testing based on a reasonable clinical suspicion of a particular condition or disorder
- Diagnostic Workup – initial staging of documented malignancy
- Management – testing to direct therapy of an established condition, which may include preoperative or postoperative imaging, or imaging performed to evaluate the response to nonsurgical intervention. In oncologic imaging, management applies to patients with measurable disease and to imaging performed before or after planned treatment intervention, therapy response, restaging or clinically suspected recurrence.
- Surveillance – periodic assessment following completion of therapy. In oncologic imaging, surveillance applies to asymptomatic patients in remission and/or without measurable disease
Other terms used in this guideline:
- Documented malignancy: Established cancer diagnosis, usually by biopsy. Biopsy may not be required when imaging findings are an accepted alternative (for instance hepatobiliary cancer, brain cancer or spinal cord cancer) OR are highly suspicious for cancer when biopsy is contraindicated or nondiagnostic.
- Indicated – Evidence supports use and is considered medically necessary and consistent with Carelon’s clinical appropriateness framework. Scenarios that follow “Indicated” are required by the clinical guideline. Scenarios that follow “Indicated” with a note are suggested but not required to establish medical necessity.
- Not indicated – Evidence does not support use and/or is not considered medically necessary and consistent with Carelon’s clinical appropriateness framework
- Indeterminate lesion – focal mass or mass-like finding identified on prior imaging that has not been confidently diagnosed as either benign or malignant based on imaging appearance and/or biopsy
- Cannot be performed or is nondiagnostic – applies when the test:
- Is positive or indeterminate for clinically significant pathology when the information provided about the abnormality by the test is not sufficient to direct subsequent management
- Is negative when the negative likelihood ratio of the test is both insufficient to confidently exclude the absence of suspected disease and unable to direct subsequent management. This typically applies in scenarios with moderate to high clinical pretest probability with negative testing or low pretest probability with clear evidence for net benefit
- Has been previously nondiagnostic because of a persistent clinical factor (e.g., body habitus, immobility) that is very likely to make retesting nondiagnostic as well
- Cannot be performed due to a medical contraindication (e.g., contrast nephrotoxicity, allergy, or in highly radiation sensitive populations such as pediatrics and pregnancy) or reasonable unavailability related to lack of local expertise or service availability.
- Standard or conventional imaging: Refers to imaging that does not require a PET/CT. Depending on the clinical scenario and individual patient circumstances, this may include computed tomography, magnetic resonance imaging, ultrasound and/or scintigraphy.
- Clinical suspicion: Documented signs, symptoms, lab and/or other diagnostic test results that sufficiently increase the pre-test likelihood of disease to warrant further advanced imaging evaluation to direct management. Includes symptom directed staging.
Statistical terminology
- Confidence interval (CI) – range of values which is likely to contain the cited statistic. For example, 92% sensitivity (95% CI, 89%-95%) means that, while the sensitivity was calculated at 92% on the current study, there is a 95% chance that, if a study were to be repeated, the sensitivity on the repeat study would be in the range of 89%-95%.
- Diagnostic accuracy – ability of a test to discriminate between the target condition and health. Diagnostic accuracy is quantified using sensitivity and specificity, predictive values, and likelihood ratios.
- Hazard ratio – odds that an individual in the group with the higher hazard reaches the outcome first. Hazard ratio is analogous to odds ratio and is reported most commonly in time-to-event analysis or survival analysis. A hazard ratio of 1 means that the hazard rates of the 2 groups are equivalent. A hazard ratio of greater than 1 or less than 1 means that there are differences in the hazard rates between the 2 groups.
- Likelihood ratio – ratio of an expected test result (positive or negative) in patients with the disease to an expected test result (positive or negative) in patients without the disease. Positive likelihood ratios, especially those greater than 10, help rule in a disease (i.e., they substantially raise the post-test probability of the disease, and hence make it very likely and the test very useful in identifying the disease). Negative likelihood ratios, especially those less than 0.1, help rule out a disease (i.e., they substantially decrease the post-test probability of disease, and hence make it very unlikely and the test very useful in excluding the disease).
- Odds ratio – odds that an outcome will occur given a particular exposure, compared to the odds of the outcome occurring in the absence of that exposure. An odds ratio of 1 means that the exposure does not affect the odds of the outcome. An odds ratio greater than 1 means that the exposure is associated with higher odds of the outcome. An odds ratio less than 1 means that the exposure is associated with lower odds of the outcome.
- Predictive value – likelihood that a given test result correlates with the presence or absence of disease. Positive predictive value is defined as the number of true positives divided by the number of test positives. Negative predictive value is defined as the number of true negatives divided by the number of test negative patients. Predictive value is dependent on the prevalence of the condition.
- Pretest probability – probability that a given patient has a disease prior to testing. May be divided into very low (less than 5%), low (less than 20%), moderate (20%-75%), and high (greater than 75%) although these numbers may vary by condition.
- Relative risk – probability of an outcome when an exposure is present relative to the probability of the outcome occurring when the exposure is absent. Relative risk is analogous to odds ratio; however, relative risk is calculated by using percentages instead of odds. A relative risk of 1 means that there is no difference in risk between the 2 groups. A relative risk of greater than 1 means that the outcome is more likely to happen in the exposed group compared to the control group. A relative risk less than 1 means that the outcome is less likely to happen in the exposed group compared to the control group.
- Sensitivity – conditional probability that the test is positive, given that the patient has the disease. Defined as the true positive rate (number of true positives divided by the number of patients with disease). Excellent or high sensitivity is usually greater than 90%.
- Specificity – conditional probability that the test is negative, given that the patient does not have the disease. Defined as the true negative rate (number of true negatives divided by the number of patients without the disease). Excellent or high specificity is usually greater than 90%.
Staging systems referred to in the Guidelines:
- AJCC staging1 – classification system developed by the American Joint Committee on Cancer for describing the extent of disease progression in cancer patients. It utilizes the TNM scoring system which takes into account Tumor size, the lymph Nodes affected, and Metastases.
- Ann Arbor staging2 – system for staging Hodgkin lymphoma and non-Hodgkin lymphoma based on location of malignant tissue and on systemic symptoms due to the lymphoma.
- Deauville criteria3 – internationally accepted response assessment criteria utilizing a five-point scoring system for the FDG avidity of a Hodgkin lymphoma or non-Hodgkin lymphoma tumor mass as seen on FDG-PET.
- FIGO system4 – a cancer staging and classification system for gynecologic malignancies developed by the International Federation of Gynecology and Obstetrics.
- Lugano classification5 – staging and response assessment system used for patients with non-Hodgkin lymphoma based on the Ann Arbor staging system. The Lugano criteria takes into account FDG-PET in response assessment.
- RECIST6 (response evaluation criteria in solid tumors) – set of published rules jointly developed by the European Organization for Research and Treatment of Cancer, National Cancer Institute of the U.S., and the National Cancer Institute of Canada Clinical Trials Group to assess tumor response during treatment.
Clinical Indications
The following sections include indications for which advanced imaging is considered medically necessary, along with prerequisite information and supporting evidence where available. Indications, diagnoses, or imaging modalities not specifically addressed are considered not medically necessary.
Indications are presented in the following sections by tumor type.
Cancer Screening
Advanced imaging is indicated for the following screening scenarios.
Breast cancer screening
Annual MRI breast is indicated in ANY of the following scenarios:
- Individuals who received radiation to the chest between ages 10 and 30
- Individuals with a genetic predisposition to breast cancer, in either themselves or a first-degree relative, which may include ANY of the following:
- Bannayan-Riley-Ruvalcaba syndrome
- BRCA1 and BRCA2 mutations
- Cowden syndrome
- Li-Fraumeni syndrome (TP53)
- Individuals known to have ANY of the following established genetic mutations:
- ATM
- BARD1
- CDH1
- CHEK2
- NF-1
- PALB2
- PTEN
- RAD51C or RAD51D
- STK11 (Peutz-Jeghers syndrome)
- History of lobular carcinoma in situ (LCIS), atypical ductal hyperplasia (ADH), or atypical lobular hyperplasia (ALH) on biopsy
- Lifetime risk of 20% or greater as defined by the GAIL model, BOADICEA, BRCAPRO, Claus,Tyrer-Cuzick or other models that are largely dependent on family history
Rationale
While several recent studies have shown breast MRI to improve cancer detection in women with a personal history of breast cancer, the false positive rate remains extremely high, with one study reporting a false positive rate of 61%.7, 8 False positives are commonly seen in average-risk women screened for breast cancer with MRI, particularly those with dense breasts.9 In a systematic review for the U.S. Preventive Services Task Force, the authors concluded that the effect of supplemental screening on breast cancer outcomes remains unclear.10 However, additional imaging with MRI breast has been found to be beneficial in higher-risk groups.11-17 The American College of Radiology Appropriate Use Criteria for supplemental screening based on breast density note that there is limited data regarding the use of MRI for screening average-risk patients with dense breast tissue. They report some evidence supporting MRI for supplemental screening of patients with dense breast tissue and intermediate risk for breast cancer, specifically in patients with a personal history of breast cancer or LCIS, though those studies included all breast densities.The ACR recommendation is for annual surveillance MRI in patients with dense breasts and a personal history of breast cancer as well as those diagnosed before age 50.18 Additionally, the ACR recommends MRI for breast cancer screening in transmasculine patients age 25 to 30 or older and who are at high risk for breast cancer (based on genetic predisposition, first-degree relative with genetic predisposition, chest irradiation between age 10 and 30 years, or 20% or greater lifetime risk of breast cancer).19
MRI mammography has been shown to be more sensitive but less specific than mammography.11, 20-23 In a review of 11 prospective, nonrandomized studies comparing screening MRI to mammography in women at high risk for breast cancer, the sensitivity of MRI was higher than mammography: 77% vs 39%, respectively. Similar to previous studies, the specificity of MRI was lower than mammography: 86% vs 95%. Comparing diagnostic odds ratios (positive defined as BI-RADS 3 or higher), the diagnostic odds ratio was 14.7 (6.1-35.6) for mammogram, 18.3 (11.7-28.7) for MRI, and 45.9 (17.5-120.9) for the MRI-mammogram combination. The combined modalities were superior in terms of sensitivity (94%) and specificity (77%) to either modality alone.24 A prospective randomized trial showed that when MRI was added to screening ultrasound and mammography for high-risk patients, the sensitivity was 100% as compared to 44% for mammography and ultrasound alone.25 Benefits in survival may also be seen, particularly in patients with BRCA1 and BRCA2 mutations.26, 27 In a prospective trial using both mammography and MRI breast for screening of high-familial-risk women for breast cancer (N = 649), 19 cancers were detected by MRI only, 6 by mammography only, and 8 by both modalities combined, with 2 found on serial imaging. In patients with lobular carcinoma in situ and atypical hyperplasia, MRI was significantly more sensitive than mammography, but resulted in 3 times more benign biopsies.28
Carelon Oncologic Imaging guidelines pertaining to breast cancer screening are in concordance with the National Comprehensive Cancer Network, American Cancer Society, and American College of Radiology recommendations.29-31
Colorectal cancer screening
CT colonography (CTC) is indicated in ANY of the following scenarios:
- Screening CT colonography is indicated for average risk individuals* as an alternative to conventional colonoscopy at 5-year intervals, beginning at age 45
*Average risk:
– No personal history of colonic adenoma, serrated sessile polyp (SSP), or colorectal cancer (CRC)
– No personal history of inflammatory bowel disease
– Negative first-degree family history for CRC, confirmed advanced adenoma (i.e. high-grade dysplasia, ≥ 1 cm, villous or tubulovillous histology or an advanced SSP)
- Diagnostic CT colonography is indicated when ANY of the following conditions are present:
- Coagulopathy
- Complications from prior fiberoptic colonoscopy
- Diverticulitis with increased risk of perforation
- Failed or incomplete fiberoptic colonoscopy of the entire colon, due to inability to pass the colonoscope proximally (may be secondary to obstructing neoplasm, spasm, redundant colon, altered anatomy or scarring from previous surgery, stricture, or extrinsic compression)
- Increased sedation risk, such as chronic obstructive pulmonary disease or previous adverse reaction to anesthesia
- Known colonic obstruction when standard fiberoptic colonoscopy is contraindicated
- Lifetime or long-term anticoagulation with increased patient risk if discontinued
- Following screening CTC demonstrating 1-2 polyps which are 6-9 mm in size, for 3 year follow-up CTC
Rationale
CT Colonography (CTC) has the advantages of being noninvasive and not requiring sedation, but carries the risk of radiation exposure and detection of potentially clinically insignificant extracolonic findings; a positive finding by CTC still requires subsequent optical colonoscopy evaluation. However, CTC may be an acceptable screening alternative for many individuals at average risk for colorectal cancer. In the National CT Colonography trial (ACRIN 6664) organized by the American College of Radiology (ACR) Imaging Network, 2531 participants underwent CTC followed by traditional optical colonoscopy.32 CTC detected 90% of patients who had lesions measuring 10 mm of larger found by colonoscopy (sensitivity 90%, specificity 86%). In a review comparing CTC and optical colonoscopy, both screening strategies resulted in comparable detection rates for advanced neoplasia (3.2% for CTC, 3.4% for colonoscopy), although the numbers of polypectomies and complications were considerably higher in the optical colonoscopy group.33 A population based study of 93 individuals with one or two polyps (6-9 mm) examined with 3 year surveillance CTC suggested that polyps of this size are unlikely to progress to advanced neoplasia within 3 years.34
Carelon Oncologic Imaging guidelines pertaining to colorectal cancer screening are in concordance with the U.S. Preventive Services Task Force and National Comprehensive Cancer Network recommendations.35, 36
Lung cancer screening
Annual low-dose CT is indicated when ALL of the following criteria are met:
- Age equal to or greater than 50 and less than or equal to 80
- 20 or greater pack-year history* of cigarette smoking (current smoker, or quit date within the past 15 years), or established asbestosis-related lung disease
- No signs or symptoms suggestive of underlying cancer
- No health problems that would be expected to substantially limit life expectancy or the ability to undergo an intervention with curative intent
*One pack-year of smoking equals smoking 1 pack (20 cigarettes) per day for 1 year or 7300 cigarettes annually.
Rationale
Low dose CT (LDCT) is an annual lung cancer screening exam which utilizes specific protocols to image the lungs at an ultra-low dose of radiation. Screening CT for lung cancer can be beneficial; however, these benefits must be weighed against the risks of radiation exposure, over diagnosis, and false positives.37 Previous studies have shown that screening with standard chest X-rays does not reduce the mortality rate from lung cancer. A 2011 National Cancer Institute-sponsored National Lung Screening Trial showed that people ages 55 to 74 with a history of heavy smoking were 20% less likely to die from lung cancer if they were screened with LDCT than with standard screening chest X-rays,38 but those screened also experience higher overall rates of false positive results, invasive procedures, and serious complications.39
In 2021, the U.S. Preventive Services Task Force released the following updated recommendation summary: “The USPSTF [U.S. Preventive Services Task Force] recommends annual screening for lung cancer with LDCT in adults aged 50 to 80 years who have a 20 pack-year smoking history and currently smoke or have quit within the past 15 years. Screening should be discontinued once a person has not smoked for 15 years or develops a health problem that substantially limits life expectancy or the ability or willingness to have curative lung surgery.”40 (Note: Centers for Medicare & Medicaid Services (CMS) requests follow national coverage determination (NCD) eligibility criteria, for which the screening upper age limit is 77 years). One multi-center study also found that in subjects with past asbestos exposure, the presence of smoking history, fibrotic plus emphysema changes, and pleural effusion were correlated with an increased prevalence of lung cancer. 41
Carelon Oncologic Imaging guidelines pertaining to lung cancer screening are in concordance with the American Cancer Society, American College of Chest Physicians, American Society of Clinical Oncology, and U.S. Preventive Services Task Force recommendations.37, 40, 42
Pancreatic cancer screening
Annual CT or MRI (preferred) Abdomen is indicated as an alternative to endoscopic ultrasound in ANY of the following scenarios:
- Peutz-Jeghers syndrome (LKB1/STK11 mutations), starting at age 30-35 or 10 years earlier than youngest affected relative
- Familial Atypical Multiple Melanoma and Mole syndrome (FAMMM; CDKN2A, p16 mutation), starting at age 40 or 10 years earlier than youngest affected relative
- BRCA1, BRCA2, PALB2, ATM, EPCAM, TP53, or MLH1/MSH2/MSH6 (Lynch syndrome) gene mutation and at least one first- or second- degree relative* with pancreatic cancer, starting at age 50 or 10 years earlier than the youngest affected relative
- Hereditary pancreatitis gene mutation (PRSS1 or SPINK1) with personal or family history of recurrent acute pancreatitis, starting at age 40 or 20 years after the initial onset of pancreatitis
- Family history of pancreatic cancer, starting at age 50 or 10 years earlier than the youngest affected relative in EITHER of the following:
- At least two first-degree relatives*
- At least three first- and/or second-degree relatives*
*Relative(s) with exocrine pancreatic cancer, on the same side of the family as the gene mutation or history of pancreatic cancer
Rationale
Emerging data regarding the efficacy of pancreatic cancer screening in select individuals has largely been limited to individuals with known pathogenic/likely pathogenic germline variants in a pancreatic cancer susceptibility gene (as listed above) or those with strong family history, utilizing contrast MRI/MRCP and/or EUS. Potential benefits of screening include a suggestion of tumor downgrading and improved mortality, compared to historical data, with 75%-90% of screen-detected malignancy being surgically resectable at diagnosis.43, 44 Longer term studies are needed to determine if this downstaging translates to improved survival, as evidence suggests that long term survival is common in patients presenting with stage I sporadic ductal adenocarcinoma, and further data is needed to better define the threshold for biopsy and surgical intervention given the frequency with which pancreatic abnormalities are seen (42% of high risk individuals in one study had at least one pancreatic mass/cyst and/or duct abnormality).45
Carelon Oncologic Imaging guidelines pertaining to pancreatic cancer screening are based on the National Comprehensive Cancer Network.46
Hepatocellular carcinoma (HCC) screening
CT or MRI Abdomen is indicated as an alternative to abdominal ultrasound in patients with Hepatitis B or cirrhosis (any etiology) when ultrasound cannot be performed or is nondiagnostic.
Rationale
Hepatocellular cancer (HCC) is the sixth-most common cancer in the world and in the United States, and the third leading cause of cancer-related mortality as of 2020.47 Pre-existing cirrhosis is found in more than 80% of individuals diagnosed with HCC. Risk factors for HCC include hepatitis B and C virus, alcohol, non-alcoholic fatty liver disease (NAFLD), as well as less prevalent conditions such as hereditary hemochromatosis and Wilson’s disease. Hepatitis B is correlated with the development of HCC even in the absence of cirrhosis, as DNA integration occurring in most cases of chronic infection induces genetic damage.
The American Association for the Study of Liver Diseases (AASLD) recommends screening for HCC with abdominal ultrasound every six months in those with cirrhosis (any etiology) or hepatitis B (also National Comprehensive Cancer Network category 2A recommendation).47, 48 However, ultrasound may be limited due to technical factors like morbid obesity, obscuring intestinal gas, chest wall deformity, or the degree of liver disease itself (advanced cirrhosis causes distortion and heterogeneity of the hepatic parenchyma), resulting in poor liver visualization and lowered sensitivity for detection of early HCC.49-52 The AASLD notes that CT or MRI may be utilized “in select patients with a high likelihood of having an inadequate US or if US is attempted but inadequate.”
Carelon Oncologic Imaging guidelines pertaining to HCC screening are based on the National Comprehensive Cancer Network (NCCN) and the American Association for the Study of Liver Diseases (AASLD) guidelines.47, 48
Cancer screening, not otherwise specified
CT or MRI is indicated for cancer screening currently categorized as a 2A recommendation from the National Comprehensive Cancer Network (NCCN).
Rationale
Carelon will adopt all level 1 or 2A single modality and/or preferred modality and frequency recommendations published by the National Comprehensive Cancer Network (NCCN), including any imaging recommended for cancer screening not addressed in other sections.
Anal Cancer
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented anal cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
CT chest CT abdomen and pelvis | Indicated | Indicated (note: DRE exam of choice) | Indicated (note: especially useful in T3-4 tumors in first 3 years) |
MRI pelvis | Indicated | Indicated | Indicated |
FDG-PET/CT | Indicated when standard imaging cannot be performed or is nondiagnostic for metastatic disease |
| Not indicated |
Note: PET/CT does not replace a diagnostic CT scan.
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Anal cancer, which arises from the cells of the anal canal or anal margin, accounts for 3% of all gastrointestinal cancers. The most common histological subtype is squamous cell carcinoma. Risk factors for developing anal cancer include high-risk sexual behavior, tobacco use, and infection with human papillomavirus or human immunodeficiency virus. The most common presentation is rectal bleeding or pain.
DIAGNOSTIC WORKUP
Anal cancer is staged using the American Joint Committee on Cancer TNM system. The vast majority of patients with locoregional disease will undergo concurrent chemoradiation treatment regardless of tumor or nodal staging. Evaluation of pelvic lymph nodes with CT or MRI Pelvis is recommended by the NCCN for initial staging, as is CT of the Chest and Abdomen to assess disseminated disease (since veins of the anal region are part of the venous network associated with systemic circulation).53 The European Society for Medical Oncology (ESMO) also recommends MRI pelvis and CT chest, abdomen, and pelvis for initial staging, and states that PET-CT may be considered, though they note that further research is needed to validate its utility as a supplement to conventional imaging.54
PET/CT can be used to verify staging before treatment, which may alter the radiation plan for curative combined modality therapy. PET/CT has been reported to be useful in the evaluation of pelvic lymph nodes, even when appearing normal-sized by CT. A meta-analysis of 12 studies found that CT and PET had a sensitivity of 60% and 99%, respectively, for the detection of primary disease. Compared with conventional imaging, PET upstaged 15% and downstaged another 15% of nodal disease. This led to a change in nodal staging in 28% and TNM staging in 41% of patients.55 A more recent meta-analysis published by Mahmud et al. found a pooled sensitivity of 99% for PET or PET/CT and 67% for CT scan alone. PET imaging also had a sensitivity of 93% and specificity of 76% for detecting nodal disease. A total of 5.1-37.5% of patients were upstaged and 8.2-26.7% were downstaged, with 12.5-59.3% of patients requiring treatment changes. However, the majority of the changes in treatment were in radiation planning.56
MANAGEMENT
Following completion of concurrent chemoradiation therapy, the National Comprehensive Cancer Network (NCCN) recommends that initial follow up of anal cancer include digital rectal exam 8-12 weeks after treatment. Patients with persistent disease but without evidence of progression may be managed with close follow-up for up to 6 months to ensure complete response after completion of radiation and chemotherapy. In the event of biopsy-proven progressive disease or recurrence, reimaging can be performed with conventional advanced imaging or PET/CT scan when salvage surgery is indicated.53 The 5-year overall survival was 64% in a small study of 39 patients treated with radical salvage surgery.57 ESMO recommends the use of CT chest, abdomen, and pelvis at diagnosis and follow-up. They state that while PET/CT may be considered to assist in radiation therapy planning, there is insufficient evidence to recommend routine PET/CT for assessment of treatment response or follow-up.54
SURVEILLANCE
Local recurrence of early stage disease is detectable by exam or anoscopy. For patients at high risk for recurrence (locally advanced [T3/T4], inguinal node positive, or locally persistent/progressive/recurrent anal squamous cell cancer), surveillance may include CT chest, CT or MRI abdomen/pelvis with contrast annually for a duration of 3 years per the NCCN guidelines.53 However, due to the lack of prospective trials and because most recurrences are locoregional, the European Society of Medical Oncology does not endorse routine advanced imaging.54
Bladder and Urothelial Cancers
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of documented urothelial cancers of the bladder, renal pelvis, ureter, prostate and urethra.
Bladder/Urothelial Cancers: Non-muscle Invasive
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest | Indicated (note: not generally needed with non-muscle invasive bladder cancer) | Indicated (note: not generally needed with non-muscle invasive bladder cancer) | Indicated (note: not generally needed with non-muscle invasive bladder cancer) |
CT abdomen and pelvis* | Indicated | Indicated | Indicated (note: for baseline imaging after completion of planned treatment and especially useful for high risk patients) |
MRI pelvis | Indicated for local staging of sessile or high-grade tumors (as an adjunct to CT imaging) | Not indicated | Not indicated |
FDG-PET/CT | Not indicated | Not indicated | Not indicated |
*Includes CT urography (CTU) (CT of the abdomen and pelvis without and with IV contrast with excretory imaging).
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity). MR urography (MRU, requested as MRI Abdomen/MRI Pelvis) may be appropriate in patients with poor renal function or iodinated CT contrast allergy but with GFR >30 and no acute renal failure.
Bladder/Urothelial Cancers: Muscle Invasive
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest | Indicated (note: chest X-ray is sufficient in most cases. CT especially useful when chest X-ray is abnormal OR in high-risk patients (T3/T4 disease or as stage T2 with hydronephrosis or high-risk histological features)) | Indicated | Indicated |
CT abdomen and pelvis* | Indicated | Indicated | Indicated (note: especially useful for first 5 years) |
MRI pelvis | Indicated for local staging (as an adjunct to CT imaging) | Not indicated | Not indicated |
FDG-PET/CT |
|
| Not indicated |
*Includes CT urography (CTU) (CT of the abdomen and pelvis without and with IV contrast with excretory imaging).
Note: PET is not indicated in bladder tumors which have not invaded the muscle (stage < cT2).
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity). MR urography (MRU, requested as MRI Abdomen/MRI Pelvis) may be appropriate in patients with poor renal function or iodinated contrast allergy but with GFR >30 and no acute renal failure.
Rationale
Cancers of the urinary tract, including renal pelvis, ureter, bladder, and urethra, comprise the sixth most common cancer in men and women. The most common histology of urinary tract cancer is urothelial carcinoma (also called transitional cell carcinoma), accounting for 90% of tumors. Risk factors for urothelial cancer include tobacco use and occupational exposure to carcinogens. The most common presentation of urinary tract cancer includes hematuria, pain from local or metastatic disease, and voiding symptoms.
DIAGNOSTIC WORKUP
Staging utilizes the American Joint Committee on Cancer TNM system. Bladder cancer is further classified as muscle invasive or non-muscle invasive. Imaging is used to further assess the local tumor, lymph nodes, and distant metastases.
CT abdomen and pelvis with excretory imaging can be used for staging of invasive locally advanced bladder cancer.58 Although CT provides adequate visualization of tumors and allows for assessment of the upper urinary tract, it does not have the same capability as MRI pelvis for local staging of bladder cancer. Compared to CT, MRI has the added benefit of high soft tissue contrast and direct multiplanar imaging capabilities, allowing for accurate tumor evaluation and better visualization of the bladder dome, trigone, and adjacent structures. The reported accuracy of MRI in overall staging of bladder cancer varies from 60% to 85%, whereas local staging ranges from 73% to 96%.59 Both CT and MRI have comparable accuracy for staging lymph nodes: 73% to 90%.60 The European Society for Medical Oncology (ESMO) recommends cross-sectional upper tract imaging with either CT or MR urography to assess for concurrent upper tract urothelial carcinoma. They recommend that, in patients with invasive disease, regional and distant staging should be done with CT chest and either CT or MRI abdomen/pelvis. There was no consensus reached on the utility of PET/CT.61 The National Comprehensive Cancer Network (NCCN) does not recommend routine evaluation of bone metastases for non-muscle invasive urothelial cancer, and only recommends bone scintigraphy for muscle invasive urothelial cancer in symptomatic, high-risk patients or those with laboratory indicators of bone metastasis.62
The utility of PET/CT prior to planned cystectomy has been studied prospectively. In a study by Goodfellow et al., PET/CT was able to detect metastatic disease outside the pelvis with a sensitivity of 54% compared to 41% for the staging CT (N = 207). Both modalities had similar specificities of 97% and 98%.63 In 2 additional studies, management was changed in 6%-27% of the patients based on new findings on PET/CT not detected by conventional CT.64, 65 A meta-analysis of PET/CT in urinary bladder cancer showed pooled sensitivity and specificity of PET/CT for primary lesion detection were 90% and 100%, respectively. The authors concluded that diagnostic accuracy of PET/CT was good in metastatic lesions of urinary bladder cancer, but due to the small number of patients and limited number of studies analyzed, the diagnostic capability of FDG-PET or PET/CT in detection of primary bladder wall lesions could not be assessed.66
Additional metastatic workup with MRI of the brain and bone scan should not be routinely ordered unless localizing labs or symptoms are present.67, 68 The imaging recommendations for renal pelvis and urothelial carcinoma of the ureter for ≤ T1 disease should be guided by recommendations for noninvasive bladder cancer and for ≥ T2 disease should be guided by recommendations for invasive bladder cancer.69, 70
MANAGEMENT
There is limited evidence to favor one imaging modality over another for tumor evaluation following initial therapy. Results for the bladder cohort from the national oncologic PET registry showed that FDG-PET used for chemotherapy monitoring changed management in 52% of patients.71 This study included all disease stages and did not report the comparative effects of other imaging modalities on treatment.
SURVEILLANCE
The majority of recurrences after cystectomy are asymptomatic and routine surveillance is indicated. Professional society guidelines including the American College of Radiology Appropriate Use Criteria recommend post-treatment surveillance in patients with muscle-invasive bladder cancer, and those with nonmuscle invasive bladder cancer and symptoms or risk factors.70 The most common sites of recurrence are the peritoneum, lymph nodes, liver, bone, lungs, and adrenal glands with late recurrences occurring in the upper urinary tract.72 Early detection of asymptomatic recurrence has been shown to positively impact survival.73
Brain and Spinal Cord Malignancy
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented primary central nervous system cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated (note: especially useful when systemic involvement is clinically suspected) | Not indicated | Not indicated |
MRI brain | Indicated | Indicated for evaluation of suspected or known primary CNS cancer or brain metastases | Indicated |
MRI spine | Indicated (note: especially useful for intracranial and spinal ependymoma, medulloblastoma, primary spinal cord tumors, leptomeningeal disease, and symptomatic or cerebrospinal fluid-positive primary central nervous system lymphoma) | Indicated for evaluation of suspected or known primary CNS cancer or spinal metastases | Indicated for primary CNS cancers affecting the spinal cord |
fMRI | Indicated for preoperative neurosurgical planning, as a replacement for a Wada test or direct electrical stimulation mapping | Indicated for preoperative neurosurgical planning, as a replacement for a Wada test or direct electrical stimulation mapping | Not indicated |
MR angiography head | Not indicated | Indicated for evaluation of vascular supply to tumor | Not indicated |
MR spectroscopy | Not indicated | Indicated to differentiate recurrent or residual brain tumor from post-therapy changes, such as delayed radiation necrosis | Not indicated |
FDG-PET/CT brain |
Not indicated | Indicated for differentiation of posttreatment scarring from residual or recurrent disease | Not indicated |
FDG-PET/CT whole body | Indicated for evaluation of possible systemic disease in proven CNS lymphoma | Not indicated | Not indicated |
Note: CT head or CT myelogram are imaging alternatives when MRI cannot be performed or is not available.
Note: Commonly used radiolabeled tracers for PET brain are not currently reviewed at Carelon.
Rationale
Primary brain and spinal cord tumors encompass a large and heterogeneous group of cancers that range from benign to highly aggressive. Glioblastomas are the most common high-grade primary central nervous system cancer, and comprise about 15% of primary brain cancers.74 Risk factors for brain and spinal cord cancers include genetic predisposition and radiation exposure. The most common presentation is focal neurological symptoms based on the region of brain involved.
DIAGNOSTIC WORKUP
The World Health Organization Classification of Tumors of the Central Nervous System is used to classify and grade gliomas. All patients require an MRI of the brain for initial evaluation unless contraindicated. Spine imaging is indicated for intracranial and spinal ependymoma, medulloblastoma, primary spinal cord tumors, leptomeningeal disease, and symptomatic or cerebrospinal fluid-positive central nervous system lymphoma. Imaging is also indicated for central nervous system lymphomas to assess for possible systemic involvement; one study found that PET/CT body had a significantly higher sensitivity (94%-98%) than CT and resulted in change in management in 34% of patients.75
Per NCCN, MR spectroscopy and PET brain imaging are not generally useful in the initial evaluation of primary central nervous system cancers. However, the evidence to date is limited and PET imaging is currently a National Comprehensive Cancer Network (NCCN) level 2B recommendation.76-78
MANAGEMENT
MR angiography, fMRI, MRS, or PET brain scan may be used to differentiate radiation necrosis from active tumor.79 In a study comparing MRI to MRS, MRS plus diffusion-weighted imaging sequences was found to have above 95% sensitivity and specificity for distinguishing bacterial abscess from cystic tumor.80 In a meta-analysis comparing the accuracy of MRS to PET, there was no significant difference between the two modalities.81
SURVEILLANCE
Carelon Oncologic Imaging guidelines for monitoring of primary central nervous system cancers are in concordance with both NCCN Nervous System Cancers guidelines as well as the European Society for Medical Oncology High-Grade Malignant Glioma guidelines.78, 82
Breast Cancer
Advanced imaging is considered medically necessary for the diagnostic workup and management of suspected or documented breast cancer. Routine surveillance imaging following completion of therapy is not considered medically necessary.
Imaging Study | Suspected Cancer | Diagnostic Workup | Management | Surveillance |
---|---|---|---|---|
CT chest CT abdomen and pelvis | Not indicated | Indicated for stage IIIA-IV or clinically suspected metastatic disease | Indicated | Not indicated |
MRI breast | Indicated in ANY of the following scenarios: Single follow-up MRI at 6 months following a breast MRI with BI-RADS category 3 findings Differentiation of palpable mass from surgical scar tissue Lesion characterization when ultrasound and mammography are inadequate to localize for biopsy Suspected breast implant associated anaplastic large cell lymphoma (BIA-ALCL) in patients with textured breast implants when ultrasound is nondiagnostic Metastatic cancer suspected to be of breast origin by histology when no mammographic findings of primary breast carcinoma Evaluation of pathologic nipple discharge* after nondiagnostic mammography and ultrasound |
| Indicated in ANY of the following scenarios: To assess response to neoadjuvant chemotherapy prior to surgery Post-lumpectomy with close or positive margins to evaluate for residual disease Suspected recurrence in patients with tissue transfer flaps (rectus, latissimus dorsi, and gluteal) post-reconstruction Suspected recurrence of breast cancer when clinical, mammographic, and/or sonographic findings are inconclusive |
|
Not indicated | Indicated in EITHER of the following scenarios: Locally advanced disease (stage IIIA-IIIC) has been established and standard imaging cannot be performed or is nondiagnostic for metastatic disease Clinical suspicion for metastatic disease when standard imaging cannot be performed or is non diagnostic for metastatic disease | Indicated in ANY of the following scenarios: Radiation planning for treatment of locoregional recurrence Standard imaging cannot be performed or is nondiagnostic for recurrent or progressive disease Evaluation of elevated LFTs or rising tumor markers when standard imaging has not clearly identified a site of recurrence or progression Restaging/treatment response when bone is the only site of measurable disease in the chest, abdomen, and pelvis | Not indicated | |
18F-fluoroestradiol (18F-FES) PET/CT | Not indicated | Not indicated | Not indicated | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Note: PET mammography will continue to undergo review as new evidence-based studies are published. Interval routine coverage for PET mammography is not considered medically appropriate at this time.
*Pathologic nipple discharge: persistent and reproducible on exam, spontaneous, unilateral, single duct, and clear or bloody
**Heterogeneously or extremely dense breast tissue by mammographic characterization
Rationale
Breast cancer is the most common cancer in women. Invasive ductal carcinoma and invasive lobular carcinoma are the two main histological subtypes of breast cancer, accounting for 91% of all diagnoses.83 Incidence increases with age and risk factors include family history, use of hormone replacement therapy, use of oral contraceptives and benign breast disease. Most cases of breast cancer are detected by mammographic screening or self-examination.
SUSPECTED CANCER
Imaging cannot replace tissue diagnosis, and suspicious lesions detected by screening mammography should be evaluated with diagnostic mammography and breast ultrasound to further characterize and direct potential biopsy. MRI breast may be indicated when these modalities are unable to localize a lesion for biopsy. Although the risk of malignancy with a mammogram designated as BI-RADS 3 is relatively low (0.3%-2%), some experts recommend follow-up with MRI in this scenario. MRI can also assess possible mammographically-occult primary breast cancer when presenting with supraclavicular or axillary nodal metastases.84
DIAGNOSTIC WORKUP
Breast cancer is staged using the American Joint Committee on Cancer TNM system. Advanced imaging should be guided by stage and other presenting symptoms. In a large single-institution retrospective study of newly diagnosed asymptomatic breast cancer, bone scan detected bony metastases in 6% of patients (stage I 5%, stage II 6%, and stage III 14%), liver ultrasound detected hepatic metastases in 0.7% of patients (stage I or II 0%, and stage III 6%), and chest X-ray detected lung metastases in 0.9% of patients (stage I or II 0% and stage III 7%). However, there was an unacceptably high rate of false positives: 6% for bone scans, 6% for liver ultrasounds, and 3% for chest X-rays.85 A review of 20 studies similarly showed that bone scan detected skeletal metastases in 0.5%-6.8% of those with stage I, 2.4%-8.8% with stage II, and 8.3%-24.5% with stage III breast cancer. The detection of liver and bone metastases ranged from 0%-1.7% in stage I-II patients and 1.7%-2% for stage III patients. False-positive rates were 10%-22% for bone scan, 33%-66% for liver ultrasonography, and 0%-23% for chest radiography.86 Based on the poor sensitivity and specificity of imaging in asymptomatic early stage breast cancer, imaging should be reserved for evaluation of specific signs or symptoms suggestive of metastatic disease.
The use of PET or PET/CT is not indicated in the routine staging of clinical stage I, stage II or operable stage III (T3 N1) breast cancer, supported by studies detailing the high false-negative rate in the detection of lesions that are small (<1 cm), low sensitivity for detecting axillary nodal metastases, low probability of these patients having detectable metastatic disease, and high rate of false-positive scans.87-90 In the setting of metastatic disease found on conventional imaging, there is insufficient data and limited evidence to show PET scan alters treatment. In a prospective study (N=178) by Jeong et al., patients without clinically detected axillary node metastases had virtually no benefit from PET/CT scan; management was changed in only 1.7% of patients.91 The National Comprehensive Cancer Network (NCCN) has notes PET/CT to be most beneficial and accurate for advanced (stage III) disease and invasive ductal histology, and may be useful when standard staging studies are equivocal.31
The utility of preoperative MRI breast is controversial and is not universally recommended. In 2 prospective trials, the rate of postoperative re-excision was unaffected by preoperative MRI.92, 93 In a meta-analysis of 4 studies by Houssami et al., (N=3169 patients), there was no difference in the rate of local recurrence or disease-free survival at 8 years for patients receiving a preoperative breast MRI compared with those without preoperative imaging.94 The NCCN designates MRI breast as an optional imaging test.31 The American College of Radiology states that MRI breast with and without contrast “may be appropriate” prior to treatment of newly diagnosed breast cancer in some scenarios, including for lesions greater than 2 cm in size, or for lesions 2 cm or smaller when there is clinical evidence of nodal involvement. However, they also note that much of the evidence regarding diagnostic accuracy of breast MRI relate to evaluating tumor within the breast, not to evaluation of axillary nodal involvement.95
MANAGEMENT
For evaluation of the axilla, both in newly diagnosed breast cancer and in post-treatment evaluation, ultrasound is generally the initial study of choice. However, the American College of Radiology states that MRI breast with and without contrast “may be appropriate” after completion of therapy or in the setting of local recurrence (following diagnostic mammography or digital breast tomosynthesis). For newly diagnosed local recurrence, the ACR also indicates that FDG-PET/CT imaging “may be appropriate,” but that the primary supporting evidence consists of a systematic review in which analysis was limited due to the heterogeneity of the included studies.95
Response to therapy based on PET/CT imaging has been correlated with longer time to progression but whether this translates into improved patient outcomes is unknown.96 In a comparative study of 17 single-institution, nonrandomized, observational studies, PET/CT response correlated with changes in tumor volume as determined by bone scan, MRI, and/or CT; however, performance compared to conventional modalities and overall clinical impact could not be determined.97 The NCCN recommends conventional imaging for systemic restaging.31 In the unique scenario of bone-only metastases, the Carelon External Expert Advisory Board allows for disease monitoring with PET imaging, as restaging with CT or MRI is expected to result in suboptimal distinction between treated and residual/recurrent bone disease.
The FDA approved CERIANNA (18F-fluoroestradiol, 18F-FES) for use as an adjunct to biopsy in metastatic or recurrent breast cancer.98 There is a high correlation between 18F-FES uptake and estrogen receptor (ER) expression on immunohistochemistry.99 Appropriate use criteria from the Society of Nuclear Medicine and Molecular Imaging (SNMMI) state that FES-PET imaging is appropriate for assessment of ER status when biopsy is nondiagnostic or in lesions difficult to biopsy, as well as when other imaging tests are equivocal or suggestive. They further state that FES-PET is appropriate when considering endocrine therapy in newly diagnosed metastatic disease and when considering second-line endocrine therapy after progression of metastatic disease, citing multiple prospective trials using FES-PET as a predictive biomarker for response to therapy.100 However, decisions regarding initial therapy rely on both ER status as well as HER2 status, and evidence regarding outcomes when used to direct management remains limited. In a retrospective data review from the TRANSCAN project, a prospective multicenter clinical trial, the authors reported that while FES-PET can reveal more lesions than FDG-PET, it should not be used as a first-line technique for detection of metastatic disease in patients with ductal ER-positive disease due to lower sensitivity compared to FDG-PET, on patient-based analysis. The authors state, “although some encouraging data are available, conficting results have been reported and the real predictive value of this imaging procedure in terms of patient outcome has never been proved by large prospective studies.”101
SURVEILLANCE
Both the American Society of Clinical Oncology and the NCCN discourage the use of advanced imaging for routine surveillance of treated, asymptomatic breast cancer.31, 102 Early detection has not been shown to provide an advantage in survival or the ability to palliate recurrent disease and there is no evidence to support the use of CT, MRI, or PET scan.88
The NCCN recommends annual mammography surveillance, and notes that while MRI surveillance is of undefined utility, it should be considered for those with dense breasts treated with breast conservation + radiation, those diagnosed before age 50, and those whose lifetime risk of a second primary cancer is >20% (based on models largely dependent on family history) .31 The American College of Radiology (ACR) Appropriateness Criteria considers MRI and other advanced imaging modalities usually inappropriate for the mastectomy or reconstruction side(s) in patients with a history of breast cancer.103
Cancers of Unknown Primary / Cancers Not Otherwise Specified
The following imaging criteria may be utilized for cancers not addressed elsewhere in the Oncologic Imaging guidelines, including cancers of unknown primary.
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented malignancy.
Imaging Modality | Diagnostic Workup | Management | Surveillance |
CT chest CT abdomen and pelvis | Indicated based on specific cancer or cancer type suspected | Indicated based on specific cancer or cancer type suspected | Indicated based on specific cancer or cancer type suspected |
MRI imaging | Indicated based on specific cancer or cancer type suspected | Indicated based on specific cancer or cancer type suspected | Indicated based on specific cancer or cancer type suspected |
FDG-PET/CT | Indicated when standard imaging cannot be performed or is nondiagnostic in determining the extent of disease | Indicated when standard imaging cannot be performed or is nondiagnostic in determining the extent of disease | Not indicated |
Note: For malignancy of unknown origin involving the cervical lymph nodes, please see “Head and Neck Cancer”
Rationale
Cancer of unknown primary (CUP) describes findings of malignancy by histopathology, without confirmation of tumor origin. CUP can be subdivided into four categories: adenocarcinoma, squamous cell carcinoma, neuroendocrine carcinomas, and poorly differentiated carcinomas. Further testing should be guided by patient history and physical, pattern of disease spread, and clinical factors. In the majority of CUP, the underlying malignancy is never identified and treatment often is empiric based on histopathologic subtype. As CUP often present as metastatic disease, prognosis is poor with 80% of patients having a median overall survival of only 6 months.104 This section addresses both cancers of unknown primary as well as cancers not otherwise specified in Carelon Clinical Appropriateness Guidelines section for Oncologic Imaging.
DIAGNOSTIC WORKUP
For malignancy of unknown origin involving the cervical lymph nodes but suspected to be of Head/Neck origin, please see “Head and Neck Cancer” guidelines.
The initial work-up for cancers of unknown primary should include a history and physical, laboratory evaluation, and imaging studies. CT of the chest, abdomen, and pelvis is commonly used to identify the primary cancer, assess extent of disease, and select for sites amenable to biopsy.105 PET imaging is increasingly being used as part of the diagnosis of CUP. A meta-analysis and systematic review on the use of PET/CT in patients with CUP found that primary tumors were detected in 37% of 433 patients from 11 studies, with pooled sensitivity and specificity both at 84%.106 Another study found that PET/CT detected more primary sites (24%-40%) than CT or MRI (20%-27%).107 NCCN, however, does not recommend routine use of PET imaging for CUP due to a lack of prospective randomized studies comparing PET imaging to conventional imaging.84 Special consideration should be given to patients presenting with a solitary metastasis where localized intervention is planned and to cervical nodal metastases of unknown origin. In a comprehensive review of patients with a solitary metastasis, PET imaging changed management in 34% of patients relative to conventional imaging. Fourteen percent of patients underwent surgery with curative intent.108 In a systematic review and meta-analysis of patients with cervical nodal metastases of unknown origin, the primary tumor detection rate, sensitivity, and specificity of PET-CT were 0.44 (95% CI, 0.31-0.58), 0.97 (95% CI, 0.63-0.99), and 0.68 (95% CI, 0.49-0.83). Area under the curve was 0.83 (95% CI, 0.80-0.86).109
The initial work-up of patients with cancer not otherwise specified should include imaging of the primary neoplastic process and assessment for systemic involvement if warranted. Specific imaging recommendations vary with underlying pathologic diagnosis, staging, and patient factors. Because of the many nuances associated with cancer evaluation, peer-to-peer discussions will often be necessary to determine appropriateness of advanced imaging.
MANAGEMENT
For patients with either active disease or localized disease in remission, follow-up frequency should be determined by clinical need with additional diagnostic tests based on symptomatology.84
Subsequent imaging strategy for cancer not otherwise specified varies with underlying pathologic diagnosis and staging. In general terms, imaging used in the initial detection of the cancer may be used to assess for treatment response.
SURVEILLANCE
For patients with either active disease or localized disease in remission, follow-up frequency should be determined by clinical need with additional diagnostic tests based on symptomatology.84
The type and frequency of surveillance imaging for cancer not otherwise specified is dependent on the underlying pathologic diagnosis and staging. When indicated, CT imaging can be used in most cancers, with PET rarely indicated for surveillance.
Cervical Cancer
Advanced imaging is considered medically necessary for diagnostic workup and management of documented cervical cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
CT chest CT abdomen and pelvis | Indicated (note: CXR usually sufficient for Stage I) | Indicated (note: especially useful 3-6 months after completion of therapy if PET imaging not done) | Not indicated |
MRI pelvis | Indicated | Indicated (note: especially useful 3-6 months after completion of therapy OR in patients who have undergone fertility-sparing surgery) | Not indicated |
FDG-PET/CT | Indicated for patients with a definitive diagnosis of stage IB1 or higher as an alternative to CT chest, abdomen, and pelvis |
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Ninety-five percent of cervical cancers are classified as either squamous cell carcinomas (the majority) or adenocarcinomas.110 Other rare histologies include neuroendocrine carcinoma, small cell carcinoma, lymphoma, and rhabdomyosarcoma. Risk factors for cervical cancer include immunosuppression, high-risk sexual behavior and infection with human papillomavirus.
DIAGNOSTIC WORKUP
Cervical cancer is staged using the FIGO system. Pelvis MRI is most useful for determination of tumor location, size, invasion, and presence of regional nodal disease.111 A systematic review of 57 single-institution trials showed MRI was more accurate than CT for overall staging of cervical cancer.112 A retrospective American College of Radiology Imaging Network/Gynecology Oncology Group (ACRIN/GOG) study comparing MRI and CT for early-stage cervical cancer found that contrast-enhanced multi-detector CT was equivalent to MRI for overall preoperative staging, but MRI performed significantly better for visualization of the primary tumor and detection of parametrial invasion.113 In a second ACRIN/GOGIntergroup Study, MRI was superior to CT and clinical examination for evaluating uterine body involvement and measuring tumor size.114 This benefit was also seen for preoperative selection of women for fertility-sparing surgery and for evaluation of residual tumor in the cervix after a cone biopsy with negative margins. In a small retrospective study in patients with negative margins after conization, MRI was 100% concordant in showing no residual cancer.115 MRI may also play a role in radiation planning to aid with CT contouring.116
PET/CT is a useful modality for evaluating for extrauterine disease.117, 118 Lin et al. reported a PET sensitivity of 85.7%, specificity of 94.4%, and accuracy of 92% for detecting para-aortic lymph node metastasis in CT-negative advanced cervical cancer patients.119 Another review also concluded that PET/CT appeared better than conventional imaging for detection of metastatic lymph nodes with a reported sensitivity of 78%-84% for PET/CT, 72% for MRI, and only 47% for CT alone.120 Per NCCN, whole body PET/CT is preferred for stage IB1/IB2 disease prior to fertility sparing treatment, and for stage IB3 and higher disease as part of initial work-up (level of evidence category 2A).121
MANAGEMENT
PET imaging is preferred for patients with high risk stage IB2 or above disease treated with adjuvant radiation or chemoradiation therapy. Early data suggest PET/CT during and/or after concurrent chemoradiation therapy may be a useful test for predicting local and distant failures and overall survival.122 In the setting of recurrent disease, PET/CT has reported sensitivities ranging from 90.3%-92.7% and specificities ranging from 81%-100%.123 NCCN recommends whole-body PET/CT for suspected recurrent/metastatic disease.121
SURVEILLANCE
In the setting of fertility-sparing surgery, MRI is commonly used for postoperative follow up. In a single-institution study, serial MRI follow up detected recurrent cervical cancer at a rate of 4%. Review of the literature shows that the recurrence rate after trachelectomy varies from 0%-25%.124, 125
Routine surveillance is not indicated in cervical cancer patients treated with radical hysterectomy, radiation, or concurrent chemotherapy, in accordance with NCCN guidelines.121
Colorectal Cancer
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented colorectal cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated for known or suspected invasive cancer | Indicated for known or suspected invasive cancer | Indicated annually for Stage II or III colorectal cancer, and every 6-12 months for Stage IV colorectal cancer |
MRI pelvis | Indicated for known or suspected invasive rectal cancer ONLY | Indicated for known or suspected invasive rectal cancer ONLY | Indicated for rectal cancer treated with transanal local excision alone only |
FDG-PET/CT | Indicated when standard imaging (CT Chest, Abdomen and Pelvis) cannot be performed or is non-diagnostic for surgically curable metastatic disease |
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Colorectal cancer is the third most common cancer in both men and women. Over 90% of cancers originating from the colon and rectum are adenocarcinomas. Incidence is higher in males and increases with age; other risk factors include alcohol use, dietary factors, obesity, smoking, and lack of physical exercise. There is a strong association with inflammatory bowel disease, and up to 10% of colorectal cancers are due to genetic factors. Tumors may be discovered on screening colonoscopy. Other presentations include bloody stool, abdominal pain, anemia, and obstructive symptoms.
DIAGNOSTIC WORKUP
Colorectal cancer is staged using the American Joint Committee on Cancer TNM system. For colon cancer, the NCCN recommends CT chest, abdomen, and pelvis for initial staging.126 Additionally, the European Society for Medical Oncology (ESMO) states, “staging is carried out primarily with imaging techniques, such as a contrast-enhanced CT of the thorax, abdomen, and pelvis.”127 In a meta-analysis of 19 studies evaluating CT imaging in preoperative colorectal staging, the pooled sensitivity and specificity for detection of tumor invasion were 86% (95% CI, 78%-92%) and 78% (95% CI, 71%-84%). Similarly, the values for nodal detection were 70% (95% CI, 63%-73%) and 78% (95% CI, 73%-82%). In a subgroup analysis, studies utilizing multi-detector CT fared better than conventional CT.128 Results from this meta-analysis are consistent with the findings of several other studies.129-134
MRI pelvis or endoscopic rectal ultrasound (ERUS) is indicated for the initial staging of rectal cancer, in addition to CT chest and abdomen.135 In the prospective MERCURY II trial, MRI pelvis was able to accurately assess the low rectal plane which resulted in avoidance of overtreatment through selective preoperative therapy and substantially fewer pathologically positive circumferential resection margins.136
PET/CT does not supplant a diagnostic contrast enhanced CT, and should only be used to evaluate an equivocal finding or in patients with strong contraindications to IV contrast. Two studies found that PET/CT was not superior to CT for routine preoperative staging of colorectal cancer. In a study by Furukawa et al., PET/CT findings resulted in treatment changes in only 2% of patients who had bone and distant lymph node metastases detected only by PET/CT. In one case, CT imaging detected lung metastases that were not demonstrated on PET.137
PET/CT may be useful in identifying additional sites of extrahepatic metastases, but a positive impact on overall management and survival has not been definitively established. In the setting of resectable M1 disease, Moulton et al. found that PET/CT compared with CT alone did not influence survival. Surgical management was affected in 8% of patients, in which only 2.7% were deemed to no longer be surgical candidates. In addition, the false positive rate of PET/CT was 8.4%.138 However, a meta-analysis of 18 studies suggests that FDG PET/CT is highly accurate for the detection of liver metastases on a per-patient basis but less accurate on a per-lesion basis. Compared to MRI, PET was less sensitive but more specific, and impacted management in about 25% of patients.139
MANAGEMENT
Response to neoadjuvant therapy can be seen in as many as 60% and complete response in as many as 18% of patients with rectal cancer.140, 141 In the prospective MERCURY study, MRI assessment of tumor response and circumferential resection margin was correlated with positive survival outcomes. 142 A recent meta-analysis by de Jong et al., however, concluded that MRI, CT, and ERUS could not be used to predict complete response of locally advanced rectal cancer, and had poor accuracy for predicting lymph node involvement and tumor invasion in the circumferential resection margin.143
Chemotherapy may reduce the sensitivity of PET for the detection of liver metastases, likely due to metabolic inhibition caused by cytotoxic therapies.144, 145 False negative rates of 87% have been reported for PET scans performed within 4 weeks of chemotherapy.146 False positive PET/CT scans may also result from tissue inflammation after surgery.
In the uncommon setting of a rising carcinoembryonic antigen (CEA) and CT scans which have not identified a site of recurrence, PET/CT is a consideration; however, surgically curable recurrent disease may not be identified. It is notable that almost half of elevated CEAs after R0 resection are false positives and serial CTs at 3-month intervals until CEA stabilizes or normalizes or until disease is identified is often the preferred approach. When the CEA level is above 15ng/mL, false negatives are rare.147 Based on a pooled analysis for detection of colorectal cancer recurrence, the sensitivity of CEA ranges from 68% for a threshold of 10 µg/L to 82% for a threshold of 2.5 µg/L and the specificity ranges from 97% for a threshold of 10 µg/L to 80% for a threshold of 2.5 µg/L.148 A meta-analysis of 11 studies estimated sensitivity and specificity and positive and negative likelihood ratios of FDG-PET/CT in the detection of tumor recurrence in colorectal cancer patients with elevated CEA to be 94.1%, 77.2%, 4.70, and 0.06, respectively.149
SURVEILLANCE
Surveillance CT chest, abdomen and pelvis is indicated for stage II and higher colon cancer per the NCCN at variable intervals depending on stage of disease.126 For patients who have undergone local transanal excision of rectal cancer, the NCCN recommends surveillance imaging with MRI or EUS of the rectum every 3-6 months for 2 years, then every 6 months for a total of 5 years.135
Although PET/CT detects recurrence earlier in some patients, these benefits are offset by both false positive and false negative results. A trial randomizing patients (N = 130) treated with curative resection to conventional surveillance alone or conventional surveillance plus PET/CT scan found no significant difference in detection of recurrence between the 2 groups. The use of PET/CT in the setting of metastatic colorectal cancer treated with definitive therapy is also not indicated. A recent retrospective study failed to show a correlation with frequency of imaging and effect on time to second procedure or median survival duration.150
For surveillance of colorectal cancer, Carelon Oncologic Imaging guidelines are in concordance with the American Society of Clinical Oncology recommendations, National Comprehensive Cancer Network (NCCN) Guidelines for Colon Cancer, and NCCN Guidelines for Rectal Cancer.126, 135, 151
Esophageal and Gastroesophageal Junction Cancers
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented esophageal and gastroesophageal junction cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
CT chest CT abdomen | Indicated | Indicated (note: especially useful if PET imaging not done) | Indicated (note: especially useful in first 2-3 years) |
CT pelvis | Indicated based on clinical suspicion for pelvic disease | Indicated based on clinical suspicion for pelvic disease | Indicated based on clinical suspicion for pelvic disease |
FDG-PET/CT | Indicated when standard imaging cannot be performed or does not demonstrate distant (M1) metastatic disease |
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Esophageal cancer is the seventh most common cause of cancer-related mortality in men. Over 90% of esophageal cancers are either squamous cell carcinoma or adenocarcinoma.152 Risk factors for squamous cell carcinoma include tobacco and alcohol use, while adenocarcinoma is associated with gastroesophageal reflux disease and Barrett’s esophagus. The most common presentation is symptoms due to obstruction (such as dysphagia or odynophagia), or symptoms caused by distant metastases.
DIAGNOSTIC WORKUP
Esophageal cancer is staged using the American Joint Committee on Cancer TNM system. The role of endoscopic ultrasound is to evaluate tumor depth and lymph node involvement. The overall accuracy of endoscopic ultrasound (EUS) for this component of staging is in the 80% to 90% range. In a meta-analysis which also included high grade esophageal dysplasia, surgical or endoscopic mucosal resection pathologic staging compared to EUS had a T-stage concordance of only 65%.153 Nonetheless, EUS is still considered superior to CT, MRI, and PET for locoregional staging.154-156 The National Comprehensive Cancer Network (NCCN) recommends chest/abdominal CT with oral and IV contrast for initial workup; pelvic CT with contrast only as clinically indicated.157
While CT is the most widely used modality for detection of distant metastases (M1 disease), the addition of FDG-PET improves detection of lesions that may remain occult on CT, allowing proper patient selection for surgical resection. A meta-analysis of 31 articles found PET/CT to be more accurate than CT for identifying metastatic disease: sensitivity and specificity were 71% (95% CI, 0.62-0.79) and 93% (95% CI, 0.89-0.97) for FDG-PET and 52% (95% CI, 0.33-0.71) and 91% (95% CI, 0.86-0.96) for CT, respectively.154 In the prospective American College of Surgeons Oncology Group trial Z0060, PET scan identified an additional 5% of biopsy-confirmed distant metastatic disease as compared to conventional imaging.158 In 2 additional studies, PET/CT resulted in avoidance of futile surgery in up to 17% of patients and change in management of 38.2% of cases.159
MANAGEMENT
Metabolic response by PET/CT has been suggested as a surrogate marker for prognosis. In the largest of these studies, the prospective MUNICON phase II trial (N=110) showed that post-treatment PET correlated with treatment response and event-free survival (29.7 months in metabolic responders and 14.1 months in nonresponders, Hazard Ratio, 2.18, P = .002).160 Conversely, in a review from 2017 that included 13 studies (N = 697), Cremonesi et al. noted that 8 studies supported interim PET, while 5 studies found no benefit in terms of pathological complete response and/or outcome.161 The NCCN recommends PET/CT as a preferred modality after preoperative or definitive chemoradiation (level 2A recommendation), at least 5-8 weeks after completion of therapy.157
SURVEILLANCE
The majority of esophageal and gastroesophageal junction cancer recurrences present as distant metastases within the first 1 to 3 years. Based on the NCCN Guidelines, surveillance imaging can be considered for up to 3 years if the patient is likely to tolerate additional curative-intent therapy for recurrence.157
Gastric Cancer
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented gastric cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated (note: especially useful in first 5 years) |
FDG-PET/CT | Indicated for tumors initially stage IB or higher when standard imaging cannot be performed or does not demonstrate distant (M1) metastatic disease, and the patient is a candidate for curative surgery |
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
The incidence of gastric cancer has declined over the past 10 years, but it remains one of the leading causes of death worldwide. The most common histologic type is adenocarcinoma. Presenting symptoms may include weight loss, pain, bleeding, or dysphagia. More advanced disease can manifest as ascites and symptoms related to distant metastases.
DIAGNOSTIC WORKUP
Gastric cancer is staged using the American Joint Committee on Cancer TNM system. Endoscopic ultrasound (EUS) is used to obtain pathologic confirmation of malignancy and local tumor staging, with advanced imaging used to assess lymph nodes and metastases. In a meta-analysis of 50 studies, EUS for assessment of locoregional disease showed sensitivity and specificity rates for distinguishing T1 from T2 cancers of 85% and 90%, respectively. Sensitivity and specificity for distinguishing T1/2 from T3/4 tumors were 86% and 90%, respectively. When used to evaluate lymph nodes, EUS had a lower diagnostic yield with sensitivity and specificity of 83% and 67%, respectively.162 A second meta-analysis reported accuracy rates for tumor staging at 75% and nodal staging at 64% with a sensitivity of 74% and specificity of 80%.163 In a third systematic review comparing EUS, CT, and MRI, the diagnostic accuracy of overall T staging for EUS, multidetector CT, and MRI varied between 65% to 92.1%, 77.1% to 88.9%, and 71.4% to 82.6%, respectively. The authors concluded that although efficacy was similar, EUS remains the standard of care.164 The American College of Radiology Appropriate Use Criteria for epigastric pain state that endoscopy is the reference standard for diagnosis of gastric cancer, though they note that patients often present with nonspecific symptoms leading to advanced imaging such as CT; they further state that CT may be ordered in the setting of suspected gastric outlet obstruction.165
Combining PET and CT leads to improved accuracy in preoperative staging (68%) compared to PET (47%) or CT (53%) alone, and in a single-institution retrospective study, changed management in 38% of patients.166 The major advantage conferred by PET is improved specificity over CT for the detection of distant metastases (M1 disease). Smyth et al. reported in a prospective study that PET/CT identified an additional 10% occult metastatic lesions in patients with locally advanced disease, compared to preoperative CT imaging, EUS, and laparoscopy.167 FDG PET/CT is recommended if no evidence of M1 disease by standard imaging and if clinically indicated (may not be appropriate for T1 disease) by National Comprehensive Cancer Network (NCCN) (level of evidence category 2A).168
MANAGEMENT
The results of studies showing response to therapy as evidenced by FDG-PET have been mixed. A prospective observation trial by Vallbohmer et al. showed no correlations between interval PET findings and change in FDG avidity to response or prognosis.169 In another study, survival of patients without FDG-avid disease was not significantly different from FDG-avid non-responders.170 In the setting of recurrent disease, a retrospective study showed overall sensitivity and specificity of 78% and 82% for PET compared to 74% and 85% for CT, respectively.171 Therefore, NCCN recommends chest/abdominal/pelvic CT scan for medically fit patients after the completion of preoperative therapy (chemotherapy or chemoradiation) and before surgical intervention, with PET as clinically indicated.168
SURVEILLANCE
The majority of gastric cancer recurrences occur locoregionally in the lymph nodes and peritoneum, followed by the liver. A retrospective Italian trial, which included patients with T1-4 N0-3 M0 gastric cancer who had undergone D2 dissection, found that 94% recurred within 2 years and 98% recurred within 3 years. Of the recurrences, only 3.2% were treated with curative intent.172 In a review of 5 articles that included 810 patients, intense surveillance with CT imaging did not show an improvement in survival.173 Based on the NCCN Guidelines for Gastric Cancer, surveillance imaging for patients with stage II or greater gastric cancer can be done as clinically indicated based on symptoms and concern for recurrence; after 5 years, additional follow-up may be considered based on risk factors and comorbidities.168
Head and Neck Cancer
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented head and neck cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT primary site and neck | Indicated | Indicated to assess response to neoadjuvant treatment or after concurrent chemoradiotherapy | Indicated (note: especially useful within 6 months of completed treatment for baseline imaging) |
CT chest CT abdomen and pelvis | Indicated (note: especially useful for advanced disease or lung cancer screening in smokers) | Indicated (note: not routinely used in subsequent management strategy) | Indicated (note: not routinely used in surveillance but especially useful for patients with smoking history (See Lung Cancer Screening Guideline)) |
MRI primary site and neck | Indicated (note: especially useful for nasopharyngeal carcinoma) | Indicated to assess response to neoadjuvant treatment or after concurrent chemoradiotherapy | Indicated (note: especially useful within 6 months of completed treatment for baseline imaging) |
FDG-PET/CT |
|
| Not indicated |
Note: PET is not generally indicated for initial evaluation of lip and salivary gland cancers, regardless of stage.
Note: PET imaging is not indicated for adjuvant radiation therapy planning when all known disease has been removed.
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Head and neck cancers comprise 3% of all cancers in the U.S. Squamous cell carcinoma accounts for more than 90% of these tumors. Tobacco and alcohol use in addition to human papillomavirus infection are primary risk factors. The most common presenting symptoms are pain, dysphagia, or neck mass. Early mucosal lesions may be found incidentally on oral examination.
DIAGNOSTIC WORKUP
Head and neck cancers are staged using the American Joint Committee on Cancer TNM system. When compared to physical exam alone, CT results in a change of stage in 54% of patients.174 However, CT is relatively poor at identifying invasion of non-osseous cartilage. Newer techniques have improved sensitivity and specificity of CT to almost 90% and 96%, respectively,175 but up to 67% of pathologic lymph nodes may still be missed.176 MRI may be indicated as an adjunct to CT, particularly in the management of nasopharyngeal cancers. In a meta-analysis of 10 studies, diffusion-weighted MRI for evaluation of head and neck squamous cell carcinomas improved overall accuracy from 66% to 86%.177
In a retrospective study conducted by Fleming et al., PET/CT had an accuracy of 90%, true positive rate of 82.9%, and false positive rate of 12.2%. In patients with unknown primary, PET/CT was able to identify the primary site in 72.7% of patients. Distant metastases were detected in 15.4% of patients, and overall treatment was altered in 30.9% of patients.178 In a meta-analysis of 8 studies, sensitivity and specificity of PET/PET-CT for detecting distant metastatic disease were 83% and 96% compared with conventional anatomic imaging, 44% and 96%, respectively.179 The accuracy of PET in early stage head and neck cancers without lymph node involvement is less clear. Multiple small studies have shown relatively poor sensitivity ranging from 25% to 63% for detecting occult lymph node metastases.180, 181
MANAGEMENT
A prospective randomized trial by Mehanna et al. found that PET/CT performed 12 weeks after chemoradiation therapy for treatment response for patients with N2/3 disease resulted in substantially fewer neck dissections with no adverse impact on survival.182 A meta-analysis of 23 studies looking at accuracy of PET/CT found a pooled sensitivity and specificity of 92% and 87%, respectively, for detection of recurrence. A second meta-analysis of 27 studies confirmed these results, with pooled sensitivity and specificity of PET for detecting residual or recurrent head and neck squamous cell carcinoma reported to be 94% and 82%, respectively. However, sensitivity was adversely affected when PET/CT imaging was done within 10 weeks of completion of treatment.183 A negative PET/CT corresponds with a 90% chance of disease eradication.184 These findings were corroborated by 2 additional retrospective studies.185, 186
SURVEILLANCE
Most recurrences are discovered by patients and not by serial imaging or physical exam. Carelon guidelines are in accordance with National Comprehensive Cancer Network Guidelines for Head and Neck Cancers.187
Hepatocellular and Biliary Tract Cancers
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of documented hepatocellular and biliary tract cancers.
Imaging Study | Diagnostic Workup and Diagnosis | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated |
MRI abdomen with or without MRCP |
| Indicated | Indicated |
FDG-PET/CT | Indicated when standard imaging cannot be performed or is nondiagnostic regarding the extent of disease | Indicated when standard imaging cannot be performed or is nondiagnostic for recurrent or progressive disease | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
*Positive AFP ≥ 200 ng/mL (American Association for the Study of Liver Disease)
Rationale
DIAGNOSTIC WORKUP
Hepatobiliary cancer (including gallbladder cancer, cholangiocarcinoma and hepatocellular carcinoma) is staged using the American Joint Committee on Cancer TNM system.
Hepatocellular Carcinoma (HCC)
The initial staging evaluation of suspected HCC should include either a multiphasic abdominal CT or MRI to establish the diagnosis and assess the burden of disease. The National Comprehensive Cancer Network (NCCN) also recommends CT or MRI if positive or rising serum AFP is found during HCC screening.48
A diagnosis of HCC can be made based on imaging criteria in patients at high risk for developing HCC; the most commonly used guidelines are published by the American Association for the Study of Liver Disease (AASLD)47, which incorporates the American College of Radiology (ACR) Liver Imaging Reporting and Data System (LI-RADS).188 In a systematic review and meta-analysis evaluating the diagnostic performance of multidetector CT and MRI, the overall per-patient sensitivity of MR imaging was 88% (95% CI, 83%-92%) and per-patient specificity was 94% (95% CI, 85%-98%). An insufficient number of studies disallowed pooled analysis of CT for diagnostic accuracy and comparison to MRI, but the overall per-lesion sensitivity of MR imaging was higher than that of multidetector CT when the paired data of the 11 available studies were pooled (80% vs 68%, P = .0023). In addition, MRI sensitivity was further improved when gadoxetic acid-enhanced MR imaging was used. Sensitivity tends to be worse in both modalities for lesions < 1cm.189
Extrahepatic imaging should include CT of the chest and pelvis if not already done. Bone scan may be useful when clinical suspicion of bone metastases is high. In a retrospective study comparing PET and conventional imaging for initial diagnosis of HCC, PET identified additional metastases in 2.7% of patients with T2, 5.3% of patients with T3a (5.3%), and 4.8% of patients with T3b tumor classifications.190 In a systematic review and meta-analysis, the pooled estimates of sensitivity, specificity, positive likelihood ratio, and negative likelihood ratio of FDG PET for the detection of metastatic hepatocellular carcinoma were 76.6%, 98.0%, 14.68, and 0.28, respectively.191 Although PET imaging may provide prognostic information on the biological aggressiveness of the cancer, the low sensitivity restricts its usefulness.192
Cholangiocarcinoma and Gallbladder Cancer
In patients with suspected cholangiocarcinoma/gallbladder cancer, CT chest and multi-detector, multiphasic CT of the abdomen and pelvis should be performed to assess local disease, lymph nodes, and sites of distant metastases. If an intervention is not required and accurate imaging of the pancreatobiliary tract is needed to assess surgical resectability, an MRI abdomen with magnetic resonance cholangiopancreatography (MRCP) should be considered. MRCP has largely replaced endoscopic retrograde cholangiopancreatography (ERCP) as it provides better anatomical imaging, a non-invasive alternative with lower risk of complications, and at least equivalent accuracy.193-197 In a systematic review and meta-analysis comparing CT, MRI, and PET to assess for resectability of hilar cholangiocarcinoma, CT had the highest pooled sensitivity at 95% (95% CI, 91%-97%) and a pooled specificity of 69% (63%-75%). MRI had a pooled sensitivity of 94% (90%-97%) and a pooled specificity of 71% (60%-81%), whereas PET/CT had a pooled sensitivity of 91% (84%-96%), and the highest pooled specificity at 81% (95% CI, 69%-90%). The area under the curves (AUC) of CT, MRI, and PET/CT were 0.9269, 0.9194, and 0.9218, respectively. Overall, CT and MRI are comparable imaging modalities to assess resectability. 198 The data to support use of PET/CT for initial staging of cholangiocarcinoma is mixed, although some studies show a change in management of 17%-25%.199-201 Overall, PET imaging has limited sensitivity for local evaluation of cholangiocarcinoma, although high specificity for detection of nodal and distant metastatic disease. Per NCCN recommendations, PET/CT may be considered when equivocal findings are seen by CT or MRI imaging and prior to planned resection.202 The European Society for Medical Oncology (ESMO) recommends MRI as the reference examination for local extension of cholangiocarcinoma and for hepatic metastases, and recommends thoraco-abdomino-pelvic CT for evaluation of nodal disease and other metastases.203
MANAGEMENT
Response to treatment can be assessed with multiphasic CT or MRI of the abdomen, as both can assess intra-nodular arterial vascularity, a key feature of residual or recurrent tumor. Overall nodule size does not reliably indicate treatment response since a variety of factors may cause a successfully treated lesion to appear stable in size or even larger after treatment. The NCCN notes for hepatocellular cancer “PET/CT has limited sensitivity but high specificity, and may be considered when there is an equivocal finding.”48
SURVEILLANCE
In patients treated with curative intent, follow-up for HCC includes CT or MRI imaging of the liver, and consideration for CT chest imaging. Monitoring of AFP is appropriate for HCC. Carelon Oncologic Imaging guidelines are in concordance with the NCCN Guidelines for Hepatocellular Carcinoma and for Biliary Tract Cancers and the ESMO Clinical Practice Guideline for biliary tract cancer.48, 202 203
Histiocytic Neoplasms
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of Langerhans cell histiocytosis (LCH), Erdheim-Chester disease (ECD), and Rosai-Dorfman disease (RDD).
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
MRI or CT (any) | Indicated when categorized as 2A recommendation by NCCN | Indicated when categorized as 2A recommendation by NCCN | Indicated when categorized as 2A recommendation |
FDG-PET/CT |
|
|
|
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
DIAGNOSTIC WORKUP
Histiocytic neoplasms are rare neoplasms (annual incidence of < 5 cases per million population) originating from cells of the myeloid lineage. Clinical overlap is observed among the three most commonly seen disorders: Erdheim-Chester disease (ECD), Langerhans cell histiocytosis (LCH), and Rosai-Dorfman disease (RDD). These neoplasms may present clinically as focal or diffuse multiple organ disease, with the disease spectrum varying from incidental lesions on imaging studies to critical illness arising from severe organ dysfunction. Common sites of involvement include the axial/appendicular skeleton and skull, hypothalamus/pituitary gland, lungs, skin, heart, kidneys/retroperitoneum and less commonly arterial blood vessels, spleen, and liver.
A presumptive diagnosis (without tissue diagnosis) is typically made with characteristic radiographic/clinical findings (e.g., typical pattern of lung nodules, cysts, and cavitated nodules on high-resolution Chest CT), but definitive diagnosis requires tissue examination and immunohistochemistry stains. Because neoplastic cells are often sparsely distributed amongst fibrosis and inflammatory cells, biopsy and histologic evaluation can be challenging. Whole-body PET/CT is recommended by several guidelines (including the National Comprehensive Cancer Network, NCCN) as part of the workup/evaluation of histiocytic neoplasms, to assess both presence and extent of disease.204
MANAGEMENT
NCCN recommends PET/CT as the preferred modality for treatment response assessment, including post radiation therapy, systemic therapy, and completion of surgical curettage.
SURVEILLANCE
Carelon Oncologic Imaging guidelines are in concordance with the National Comprehensive Cancer Network (NCCN) Guidelines for Histiocytic Neoplasms.
Kidney Cancer
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of documented kidney cancer (including renal cell carcinoma, Wilms tumor/nephroblastoma).
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated (note: especially useful in first 3-5 years) |
MRI abdomen | See “Renal mass” in Abdominal Imaging | Indicated for baseline imaging after ablation, partial or total nephrectomy |
|
FDG PET/CT | Not indicated | Not indicated | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Kidney cancer is the sixth most common cancer in men and the tenth most common cancer in women. The most common tumor type is renal cell carcinoma, which arises from renal parenchyma. Primary nephrectomy is indicated in most forms of kidney cancer. Until recently, fully resected renal cell carcinoma has been managed with surveillance only. Treatment options for metastatic renal cell carcinoma have greatly expanded in the last decade with immunosuppressive therapies such as cell cycle checkpoint inhibitors (PD-1 agents), mechanistic target of rapamycin (mTOR) inhibitors, and tyrosine kinase inhibitors (TKI).
DIAGNOSTIC WORKUP
Kidney cancer is staged using the American Joint Committee on Cancer TNM system. In a study comparing triphasic helical CT and fast MRI, renal cell carcinoma was correctly staged 67% of the time.205 In another prospective study, accuracy of MRI was 78%-87%, and the accuracy of CT was 80%-83%.206 Both modalities, however, are poor at detecting invasion of perinephric fat and assessing tumor extension into the renal veins or inferior vena cava. For the evaluation of renal vein involvement, MRI and CT appear to have approximately the same accuracy of 72%-76% and 78%-88%, respectively.207
In the evaluation of primary renal cell carcinoma, PET accuracy was only 50%. The utility of PET/CT is adversely affected by poor FDG avidity and background uptake from the kidney. Although a poor staging modality, specificity of PET was found to approach 100% in 2 separate studies.208, 209 The NCCN and ACR notes that the value of PET in renal cell carcinoma remains to be determined.210 211 Current evidence suggests that imaging of the pelvis is of low yield and does not affect overall management.212, 213 For chest imaging, radiography is preferred, although CT is more sensitive in patients with symptoms, advanced-stage disease, anemia, or thrombocytopenia.214, 215
Carelon guidelines are in accordance with recommendations from the National Comprehensive Cancer Network Guidelines for Kidney Cancer.210,
MANAGEMENT
Imaging (CT or MRI) with contrast can be done when clinically indicated following ablative techniques, and as baseline imaging after partial or radical nephrectomy (NCCN level of evidence category 2B).210, 216
SURVEILLANCE
Active surveillance can be considered in select T1b patients. Imaging (CT or MRI) should be done with contrast when clinically indicated if no contraindication. Active surveillance entails serial abdominal imaging with timely intervention should the mass demonstrate growth (e.g. tumor size, growth rate, infiltrative pattern) indicative of increasing metastatic potential. No single follow-up plan is appropriate for all patients. Follow-up frequency and duration should be individualized based on patient requirements, and may be extended beyond 5 years at the discretion of the physician. The choice to perform imaging follow-up is level of evidence category 2B as designated by the National Comprehensive Cancer Network.210, 216
Lung Cancer – Non-Small Cell
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented non-small cell lung cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated (note: usually only CT chest needed with contrast for 1st 2 years followed with non-contrast thereafter) |
MRI chest | For Pancoast tumors when CT is nondiagnostic | Not indicated | Not indicated |
FDG-PET/CT | Indicated for evaluation of extent of disease following biopsy confirmation of non-small cell lung cancer, if not previously performed |
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Lung cancer is the second most common cancer in both men and women but accounts for the largest number of cancer deaths. The two most common types of lung cancer are non-small cell lung cancer and small cell lung cancer. Non-small cell lung cancer accounts for 85%-90% of lung cancers and is further subdivided into adenocarcinoma, squamous cell carcinoma, and other large cell carcinomas. Risk factors for developing non-small cell lung cancer include tobacco use, radon exposure, asbestos exposure, and other environmental factors. Adenocarcinoma is unique as this lung cancer is most often seen in nonsmokers and light smokers. Presenting symptoms may include cough, hemoptysis, dyspnea, and chest pain.
DIAGNOSTIC WORKUP
Non-small cell lung cancer is staged using the American Joint Committee on Cancer TNM system. CT can accurately evaluate the primary tumor and detect metastatic disease, but is less accurate than PET/CT in identifying mediastinal lymphadenopathy.217, 218 Studies comparing CT and PET/CT for staging of mediastinal nodes have found accuracy rates of 80%-84% for PET/CT versus 76%-77% for CT alone.219, 220 In one prospective trial, PET/CT prevented unnecessary surgery in 17% of patients.221
PET/CT can be used for planning treatment volumes as well as determination of the need for extranodal irradiation. The Radiation Therapy Oncology Group 0151 showed that PET/CT-derived tumor volumes were smaller than those derived by CT alone with only a small number of patients developing nodal failures.222 Involved field irradiation has been shown to improve overall survival in patients over extranodal irradiation in a prospective study by Yuan et al. In this prospective study, the involved field irradiation arm achieved better overall response and local control than the extranodal irradiation arm, and it allowed a dose increase from 68 to 74 Gy to be safely administered.223
MANAGEMENT
Following treatment with concurrent chemoradiation therapy for superior sulcus non-small cell lung cancer, restaging with either CT or PET/CT is appropriate for detection of metastatic disease. For definitive treatment with chemoradiation therapy, the most appropriate follow-up imaging modality is not clear. A prospective study looking at PET/CT versus CT for the restaging of stage IIIA non-small cell lung cancer after neoadjuvant chemoradiation therapy showed PET/CT scan was more accurate than CT alone for restaging at all pathologic stages (stage 0, 92% vs 39%, P = .03; stage I, 89% vs 36%, P = .04). The authors, however, concluded that nodal biopsies are required since a persistently high maximum standardized uptake value does not equate to residual cancer.224 Two other studies which evaluated post-treatment PET for locally advanced non-small cell lung cancer after treatment with concurrent chemoradiation therapy found PET was able to accurately predict local control and tumor response.225, 226 Pan et al. compared conventional CT to PET/CT for locally advanced non-small cell lung cancer performed at 9 months after completion of therapy. Although PET/CT was able to identify progression of disease and recurrence in 48% of patients, no difference in survival could be demonstrated (21.6 months in CT group vs. 23.5 months in PET/CT, P = .89).227 PET/CT may remain FDG-avid up until 2 years after radiation therapy.228 Any suspected recurrence should be biopsied for pathologic confirmation.
SURVEILLANCE
NCCN recommends surveillance imaging with CT chest every 6 months for 2 to 3 years followed by annual low-dose technique CT chest for stage I/II treated with surgery. All others should undergo CT chest every 3 to 6 months for 3 years, then every 6 months for 2 years. Timing of CT scans within Guideline parameters is a clinical decision.229
Lung Cancer – Small Cell
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented small cell lung cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen with or without pelvis | Indicated | Indicated | Indicated |
FDG-PET/CT | Indicated prior to definitive therapy when standard imaging is nondiagnostic for extent of disease | Indicated prior to initiation of radiation therapy | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Lung cancer is the second most common cancer in both men and women but accounts for the largest number of cancer deaths. The two most common types of lung cancer are small cell lung cancer and non-small cell lung cancer. Small cell lung cancer is classified as limited stage small cell lung cancer or extensive stage small cell lung cancer. Small cell lung cancer accounts for 10% to 15% of lung cancers and is most commonly found in smokers. Presenting symptoms may include cough, hemoptysis, dyspnea, and chest pain.
DIAGNOSTIC WORKUP
Asymptomatic metastatic central nervous system disease is seen in up to 15% of patients and MRI brain with contrast is indicated regardless of stage.230, 231 Most of the available data regarding PET in lung cancer is for non-small cell lung cancer, but limited data does suggest that PET/CT can increase staging accuracy in small cell lung cancer. In a small prospective trial (N = 24) evaluating PET versus CT in limited stage small cell lung cancer, FDG-PET had a lesion-based sensitivity relative to CT of 100% and upstaged 2/24 (8.3%) patients. In addition, 25% of patients (6/24) were discovered to have unsuspected regional nodal metastasis.232 Survival benefit was seen in a retrospective study using pre-treatment PET in patients with limited stage small cell lung cancer. Three-year overall survival was 47% for PET versus 19% for CT (P = .03). The authors attributed the difference in survival to improved radiation field planning and disease upstaging.233 Another review found an 84% concordance between PET and CT for staging; however, 19% were upstaged to extensive stage small cell lung cancer and 8% were downstaged to limited stage small cell lung cancer when PET was performed.230 In studies where PET/CT was used for staging and targeting of lymph nodes for radiation, the local recurrence rates have been reported to be less than 3%.234, 235 Pathologic staging is still required for PET/CT-detected lesions that would result in upstaging.236
MANAGEMENT
The NCCN recommends assessment of treatment response following systemic therapy with or without subsequent radiation therapy using chest/abdomen/pelvis CT (level of evidence category 2A); NCCN does not recommend PET/CT for routine follow-up.236 Three small prospective trials (N = 36) evaluated the use of PET for response assessment in small cell lung cancer. Although metabolic response was associated with better prognosis, no patient benefit was observed.231
SURVEILLANCE
National Comprehensive Cancer Network Guidelines for Small Cell Lung Cancer recommend imaging surveillance with a CT of the chest and abdomen every 3 to 4 months as clinically indicated. There is no role for PET/CT in surveillance of treated small cell lung cancer.236
Lymphoma – Hodgkin
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented Hodgkin lymphoma, as below.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT neck CT chest CT abdomen and pelvis | Indicated (note: may consider omitting if PET/CT has been completed) | Indicated (note: may consider omitting if PET/CT done to assess disease response to chemotherapy) | Indicated not to exceed 2 years following completion of treatment |
FDG-PET/CT | Indicated (note: especially useful as an adjunct to CT imaging) |
| Not indicated |
*Deauville 4 (uptake moderately increased compared to the liver at any site); Deauville 5 (uptake markedly increased compared to the liver at any site)
Rationale
Hodgkin lymphoma accounts for about 10% of all lymphomas. Risk factors include Epstein-Barr viral infection, immunosuppression, autoimmune disorders, and genetic predisposition. The most common presentation is painless lymphadenopathy, although many patients also present with B (systemic) symptoms (fevers, chills, night sweats, and weight loss). In more advanced disease, symptoms result from local tumor growth affecting organ function or causing systemic metabolic derangements.
DIAGNOSTIC WORKUP
Hodgkin lymphoma is staged using the Lugano classification system. PET/CT can result in changing of clinical stage in 20% of patients.237 In the RATHL (Response-Adapted Therapy in Advanced Hodgkin Lymphoma) study, PET/CT resulted in upstaging 14% and downstaging 6%.238 In a meta-analysis of 20 studies, the pooled sensitivity for PET/CT was 90.9% (95% CI, 88.0-93.4), and the pooled false positive rate was 10.3% (95% CI, 7.4-13.8) for staging and restaging.
MANAGEMENT
Response to treatment uses the 5-point Deauville criteria for assessment of metabolic response. For early stage favorable Hodgkin lymphoma, the value of interim PET/CT has been mixed although more recent data supports the use of interim PET for response-adapted treatment.239, 240 For early stage unfavorable Hodgkin lymphoma or stage III and IV Hodgkin lymphoma, Gallamini et al. found that following a negative interim PET scan, the 2-year progression-free survival was 12.8% for PET positive and 95.0% for PET negative (P < .0001).241 Cercil et al. found 3-year event-free survival was 53.4% for PET positive and 90.5% for PET negative (P < 0.001).242 Three large randomized trials have confirmed that a risk-adapted approach to chemotherapy after negative interim PET is safe and did not result in poorer outcomes.243, 244
SURVEILLANCE
National Comprehensive Cancer Network (NCCN) Guidelines include consideration of CT neck/chest/abdomen/pelvis with contrast no more than every 6 months for the first 2 years following completion of therapy.245 There is limited data to support routine PET/CT imaging in Hodgkin lymphoma. A randomized study comparing PET/CT to ultrasound and chest radiography for routine surveillance of patients with advanced Hodgkin lymphoma showed that sensitivity was equal in both groups. The conventional imaging arm had a higher specificity (96% vs 86%; P = .02) and positive predictive value (91% vs 73%; P = .01).246 Although PET/CT negative patients had a high likelihood of being disease free, PET/CT also produced false positive rates as high as 20%.5, 247, 248
Lymphoma – Non-Hodgkin and Leukemia
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented acute leukemia, chronic lymphocytic leukemia/small lymphocytic lymphoma and non-Hodgkin lymphomas.
Acute Leukemia
Advanced imaging is considered medically necessary for diagnostic workup and management of documented acute leukemias.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT neck CT chest CT abdomen and pelvis | Indicated | Indicated for clinical suspicion or treatment response to extramedullary disease (chloromas) | Not indicated |
PET/CT |
|
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Chronic lymphocytic leukemia or small lymphocytic lymphoma
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated | Indicated based on symptoms or to evaluate bulky disease | Indicated based on symptoms or to evaluate bulky disease |
FDG-PET/CT | Indicated for suspicion of Richter’s transformation when PET is utilized to direct biopsy | Indicated for suspicion of Richter’s transformation when PET is utilized to direct biopsy | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Lymphoma – Non-Hodgkin: Indolent non-Hodgkin lymphoma
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT neck CT chest CT abdomen and pelvis | Indicated | Indicated |
|
FDG-PET/CT |
|
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Lymphoma – Non-Hodgkin: Intermediate and high grade non-Hodgkin lymphoma
Includes Castleman Disease, Post-Transplant Lymphoproliferative Disorders
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT neck CT abdomen and pelvis | Indicated (note: may consider omitting if PET/CT has been completed) | Indicated |
|
FDG-PET/CT |
|
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Lymphomas are divided into Hodgkin and non-Hodgkin lymphomas. Non-Hodgkin lymphoma (NHL) is the seventh most common cancer in both men and women. Non-Hodgkin lymphoma is further subdivided into indolent, aggressive, and highly aggressive. Aggressive and highly aggressive lymphomas generally present over weeks to months, while indolent lymphomas may be undiagnosed for years due to their slow rate of growth. Common presenting symptoms include enlarged lymph nodes, B symptoms (fevers, chills, night sweats, weight loss), or in the case of more aggressive NHL, symptoms resulting from local tumor growth or systemic metabolic derangements.
Acute leukemias include acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), and acute promyelocytic leukemia (APL). Risk factors for developing ALL include older age (> 70 years), exposure to chemotherapy or radiation therapy, and certain genetic disorders. The clinical presentation of ALL is typically nonspecific, and may include fatigue, B symptoms, dyspnea, and easy bruising or bleeding. Approx. 20% of patient have lymphadenopathy, splenomegaly and/or hepatomegaly.249 Extramedullary disease (including CNS involvement) is uncommon in AML; presentation of solitary extramedullary disease is currently referred to as myeloid sarcoma (historically as chloroma).250
DIAGNOSTIC WORKUP
Lymphoma is staged using the Lugano classification system. For chronic lymphocytic leukemia/small lymphocytic lymphoma (CLL/SLL), CT chest, abdomen, and pelvis is not routinely indicated unless clinically indicated.251 PET/CT is most accurate for staging and interim assessment of lymphomas with high FDG avidity like diffuse large B-cell lymphoma, follicular NHL, and nodal marginal zone lymphoma, but may be less accurate for CLL/SLL, marginal zone lymphoma, and hairy cell leukemia.252, 253
For staging of indolent NHL, the evidence comparing the accuracy of PET/CT to CT alone is mixed. In a recent prospective trial, both modalities performed equally well at initial staging for both indolent and intermediate grade lymphomas.254 However, multiple retrospective trials have found significantly higher sensitivity for PET/CT (94%-98%) and a resultant change of management based on PET findings in 34% of patients.76, 77
For aggressive and highly aggressive NHL, a PET/CT with or without CT chest, abdomen and pelvis with contrast is indicated. In a retrospective study comparing CT to PET for Hodgkin lymphoma and high-grade NHL, the sensitivity of PET/CT versus contrast-enhanced CT was 94% vs. 88% respectively. For evaluation of organ involvement, sensitivity of PET/CT versus contrast-enhanced CT was 88% vs. 50%, respectively. Statistically, PET/CT and CT were equivalent for nodal disease, but PET/CT was more accurate for extranodal disease.255 In a meta-analysis of 20 studies, PET/CT had a pooled sensitivity of 90.9% (95% CI, 88.0-93.4) and the pooled false-positive rate was 10.3% (95% CI, 7.4-13.8).256 Change in treatment has been reported in as many as 9% of cases with the addition of PET/CT scan.257
For acute leukemia, CT scans of the neck, chest, and abdomen/pelvis with IV contrast and CT or MRI head are recommended as indicated by signs/symptoms at diagnosis; PET/CT may be considered if any extramedullary involvement is suspected.249, 250
MANAGEMENT
In general, advanced imaging is not necessary for routine monitoring of treatment response or progression of CLL/SLL. A meta-analysis of the German CLL study group phase 3 trials (CLL4, CLL5, and CLL8) found that 77% of recurrent/progressive disease were detected by clinical symptoms or laboratory testing; CT detected an additional 9% with only a 1% effect on management decisions.258
The 5-point Deauville criteria are used for assessment of treatment response. In a retrospective study, PET/CT outperformed CT for response assessment for follicular non-Hodgkin lymphoma. The accuracy of PET/CT for response assessment was superior to CT (0.97 vs 0.64) and also predicted improvement in progression-free survival (48 months vs 17 months, P < .01).259
Multiple studies have confirmed that PET positivity correlates with active tumor for both NHL and lymphomatous extramedullary disease in ALL. In a representative study, patients who had negative PET imaging after 2 cycles of therapy had a higher rate of complete remission (83% vs 58%) and greater estimated 2 year overall survival (90% vs 61%, P < .001).260 A more recent prospective study, however, showed that a positive interim PET scan predicted worse event-free survival (48% vs 74%, P =.004), but was unable to predict differences in 2 year overall survival (88% vs 91%, P < .001).261
SURVEILLANCE
For CLL/SLL, routine use of CT is not indicated. Management changes resulting from CT imaging only occurred in 1% of patients.258
National Comprehensive Cancer Network Guidelines (NCCN) for B-Cell Lymphomas recommend surveillance imaging with chest, abdominal/pelvic CT no more than every 6 months up to 2 years post treatment, then no more than annually thereafter (for certain subtypes) or as clinically indicated.253
Melanoma
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented cutaneous or mucosal (including uveal/choroidal) melanoma.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT neck CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated for stage IIB or higher |
MRI Abdomen | See “Suspected or Known Metastases” | See “Suspected or Known Metastases” | Indicated for uveal melanoma when liver ultrasound cannot be performed or nondiagnostic |
FDG-PET/CT |
|
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Melanoma, which arises from the pigment-producing cells of the epidermis, is the sixth most common cancer in men and women. Incidence increases with age and is higher in Caucasians. Risk factors include excessive sun exposure, family history, and immunosuppression. The most common initial manifestation of melanoma is a darkly pigmented lesion that changes in size, shape, or color.
Mucosal melanoma is an aggressive type of noncutaneous melanoma arising from melanocytes in mucosal cells, and includes uveal or choroidal melanomas of the eye. The most common site is the head and neck. The incidence of mucosal melanoma is higher in females and persons of African descent, and increases with age. Lesions are most often found incidentally on exam, although they can present with local symptoms such as vision loss/changes, epistaxis, loss of smell, bleeding, or ulceration. Unlike other solid cancers, all mucosal melanomas are considered stage III at a minimum. Resectable disease is treated with surgery and neck dissection followed by adjuvant radiation. For advanced stage (IVB/C) disease, treatment may include radiation and/or systemic treatment.
DIAGNOSTIC WORKUP
Cutaneous melanoma
Melanoma is staged using the American Joint Committee on Cancer TNM system. Imaging for patients with stage I/II disease is insensitive and has a high rate of false positive findings. In a study of 344 patients with T1b-T3b melanoma who had preoperative imaging, the false positive rates were 88% for CT chest, 91% for CT abdomen and pelvis, and 60% for PET/CT.262 Among patients with positive sentinel lymph nodes, routine imaging resulted in 48% of patients having indeterminate findings, of these less than 4% had confirmed systemic metastases. All patients with true positive metastatic disease had thick melanomas and/or lymph node macrometastases.263 Older studies evaluating the accuracy of CT for detection of metastases in stage III disease have found rates approaching 4%, with false positives ranging from 3%-8%.264, 265
In a systematic review evaluating PET/CT imaging, sensitivity ranged from 68% to 87% and specificity from 92% to 98% for stage III/IV melanomas. These results were similar to another meta-analysis showing an overall sensitivity of 89.4% and specificity of 88.8%. Management changed in 22% of patients when PET imaging was utilized. Comparing across modalities, a meta-analysis of 74 studies showed that the sensitivity, specificity, and odds ratio of CT were 51%, 69%, and 2.29, respectively, for detection of distant metastases compared to PET/CT which were 80%, 87%, and 25.23, respectively.266
Mucosal melanoma
Staging studies for tumors arising in the head and neck should include CT/MRI to determine extent of the primary tumor, resectability, and lymph node involvement. Despite the lack of treatment options for patients with uveal melanoma and distant metastatic disease, NCCN favors staging before primary treatment.267 The most frequent sites of uveal melanoma metastasis are liver, lungs, skin/soft tissue and bones. As such, NCCN recommends at minimum that these patients have contrast MRI or ultrasound of the liver, with modality preference determined by expertise at the treating institution.267 Bone scintigraphy is generally not required, especially if a FDG-PET/CT is planned. Evidence to support the use of PET is limited, but given the behavior of these tumors, Carelon’s panel of external experts has recommended in favor of its use.
MANAGEMENT
In most cases, conventional imaging with CT is adequate for assessment of treatment response. If radiation is planned either for definitive therapy or consolidative therapy, PET imaging may be used to assess for metastatic disease. After complete surgical resection, additional imaging should follow guidelines for surveillance.
SURVEILLANCE
The majority of cutaneous melanoma recurrences are either detected by the patient or on physical examination. Surveillance imaging is of low yield and not indicated for early stage disease. In surveillance imaging for stage III melanoma, studies have found detection rates were widely variable, ranging between 7%-56%.268-271 The National Comprehensive Cancer Network (NCCN) follow-up recommendations for stage IIB-IV (no evidence of disease) melanoma include consideration of imaging every 3-12 months for 2 years, then every 6-12 months for another 3 years (level 2B recommendation).272 Surveillance imaging of asymptomatic patients should not continue beyond 3-5 years due to the risk of radiation exposure and based on expected patterns of recurrence.273 For patients with uveal melanoma who elect surveillance imaging, options include contrast MRI or ultrasound of the liver, with modality preference determined by expertise at the treating institution.267
Merkel Cell Carcinoma
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of documented Merkel cell carcinoma.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT neck CT chest CT abdomen and pelvis | Indicated (note: may consider omitting if PET imaging done) | Indicated (note: may consider omitting if PET imaging done) | Indicated (note: most useful with high-risk patients) |
FDG-PET/CT | Indicated | Indicated | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Merkel cell carcinoma (MCC) is a very rare and aggressive type of skin cancer arising from cells in the basal layer of the epidermis and hair follicles. Incidence increases with age and is higher in Caucasians; other risk factors include sun exposure, immunosuppression, and Merkel cell polyomavirus.
DIAGNOSTIC WORKUP AND MANAGEMENT
MCC is staged using the American Joint Committee on Cancer TNM system. MCC is a highly aggressive cancer and up to 8% of patients will present with metastases.274 Results from a single institution study showed that PET resulted in upstaging in 17% and downstaging in 5% of patients with an overall management change in 37% of patients. A second single institution study also found that PET resulted in upstaging of 16% of patients.275 A meta-analysis of 6 studies (N = 92 patients) showed PET had a sensitivity of 90% (95% CI, 80%-96%) and specificity of 98%.276 Asymptomatic brain metastases are fairly rare and routine use of MRI is not recommended.277
The NCCN recommends imaging in most cases of MCC as clinically indicated (whole-body PET/CT or PET/MRI or chest/abdomen/pelvis CT), with several studies indicating whole-body PET with fused axial imaging is more sensitive for detecting occult metastatic disease at baseline. 278
SURVEILLANCE
Most recurrences of MCC occur within the first 2 years. In high-risk patients, routine surveillance with CT neck, chest, abdomen, and pelvis with contrast can be considered for the first 3 years although there is limited data to support this recommendation.
Multiple Myeloma
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of documented solitary plasmacytoma and multiple myeloma.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated for multiple myeloma, smoldering myeloma, or solitary plasmacytoma* | Indicated | N/A |
MRI (bone marrow blood supply) | Indicated for multiple myeloma, smoldering myeloma, or solitary plasmacytoma* |
| N/A |
MRI dedicated body part | Indicated for evaluation of focal bone lesions | Indicated for evaluation of focal bone lesions |
N/A |
FDG-PET/CT | Indicated for multiple myeloma, smoldering myeloma, or solitary plasmacytoma* |
| N/A |
*Includes provisional diagnosis supported by initial diagnostic workup including but not limited to labs, serum/urine protein electrophoresis, serum free light chain (FLC) assay, and bone marrow aspirate/biopsy
Rationale
Multiple myeloma arises from plasma cells in the bone marrow. The disease disseminates widely and often produces antibodies and other proteins that interfere with normal function of bone, kidney, and other organ systems. Incidence increases with age and is higher in males and persons of African descent. The most common presenting symptoms include generalized fatigue, anemia, bone pain, hypercalcemia, and renal dysfunction.
Plasmacytoma is a related tumor which, unlike multiple myeloma, remains localized in bone or soft tissue. Once systemic involvement is excluded (by laboratory testing or bone marrow evaluation), solitary plasmacytoma is typically treated with radiation therapy alone; however, close surveillance is required as these tumors may recur or evolve into multiple myeloma.
DIAGNOSTIC WORKUP
MRI is the most sensitive modality for detection of bone lesions; when compared head to head, MRI detected lesions in 74% of patients compared to 56% with whole body X-ray. In patients with negative skeletal surveys, MRI detected lesions in 52% of patients, while 20% of patients with a negative MRI were discovered to have focal lesions on skeletal survey.279 In patients thought to have a solitary plasmacytoma, MRI detected additional disease and led to a change of management in 25% of those studied.280 In a similar study of indolent myeloma, MRI detected 28% more lesions.281
While MRI is superior for detection of bone disease, PET/CT may be more sensitive for extramedullary involvement. The majority of patients with active myeloma will have positive results on PET scan, and PET imaging may detect early bone marrow involvement in patients with solitary plasmacytoma.282, 283 In a prospective study using PET/CT to stage solitary plasmacytoma and multiple myeloma, 14% of patients had a change in management as a result of information gleaned from PET imaging.282 NCCN recommends either WBCT or FDG PET/CT for initial workup of active myeloma, smoldering myeloma or solitary plasmacytoma (level of evidence category 2A); if negative, whole body MRI with contrast can be considered to discern smoldering from multiple myeloma.5 The European Society for Medical Oncology (ESMO) similarly recommends WBCT (FDG PET/CT deemed optional if carried out instead of WBCT, if available) and whole body MRI for WBCT-negative cases (if FDG PET/CT not carried out).284
MANAGEMENT
MRI may be able to detect early treatment response based on the pattern of marrow response, but false positive results are common due to persistent nonviable lesions.285 In one study, the overall accuracy of whole body MRI was 79% with a sensitivity of 64%, specificity of 86%, positive predictive value of 70%, and negative predictive value of 83%. MRI had only moderate agreement with routinely performed laboratory tests for determining remission.286
PET imaging, however, does provide early assessment of response as well as prognostic information for lesions smaller than 5 mm.287 In a head-to-head study comparing MRI and PET/CT for treatment evaluation of multiple myeloma, PET/CT was less accurate but was able to detect treatment responses earlier.288 In the IMAJEM study, normalization of PET following induction therapy with lenalidomide/bortezomib/dexamethasone (RVD) regimen was associated with improved progression-free survival (30-month progression-free survival, 78.7% vs 56.8%, respectively)289 whereas normalization of MRI findings was not found to correlate with improved outcome measures. The NCCN panel recommends considering using the same imaging modality used during the initial workup for the follow-up assessment.61 The ESMO recommends FDG PET/CT to confirm imaging minimum residual disease (MRD) at treatment response assessment, and every 12 months for follow-up of bone marrow MRD-negative patients.284
Since the risk of progression of solitary plasmacytoma into multiple myeloma or relapse is relatively high (14%-48% within first 3 years of diagnosis), the NCCN recommends yearly follow-up with the same imaging used at first diagnosis for the first 5 years; the NCCN also recommends advanced whole body imaging (ie MRI, low-dose CT, FDG PET/CT) annually for follow-up of smoldering myeloma.61
Carelon guidelines are in accordance with the NCCN Guidelines for Multiple Myeloma and the European Society for Medical Oncology (ESMO).61, 284
Neuroendocrine Tumors
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of documented neuroendocrine tumors.
Well-differentiated neuroendocrine tumor
Including carcinoid tumors of the gastrointestinal tract, lung or thymus, and pheochromocytoma or paraganglioma.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated |
MRI abdomen MRI pelvis | Indicated | Indicated | Indicated |
Somatostatin receptor (SSR)-PET/CT* |
|
| Not indicated |
1 Conventional imaging includes MRI or contrast-enhanced CT.
2 Biochemical evidence for suspected neuroendocrine tumors may include elevated levels of chromogranin A, pancreatic polypeptide, neuron-specific enolase, vasoactive intestinal polypeptide, serotonin (urinary 5-HIAA), gastrin, somatostatin, catecholamines, metanephrines, calcitonin, fasting insulin, C-peptide (proinsulin), or glucagon.
*Somatostatin receptor based PET/CT includes PET with 68Ga dotatate or 64Cu dotatate radiotracers.
Poorly-differentiated neuroendocrine tumor
For poorly differentiated neuroendocrine tumors of the lung, refer to Small Cell Lung Cancer section
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated |
MRI abdomen MRI pelvis | Indicated | Indicated | Indicated |
FDG-PET/CT | Indicated when standard imaging cannot be performed or is nondiagnostic for metastatic disease | Indicated to assess treatment response when PET used for initial staging | Not indicated |
Rationale
Neuroendocrine tumors are rare tumors arising from neuroendocrine cells, which may occur anywhere in the body. The most common neuroendocrine tumors are carcinoid tumors, the majority of which occur in the gastrointestinal tract. Well-differentiated neuroendocrine tumors are known to have a hereditary component. Poorly differentiated tumors are classically nonsecretory and tend to cause symptoms related to local tumor growth or metastatic disease, whereas secretory tumors such as carcinoid most often present with symptoms such as diarrhea, flushing, and wheezing due to excessive production of hormones.
DIAGNOSTIC WORKUP
Neuroendocrine tumor is staged using the American Joint Committee on Cancer TNM system. The World Health Organization classification scheme also takes into account proliferation rate (Ki-67) in grading of tumors. Neuroendocrine tumors of the GI tract, lung and thymus are highly vascular tumors and multiphasic imaging (abdominal ± pelvic multiphasic CT or MRI per NCCN), including arterial phase imaging, should be used to improve detection.290, 291 There is no definitive preference between CT and MRI; although the resolution on CT is often better, MRI is generally more sensitive for detecting vascular invasion or liver metastases.292, 293 Smaller lesions, especially in the small bowel and appendix, may be difficult to visualize with either modality.
Somatostatin receptor (SSR) imaging is recommended by multiple professional societies including ACR, NCCN, and ENTS as a part of initial staging of well-differentiated neuroendocrine tumors when indicated. SSR-PET/CT is generally preferred. A 2018 systematic review of 15 studies with 679 patients comparing the diagnostic accuracy of SSR-PET with OctreoScan, 18FDG PET or CT/MRI, reported that SSR-PET was associated with greater sensitivity than OctreoScan (difference in sensitivity ranged from 14% to 56%) as well as CT and/or MRI (differences in sensitivity ranged from 12% to 49%).294 Multiple prospective trials confirm the overall superiority of 68Ga DOTATATE PET to somatostatin receptor scintigraphy. Several systematic reviews, a meta-analysis, and prospective studies of variable quality have consistently shown that 68Ga dotatate has a moderate to high diagnostic accuracy for the staging of de novo, recurrent, or suspected neuroendocrine cancer with a moderate to high positive likelihood ratio and a high negative likelihood ratio to exclude neuroendocrine cancer.294-299
64Cu-DOTATATE was also found to have non-inferior diagnostic accuracy (corrected sensitivity/specificity of 100% and 96.8%, respectively) compared to 68Ga-DOTATATE.300, 301
FDG-PET for staging of poorly differentiated neuroendocrine tumor remains controversial. In a limited number of small studies, FDG-PET appears to be useful in detecting poorly differentiated neuroendocrine tumors and well-differentiated neuroendocrine tumors with high Ki-67.302-304
MANAGEMENT
Imaging to assess disease response to therapy should be performed with the same modality used to detect the initial abnormality and the same modality should be used over time. For most cases, CT chest and abdominal ± pelvic multiphasic CT or MRI is sufficient. There is limited evidence for the use of SRT-PET for monitoring disease during treatment.
Somatostatin analog receptor imaging is vital prior to PRRT. Based on the increased sensitivity for detection of somatostatin receptors and expected change in management, 68Ga dotatate also appears to play a role prior to therapy. 68Ga dotatate changed management in 13%-60% of patients, with a wide variation depending on the clinical scenario in which the radiotracer is used. No study has compared the utility of SSTR-PET with alternative imaging modalities for predicting response to PRRT or somatostatin analog therapy.305
SURVEILLANCE
Poorly differentiated tumors have a higher risk of recurrent disease after definitive treatment; therefore, routine surveillance imaging may include CT chest, abdomen, and pelvis. Limited evidence supports the use of SRT-PET for monitoring disease after completion of treatment. The North American Neuroendocrine Tumor Society states, that SSTR PET should not be used routinely for surveillance.292
Ovarian Cancer – All Variants
Advanced imaging is considered medically necessary for the diagnostic workup and management of documented ovarian cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated when tumor markers or exam are considered unreliable and/or there is a high risk of recurrence. |
MRI abdomen and pelvis | Indicated | Indicated | Indicated when tumor markers or exam are considered unreliable and/or there is a high risk of recurrence. |
FDG-PET/CT | Indicated to direct management of indeterminate lesions detected by other imaging modalities | Indicated when standard imaging cannot be performed or is nondiagnostic for recurrent or progressive disease | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Ovarian cancer is the fifth most common cause of cancer-related death in women in the U.S. Ovarian tumors may arise from epithelial cells, germ cells, and sex cord-gonadal stroma. Epithelial ovarian cancers make up over 95% of ovarian cancers and are further classified as serous, mucinous, endometrioid, or clear cell carcinoma. Incidence increases with age; other risk factors include cigarette smoking, and BRCA gene mutations. Ovarian cancer most commonly presents with pain, bloating, or gastrointestinal symptoms, while more acute presentations from disseminated disease may include bowel obstruction, pulmonary complaints from pleural effusions, or venous thromboembolic disease.
DIAGNOSTIC WORKUP
Ovarian cancer is most commonly staged using the FIGO system, although the American Joint Committee on Cancer TNM system may also be utilized. Until more conclusive data is available, CT abdomen and pelvis with contrast remains the preferred imaging modality for staging. CT abdomen and pelvis has a reported accuracy of 77%. The positive predictive value for cancer nonresectability was 100% and the negative predictive value was 92%. Results of CT are comparable to MRI in terms of accuracy, positive predictive value, and negative predictive value: 78%, 91%, and 99%. In one study, no difference was seen between MRI and CT in detection of abdominal disease.306 In a second prospective study comparing ultrasound, CT, and MRI, CT and MRI were again found to be equivalent in detecting stage III/IV disease.307 In a smaller study, MRI outperformed CT for detection of small tumors in extrahepatic sites and was particularly advantageous for evaluating the peritoneum, mesentery, and bowel.308
FDG-PET/CT or MRI may be useful for indeterminate lesions if results will alter management.309 The use of PET for initial staging is not universally supported; sensitivity and specificity have been reported at 86% and 54%, respectively. False negatives can be seen with borderline tumors, early carcinomas, and adenocarcinomas and false positives occur in some benign conditions.310
MANAGEMENT
For stage I-IV after primary treatment, the NCCN recommends CT, MRI, PET/CT or PET as clinically indicated without modality preference (level of evidence category 2A).309 Imaging should be performed with oral and IV contrast (unless contraindicated) and rectal contrast as needed.
SURVEILLANCE
Based on a review of the Surveillance Epidemiology & End Results database, up to 95% of recurrences are detected by physical exam or rising cancer antigen (CA) 125.311 Studies using radiographic surveillance for ovarian cancer have reported the sensitivity and specificity of CT 40%-93% and 50%-98%, respectively.312 In a retrospective Italian study, recurrence in asymptomatic patients was detected by physician exam in 14.8%, by serum CA 125 in 23%, and by imaging in 27.2%. No difference was seen in survival with symptomatic or asymptomatic presentation at time or relapse.313 In a post-hoc analysis of the AURELIA trial (Avastin [Bevacizumab] Use in Platinum-Resistant Epithelial Ovarian Cancer), progression-free survival was improved with earlier recurrence detection, but no difference in overall survival was demonstrated.314 Additionally, Rustin et al. reported in a randomized trial that there was no evidence of a survival benefit with early treatment of relapse on the basis of a raised CA 125 concentration alone.315 While the Society of Gynecologic Oncology and the NCCN do not recommend routine use of surveillance imaging, it may be indicated when tumor markers are considered unreliable, the physical exam is unreliable, and/or there is a high risk of recurrence.309, 312
Pancreatic Cancer
The following criteria address all cancers originating in the pancreas other than neuroendocrine tumors.
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of documented pancreatic cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest | Indicated | Indicated | Indicated |
CT abdomen and pelvis | Indicated (note: usually CT abdomen pancreatic protocol is needed) | Indicated | Indicated |
MRI abdomen |
| Not indicated | Not indicated |
FDG-PET/CT |
|
| Not indicated |
Note: Imaging of the pancreas should include a dedicated pancreatic protocol CT (multi-detector computed tomography angiography using a dual-phase pancreatic protocol, with images obtained in the pancreatic and portal venous phase of contrast enhancement) or MRI if CT is contraindicated. MRI may also be used to clarify CT-indeterminate liver lesions or suspected pancreatic tumors not visible on CT.
Rationale
Pancreatic cancer is the fourth leading cause of cancer mortality in the U.S. The most common type of pancreatic cancer is adenocarcinoma, which accounts for 85% of pancreatic cancers. Diagnosis is rare prior to the age of 45 and the rate is slightly higher in females. Risk factors include genetic predisposition, smoking, and obesity. Presentation is variable and may include pain, jaundice, and cancer anorexia/cachexia syndrome.
DIAGNOSTIC WORKUP
Pancreatic cancer is staged using the American Joint Committee on Cancer TNM system. The Society of Abdominal Radiology and the American Pancreatic Association recommend a dedicated pancreatic CT, performed with multidetector CT angiography using a dual-phase pancreatic protocol.316 CT using this protocol has demonstrated sensitivity of 89%-97% for diagnosis and a positive predictive value for assessing resectability of 89%-100%. Although a high-quality CT abdomen may suffice in some circumstances, comparison studies have found that scans performed with pancreatic protocol have changed staging and management in up to 56% of cases.317
MRI is most commonly used as a problem-solving tool, particularly for CT-indeterminate liver lesions, when CT-occult pancreatic tumors are suspected or when contrast enhanced CT cannot be done.316 Accuracy of MRI abdomen is similar to that for CT with pancreatic protocol. In a 2016 meta-analysis reviewing different imaging modalities, the pooled sensitivity was 89% and the specificities were 90% and 89% for MRI and CT, respectively.318
PET/CT has been studied as an adjunctive staging modality. The sensitivity of detecting metastatic disease for PET/CT alone, standard CT alone, and the combination of PET/CT and CT were 61%, 57%, and 87%, respectively. PET/CT influenced the clinical management in 11% of cases.319 Treadwell et al. reported no statistically significant difference in sensitivity or specificity in a pooled analysis of six studies comparing PET scan to CT scan for initial treatment staging.318 A 2017 meta-analysis of 16 articles concluded that high pretreatment PET standardized uptake values predicted poorer event-free survival and overall survival.320
MANAGEMENT
There is limited data comparing imaging modalities for post-treatment assessment. One study found that multidetector CT underestimates resectability, but no additional studies exist assessing accuracy for evaluation of lymph node and systemic metastases. Limited information is available for MRI or PET/CT in this setting.321 In a pooled analysis of the phase III MPACT (Molecular Profiling-based targeted therapy in treating patients with Advanced solid Tumors) trial, response by PET after chemotherapy was associated with improved survival regardless of regimen used (11.3 vs 6.9 months; HR 0.56; P < .001).322
SURVEILLANCE
NCCN recommends surveillance every 3-6 months for 2 years, then every 6-12 months as clinically indicated, including CT chest and CT or MRI of abdomen and pelvis with contrast (category 2A recommendation).323
Paraneoplastic Syndrome
Advanced imaging is considered medically necessary for the diagnostic workup of paraneoplastic disease. Periodic surveillance of paraneoplastic disease is indicated when initial evaluation has not detected a primary tumor.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT neck CT chest CT abdomen and pelvis | Indicated | Further management based on primary cancer identified | Indicated |
FDG-PET/CT | Indicated for initial evaluation of individuals with paraneoplastic syndrome | Further management based on primary cancer identified | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Paraneoplastic disease is a rare manifestation of cancer that is not related directly to tumor involvement, metastases, or metabolic derangements. Autoantibodies have been identified as a cause in up to 60% of the recognized syndromes attributed to paraneoplastic disease.324 In many cases, symptoms occur prior to discovery of the primary tumor. The most common presentations are neurologic (central or peripheral), but paraneoplastic disease also manifests in muscle and other soft tissue. The most common malignancies associated with paraneoplastic disease are small cell lung cancer, thymoma, and hematologic cancers.325
DIAGNOSTIC WORKUP
PET/CT has been found to be more accurate than CT in the detection of occult malignancy associated with paraneoplastic syndrome. In a retrospective study, PET outperformed CT by 50%. The sensitivity and specificity of PET compared to CT were 80% and 67%, vs 30% and 71%, respectively.326 Another retrospective study from the same institution found that PET/CT detected an additional 18% of cancers in patients with CT-negative paraneoplastic disease.327 In a review and meta-analysis of 21 studies, PET imaging demonstrated high diagnostic accuracy and moderate to high sensitivity (81%) and specificity (86%) for detection of underlying malignancy in suspected paraneoplastic syndrome.328
SURVEILLANCE
The benefit of advanced imaging for surveillance of paraneoplastic syndrome without an identified malignancy has not been demonstrated. The European Federation of Neurological Sciences endorses continued surveillance with repeat screening every 6 months for up to 4 years.329
Penile, Vaginal, and Vulvar Cancers
Note: The following information primarily addresses squamous cell carcinomas of the vagina, vulva, and penis; however, applicability and coverage include all cancers originating in the vagina, vulva, and penis unless expressly addressed elsewhere in Oncologic Imaging. Specific imaging considerations are addressed below.
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented vaginal, vulvar, or penile cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated (note: for penile cancer especially useful with T1b or higher or palpable inguinal LN; for vulvar cancer especially useful with T2 or higher. Chest imaging can be performed either with CT or radiograph.) | Indicated | Indicated for penile cancer |
MRI pelvis | Indicated for vaginal or vulvar cancer | Indicated for vaginal or vulvar cancer | Not indicated |
FDG-PET/CT |
|
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Vaginal, vulvar, and penile cancers are relatively uncommon; the most common histologic subtype is squamous cell carcinoma, although adenocarcinoma is also seen in the vagina. Risk factors for developing genital cancers are human papillomavirus infection, human immunodeficiency virus infection, smoking, and exposure to diethylstilbestrol. The most common presentation is local symptoms such as bleeding, irritation, discharge, or skin changes.
DIAGNOSTIC WORKUP
Vaginal, vulvar, and penile cancers are staged using the American Joint Committee on Cancer TNM system.
In a retrospective study, MRI performed prior to surgery for vulvar cancer had a local staging accuracy of 83% and an overall staging accuracy of 69.4%, which increased to 75%-85% when combined with CT.330 Comparable findings regarding the utility of MRI for the diagnosis, local staging, and spread of disease of vaginal cancer have been reported in 2 small studies.331, 332 There is a lack of high-quality prospective studies evaluating PET/CT for staging vaginal and vulvar cancer. Cohn et al. found that PET/CT had sensitivity of 80%, specificity of 90%, and negative predictive value of 80% in identifying lymph node metastases; thus, PET/CT does not obviate the need for surgical staging.333 In the largest study (N = 50) comparing PET and conventional imaging data for vulvar and vaginal cancer, FDG PET/CT detected nodes suspicious for metastases in 35% of patients, as compared to MRI and CT, 13% and 7%, respectively. Distant metastases were seen in an additional 4% when compared to conventional CT, and overall resultant change in management occurred in 36% of cases.334 In a small prospective study (N = 23) of patients with vaginal cancer, PET detected lymph node involvement in 35% of patients compared to 17% for CT alone.335 The American College of Radiology Appropriate Use Criteria for staging and follow-up of vaginal cancer recommend CT abdomen/pelvis, MRI pelvis, or FDG-PET/CT for initial staging of vaginal cancer, and MRI pelvis or FDG-PET/CT for post-treatment evaluation. They state that these procedures are equivalent alternatives, but also note that data related to patients with primary vaginal cancer is limited.336 For vulvar cancer, they recommend MRI pelvis for patients with tumor >2 cm and >1 mm stromal invasion, or when the tumor involves or is in proximity to the urethra, vagina, or anus. For vulvar cancer recurrence, they recommend FDG-PET/CT as well, to facilitate treatment planning prior to pelvic exenteration.337
For penile cancer, imaging is not indicated for low-risk disease (Tis,Ta, T1a). Distant metastatic disease is rare and occurs in less than 4% of cases without bulky disease.335, 338 For intermediate to high risk (T1b, T2 or greater) and/or palpable inguinal lymph nodes, chest imaging should be performed in addition to CT abdomen and pelvis with contrast. Preoperative CT has a reported sensitivity of 95% and a specificity of 82%. In a study of 10 patients, MRI with lymphotropic nanoparticles had a sensitivity, specificity, positive predictive value, and negative predictive value of 100%, 97%, 81%, and 100%, respectively.339 There is insufficient data to support the routine use of PET/CT for staging of penile cancer. In a comparative study, the sensitivity of PET was 80% compared to 100% in MRI and specificities were equivalent.340 Another trial looking at 13 patients confirmed these findings.341 In a meta-analysis of 7 studies, PET had a pooled sensitivity and specificity of 80.9% and 92.4%. Sensitivity was 96.4% when inguinal lymph nodes were detected clinically, but fell to 56.5% when nodes were clinically negative.342
SURVEILLANCE
As most recurrences of vulvar and vaginal cancer are local, surveillance imaging is not indicated. In concordance with both National Comprehensive Cancer Network and Society of Gynecologic Oncology guidelines, imaging should only be performed when recurrence is suspected based on symptoms or exam findings.312, 343 For penile cancer, surveillance with CT may be performed.344
Prostate Cancer
Note: The following information addresses adenocarcinoma of the prostate; however, applicability and coverage include all cancers originating in the prostate unless expressly addressed in another Carelon imaging guideline. Specific imaging considerations are addressed below.
Advanced imaging is considered medically necessary for diagnostic workup and management of documented prostate cancer.
Imaging Study | Diagnostic Workup and Diagnosis | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and/or pelvis | Indicated for intermediate or high-risk disease | Indicated for intermediate or high-risk disease | Not indicated |
MRI pelvis including multiparametric prostate technique |
|
| Not indicated |
FDG-PET/CT | Not indicated | Not indicated | Not indicated |
18F Fluciclovine PET/CT or 11C Choline PET/CT | Not indicated |
| Not indicated |
PET/CT using 68Ga- or 18F-labeled radiotracers targeting prostate-specific membrane antigen (PSMA) | Indicated for unfavorable intermediate or high-risk disease with equivocal or nondiagnostic conventional imaging,2 when confirmation may inform decisions about prostatectomy and/or radiation therapy |
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
*Low-risk prostate cancer defined as Gleason score of 6, PSA less than 10 ng/mL, and stage T1 or T2a.
**Elevated PSA levels defined as > 3 ng/ml in patients 45-75 years or ≥ 4.0 ng/ml in patients 75 years or older
***If PSA <10 ng/ml, this criterion does not apply
1 “Biochemical recurrence/persistence” definition depends on prior treatment:
- Post-prostatectomy (PSA should be 0 after surgery):
- Persistence: Detection of a PSA higher than 0 within the first three months after surgery
- Recurrence: PSA initially undetectable, then rising PSA ≥ 0.2 ng/ml, with a second confirmatory level ≥ 0.2 ng/mL (American Urological Association definition)
- Post-radiation therapy:
- Recurrence: rise by ≥ 2 ng/mL above the nadir PSA (Radiation Therapy Oncology Group-American Society of Therapeutic Radiology and Oncology (RTOG-ASTRO) Phoenix Consensus)
2 Conventional imaging: Bone scan, CT Abdomen and/or Pelvis, MRI pelvis, or mpMRI (prostate MRI).
3 External beam radiation therapy ± androgen deprivation therapy after prostatectomy OR radical prostatectomy, cryosurgery, high-intensity focused ultrasound, or brachytherapy after external beam radiation therapy.
Rationale
Prostate cancer is the most common malignancy among men in the U.S. The most common histological subtype is adenocarcinoma.
DIAGNOSIS
Prostate cancer is staged using the American Joint Committee on Cancer TNM system. Professional society guidelines base recommendations for MRI and repeat biopsy on PSA doubling time, thus serial PSA levels are important in clinical decision making. Screening and early detection guidelines are based on a PSA level between 3 and 10 ng/mL.345
The prospective multicenter, randomized Phase III PRECISION (PRostate Evaluation for Clinically Important Disease: Sampling Using Image-guidance Or Not?) trial compared mpMRI-targeted biopsy to standard transrectal ultrasound-guided biopsy in 500 men with clinical suspicion of prostate cancer (elevated PSA, abnormal digital rectal exam, or both) who had not undergone biopsy previously. The mpMRI-targeted evaluation was able to detect prostate cancer in 38% of men compared with 26% in the standard biopsy group (P = 0.005). Fewer men in the mpMRI group were diagnosed with clinically insignificant cancers (defined as Gleason 6).346
DIAGNOSTIC WORKUP
Advanced imaging is not indicated for very low and low-risk groups. Multiparametric MRI (mpMRI, referring to prostate MRI protocol within this guideline) can be used in the staging and characterization of prostate cancer. CT is generally not sufficient to evaluate the prostate gland, but can be used for initial evaluation of nodal and/or visceral metastatic disease. In a meta-analysis of 75 studies comparing CT to MRI for initial staging, the pooled data for extracapsular extension and T3 detection showed sensitivity and specificity of 57% and 91% for CT vs 61% and 88% for MRI.347 For detection of lymph node metastases, the differences in performance of CT and MRI were not statistically significant.348 Findings from another prospective study confirmed the equivalency of CT and MRI for lymph node staging.349 For intermediate risk or above, abdominal imaging with contrast should be performed if the risk of pelvic lymph node metastases is greater than 10%.
While PSMA-PET has been found to be more accurate than CT and bone scan in assessing pelvic nodal and distant metastases, it was not sensitive enough to forego pelvic lymph node dissection in those with high risk disease.350, 351 Multiple high quality guidelines still endorse conventional imaging for initial staging, acknowledging evidence supporting its use for equivocal findings. A guideline from the American Urological Association (AUA) and the American Society for Radiation Oncology (ASTRO) makes a strong evidence-based recommendation for bone scan and mpMRI or CT scan for initial evaluation, suggesting that molecular imaging may be obtained in high-risk patients with negative conventional imaging.352 The American Society of Clinical Oncology (ASCO) suggests the use of next-generation imaging “when conventional imaging (defined as CT, bone scan, and/or prostate MRI) is negative in patients with a high risk of metastatic disease,” and also for clarification “when conventional imaging is suspicious or equivocal,” though in both cases they note that prospective data is limited.353 Additionally, a guideline from EAU, EANM, ESTRO, ISUP, and SIOG makes a strong recommendation that “treatment should not be changed based on PSMA PET/CT findings, in view of current available data,” noting that while PSMA PET/CT has been shown to increase extraprostatic disease detection in 32% of cases, there is a lack of data regarding impact on outcomes.345 Similarly, though the NCCN Panel “does not feel that conventional imaging is a necessary prerequisite to PSMA-PET” cited evidence related to initial staging is limited while also noting that “PET/CT or PET/MRI results may change treatment but may not change oncologic outcome.”354
FDG-PET is not indicated, as physiologic activity in the bladder obscures tumor detection.355 Additionally, there is limited evidence to support 11C-choline and 18F fluciclovine PET for initial staging of prostate cancer.
MANAGEMENT
For active surveillance, the NCCN recommends mpMRI be considered for suspected anterior and/or aggressive cancers when PSA increases and prostate biopsies are negative.354
Studies of 11C-choline, 18F-fluciclovine, and prostate-specific membrane antigen (PSMA) PET support their accuracy in evaluating biochemical recurrence (BCR).356-358 The prospective FALCON (18F-Fluciclovine PET/CT in biochemicAL reCurrence Of Prostate caNcer) trial found the detection ability of 18F-fluciclovine PET after radical treatment (prostatectomy or radiation therapy/brachytherapy) broadly proportional to PSA level (one-third scans positive when PSA ≤ 1 ng/mL, compared to 93% positive with PSA greater than 2 ng/mL).359 Results were similar to that of the previous LOCATE study (patient-level detection of 56% with overall 63% management changes, compared with 57% and 59%, respectively), the latter limited to patients with negative or equivocal conventional imaging before 18F-fluciclovine PET/CT. Where 18F-fluciclovine guided salvage therapy, the PSA response rate was higher than when 18F-fluciclovine was not involved (15 out of 17 [88%] vs 28 out of 39 [72%]).359 68-Ga PSMA PET was found to have higher diagnostic accuracy than other radiotracers for biochemical recurrence (overall detection rate of 74%) by one systematic review, especially at low PSA values, resulting in management change in 53% of patients.356 A systematic revew and network meta-analysis of 12 studies encompassing eight radiotracers found comparable performance of 68Ga-PSMA-11 and 18F-DCFPyL.360 Another systematic review, this including 43 studies and 5832 patients, found no difference in detection rate between PSMA tracers based on PSA level, doubling time, or velocity.356
PSMA imaging is needed for patient selection prior to treatment of metastatic castration-resistant prostate cancer (mCRPC) with the radioligand therapeutic agent lutetium Lu 177 vipivotide tetraxetan. In the randomized, multi-center trial demonstrating prolonged imaging-based progression-free survival and overall survival of this treatment, all patients were required to have received at least one AR pathway inhibitor, and 1 or 2 prior taxane-based chemotherapy regimens.361
Although there are some studies showing a correlation between MRI stability and Gleason stability, the American Urological Association/American Society for Radiation Oncology 2022 Guidelines for Clinically Localized Prostate Cancer (endorsed by the Society of Urologic Oncology) do not currently recommend serial MRI for surveillance.352, 362-364
Sarcomas of Bone/Soft Tissue
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of documented sarcomas of bone, cartilage, connective tissue, and other soft tissue (including gastrointestinal stromal tumors).
Bone Sarcoma
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT or MRI primary site | Indicated | Indicated | Indicated (note: especially useful for Ewing sarcoma and osteosarcoma in first 5 years) |
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated |
MRI cervical, thoracic, and lumbar spine | Indicated (note: especially useful for chordoma) | Indicated for evaluation of suspected or known spinal metastases | Not indicated |
MRI pelvis | Indicated (note: especially useful for Ewing sarcoma) | Indicated for evaluation of suspected or known pelvic metastases | Not indicated |
FDG-PET/CT |
|
| Not indicated |
Soft Tissue Sarcoma
Includes head/neck, extremity/body wall, retroperitoneal or intra-abdominal sites, and desmoid tumors
Imaging Study | Diagnostic Workup | Management | Screening & Surveillance |
---|---|---|---|
CT or MRI of primary site | Indicated | Indicated | Indicated (note: especially useful for Stage II/III) |
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated |
MRI spine | Indicated (note: especially useful for myxoid/round cell liposarcoma) | Indicated for evaluation of suspected or known spinal metastases | Not indicated |
FDG-PET/CT |
|
| Not indicated |
Gastrointestinal stromal tumor (GIST)
Imaging Study | Diagnostic Workup | Management | Screening & Surveillance |
---|---|---|---|
CT chest, abdomen, and pelvis | Indicated | Indicated | Indicated |
MRI of abdomen and/or pelvis | Indicated | Indicated | Indicated |
FDG-PET/CT |
|
| Not indicated |
Rationale
Sarcomas are a heterogeneous group of cancers which arise from mesenchymal cells and occur in many different types of tissue, most commonly bone, muscle, and cartilage. Gastrointestinal stromal tumors (GISTs) are the most common soft tissue sarcomas of the GI tract. Risk factors are not well characterized but may include genetic predisposition, prior chemotherapy or radiation therapy, and environmental exposure.
DIAGNOSTIC WORKUP
Sarcomas are staged using the American Joint Committee on Cancer TNM system. Imaging of the primary tumor is important to assess resectability and local invasion. CT or MRI may be done as part of initial workup. However, MRI is often preferred for imaging the primary tumor due to superior resolution of tumor versus surrounding muscle and neurovascular bundles, and for delineating disease involving the pelvis.365-370 In a large prospective trial comparing CT and MRI imaging in both soft tissue sarcomas and bone cancer, the accuracy of local staging was not statistically different between the 2 modalities.371
Imaging of the lungs is critical, as this is the most common site of metastases. Additional imaging recommendations for soft tissue sarcoma vary by subtype. For Ewing sarcoma and osteosarcoma, NCCN recommends whole body PET/CT and/or bone scan as part of initial workup (level of evidence category 2A).372 A meta-analysis showed a pooled sensitivity of 96% and pooled specificity of 92% for staging and restaging Ewing sarcoma when PET was combined with conventional imaging.373 In another meta-analysis of 42 trials, PET had a pooled sensitivity and specificity of 96% and 79% for differentiating primary bone sarcomas from benign lesions, 92% and 93% for detecting recurrence, and 90% and 85% for detecting distant metastasis, respectively.374
MANAGEMENT
PET has been shown to be a useful adjunct in assessing treatment response to neoadjuvant therapy, as well as an indicator of prognosis.374-376 A review and meta-analysis of 11 studies confirmed the prognostic value of PET response to overall survival in soft tissue and bone sarcoma.375, 376
SURVEILLANCE
Imaging of the primary site for soft tissue sarcoma is based on the risk of recurrence and the accessibility of the primary cancer site.377 Particularly for younger patients where the radiation risks from multiple CT examinations might cause some concern, the follow up can be performed with MRI of the abdomen and pelvis supplemented with CT thorax.
Testicular Cancer
Advanced imaging is medically necessary for the diagnostic workup, management, and surveillance of documented testicular cancers.
Seminoma
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated (note: chest X-ray usually sufficient but especially useful for positive abdominal CT or abnormal chest radiographs) | Indicated (note: especially useful for IIA, IIB, IIC, III after chemotherapy) | Indicated (note: chest X-ray usually sufficient) |
FDG-PET/CT | Indicated when standard imaging cannot be performed or is nondiagnostic for metastatic disease |
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Nonseminoma
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated | Indicated (note: especially useful for IIA, IIB, IIC, III after chemotherapy. Chest X-ray is an option) | Indicated (note: chest X-ray usually sufficient) |
FDG-PET/CT | Not indicated | Not indicated | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Germ cell tumors (GCTs) are the most common type of testicular cancer and are broadly divided into seminomatous and nonseminomatous subtypes. Risk factors include cryptorchidism, family history, and ethnicity. The most common presentation is testicular pain or a palpable mass.
DIAGNOSTIC WORKUP
GCTs are staged using the American Joint Committee on Cancer TNM system. CT abdomen and pelvis with contrast is primarily used to evaluate the retroperitoneal lymph nodes.378 A CT Chest with contrast is indicated if the abdominal/pelvic CT or chest x-ray shows evidence of metastatic disease.
In direct comparisons, MRI has not shown an advantage over CT for accuracy of staging.379, 380 Per NCCN, PET scans should not be used routinely to stage testicular GCTs. In a prospective study, CT imaging showed sensitivity, specificity, positive predictive value, and negative predictive value of 41%, 95%, 87%, and 67% compared with PET/CT 66%, 98%, 95%, and 78%, respectively. The poor negative predictive value of PET limits its usefulness in initial staging.381 In another prospective trial in which high risk stage I NSGCT was imaged with PET, only 23 of 110 patients were found to have PET avid disease, and 33 of 88 PET-negative patients had disease relapse.382
MANAGEMENT
PET/CT has higher positive and negative predictive values for identifying residual viable seminomatous tumors compared to CT, especially in the setting of a radiographically persistent mass and normal tumor markers. In the prospective multicenter SEMPET trial, patients with seminoma, negative tumor markers, and at least a 1 cm residual mass following completion of chemotherapy were imaged with PET and CT of the abdomen and pelvis. When compared to CT, PET had superior sensitivity and specificity (80% and 100% vs 74% and 70%) as well as positive predictive value and negative predictive value (100% and 96% vs 37% and 92%).383 Accuracy is improved and false-negative results decreased when PET/CT is used to evaluate residual masses at least 3 cm in size.384
In patients with NSGCT and residual mass > 1 cm after primary chemotherapy, retroperitoneal lymph node dissection or surgical resection of the residual mass should be strongly considered as opposed to continued radiographic surveillance. PET has limited ability to differentiate residual non-seminomatous tumor from radiation necrosis and fibrosis. NCCN notes “PET has no role in assessing treatment response and residual masses following chemotherapy in patients with nonseminoma.” In a prospective German multicenter trial, PET used for detection of residual NSGCT after chemotherapy only had an accuracy of 56% (compared to CT scan 55% and serum tumor markers 56%).385
Carelon guidelines are in accordance with the National Comprehensive Cancer Network (NCCN) Guidelines for Testicular Cancer.386
SURVEILLANCE
Seminomas tend to recur within the first 14 months and nonseminomas within the first 2 years.387 Carelon guidelines are in accordance with the NCCN Guidelines for Testicular Cancer and European Society for Medical Oncology-EURACAN guidelines. 386, 388
Cancers of the Pleura, Thymus, Heart, and Mediastinum
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of documented pleural malignancies, cancers of the thymus, heart, and mediastinum.
Imaging Study | Diagnostic Workup | Management | Surveillance |
CT chest CT abdomen and pelvis | Indicated | Indicated | Indicated |
MRI chest | Indicated (note: for thymoma and thymic carcinoma and as an adjunct to CT chest for malignant pleural mesothelioma) | Indicated (note: for thymoma and thymic carcinoma and as an adjunct to CT chest for malignant pleural mesothelioma) | Not indicated |
FDG-PET/CT |
|
| Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Cancers of the pleura, thymus, heart, and mediastinum represent a heterogeneous group of diseases that can be either benign or malignant. The most common malignancies in this group are malignant pleural mesothelioma, thymoma, and thymic carcinoma. Myasthenia gravis is a paraneoplastic syndrome often associated with thymic neoplasms. Patients with mediastinal masses often present with symptoms resulting from direct compression of mediastinal structures, which may include cough, shortness of breath, superior vena cava syndrome, or Horner’s syndrome. Malignant pleural mesothelioma may present with nonspecific pulmonary symptoms or systemic symptoms due to distant metastases.
DIAGNOSTIC WORKUP
MRI has been shown to be superior to CT for evaluating solitary foci of chest wall invasion, endothoracic fascial involvement, and diaphragmatic muscle invasion.389 MRI should be considered for suspected chest wall, spinal, diaphragmatic, or vascular involvement based on CT. The American College of Radiology Appropriate Use Criteria for imaging of mediastinal masses recommends the use of MRI in the workup of mediastinal masses, citing benefits over CT or PET/CT including more specific tissue characterization and superior detection of invasion across tissue planes.390 Although not highly accurate at staging T4 disease or N2 lymphadenopathy, PET plays a role in detection of extra-thoracic disease, eliminating the need for surgery in 16%-40% of patients.391-395 For thymoma or thymic carcinoma, MRI chest may help differentiate benign cysts and thymoma from thymic carcinoma, thus avoiding the need for surgery.396, 397 PET can be used for initial staging to differentiate low grade thymoma from FDG-avid thymic carcinoma.397, 398
MANAGEMENT
The American Society for Clinical Oncology recommends CT with assessment of response of malignant pleural mesothelioma based on the RECIST criteria.
SURVEILLANCE
American Society for Clinical Oncology and the National Comprehensive Cancer Network (NCCN) guidelines do not address surveillance imaging for asymptomatic malignant pleural mesothelioma. In most cases, CT should provide adequate information for routine surveillance.
Carelon Oncologic Imaging guidelines are in concordance with the NCCN Guidelines® for Thymomas and Thymic Carcinomas, NCCN Guidelines® for Malignant Pleural Mesothelioma, and the American Society for Clinical Oncology guidelines for evaluation of malignant pleural mesothelioma.399-401
Thyroid Cancer
Advanced imaging is considered medically necessary for the diagnostic workup, management, and surveillance of documented thyroid cancer.
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT neck | Indicated | Indicated | Indicated |
CT chest CT abdomen and pelvis | Indicated (note: especially useful for fixed, bulky, or substernal lesions and anaplastic thyroid cancer) | Indicated (note: especially useful based on known site of metastases or as clinically indicated for medullary thyroid cancer with calcitonin > 150 pg/mL AND anaplastic thyroid cancer) | Indicated |
MRI neck | Indicated | Indicated when used in place of CT for initial treatment strategy | Not indicated |
FDG-PET/CT |
|
| Not indicated |
Somatostatin receptor (SSR) PET/CT | Indicated for medullary carcinoma | Indicated for suspected recurrent medullary carcinoma when detectable basal calcitonin or elevated CEA, and standard imaging is negative | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Thyroid cancer is the most common endocrine cancer in the U.S. The most common histologic subtypes are papillary and follicular carcinoma, which together account for 95% of all thyroid cancers. Risk factors include environmental factors, radiation exposure, and genetic predisposition (in medullary thyroid cancer). The most common presentation is a palpable mass.
DIAGNOSTIC WORKUP
Thyroid cancer is staged using the American Joint Committee on Cancer TNM system. Thyroid cancer frequently involves cervical lymph nodes, and the addition of ultrasound can result in detection and alteration in management in up to 40% of patients.402, 403 Compared to CT, high-resolution ultrasound is more accurate for evaluation of extrathyroidal tumor extension and at least equivalent for evaluation of lateral lymph nodes.404 Sensitivity, specificity, and diagnostic accuracy of ultrasound were 77%, 70%, and 74%, respectively, while those for CT were 62%, 79%, and 68%.405 MRI and PET have relatively low sensitivities ranging from 30%-40%.406, 407 An evidence-based guideline from the American Thyroid Association makes a strong recommendation for cross-sectional imaging in the initial tumor staging workup, including CT neck, chest, abdomen, and pelvis (or MRI). They also recommend the use of FDG-PET/CT, but state that bone scan can be obtained to evaluate for bony metastases in the absence of PET imaging.408
For dedifferentiated thyroid cancer, PET is indicated. Although there is a lack of prospective evidence, PET has been shown to detect metastatic disease not identified by conventional imaging in 35% of patients.409 Change in management based on PET imaging findings can be as high as 25%-50%.410
MANAGEMENT
For follow up of well-differentiated thyroid cancer, CT or MRI is not indicated unless there is clinical evidence of recurrence. Patients with high-risk features generally undergo additional imaging and/or treatment with radioactive iodine. For suspected iodine non-avid papillary, follicular, or oncocytic carcinoma, PET may be useful. The overall accuracy, sensitivity, and specificity for PET/CT in I-131 negative patients were 93%, 93%, and 81%, respectively.411
For suspected recurrence of medullary thyroid cancer, a study comparing several imaging modalities found that CT was superior to PET for evaluation of metastatic lung and mediastinal lymph node involvement, with a reported sensitivity and specificity for CT of 35% and 31%, respectively, versus 15% and 20% for PET. Detection of liver metastases with MRI, CT, ultrasound, and PET showed accuracy rates of 49%, 44%, 41%, and 27%, respectively, while bone metastases were better detected using bone scan or MRI (40%) as compared to PET (35%).412 In a review of PET for evaluation of recurrent anaplastic thyroid cancer, higher sensitivity (66% to 100%) and specificity (79% to 90%) were seen when compared to conventional imaging modalities.413
Carelon Oncologic Imaging guidelines for thyroid cancer are in concordance with the National Comprehensive Cancer Network Guidelines for Thyroid Carcinoma as well as the American Thyroid Association Practice Guidelines.414, 415
SURVEILLANCE
Biochemical monitoring remains the most vital component for surveillance of differentiated thyroid cancer; although conventional imaging may also be considered when clinically indicated. Both the American Thyroid Association and National Comprehensive Cancer Network do give consideration to a single exam after completion of therapy in intermediate and high risk differentiated thyroid cancer patients. The value of continued monitoring if no evidence of disease is seen is controversial.407, 414
Uterine Cancer
Advanced imaging is considered medically necessary for the diagnostic workup and management of documented uterine cancer (including uterine sarcoma).
Imaging Study | Diagnostic Workup | Management | Surveillance |
---|---|---|---|
CT chest CT abdomen and pelvis | Indicated (note: chest X-ray usually sufficient unless abnormal chest X-ray OR high-risk patient) | Indicated | Indicated for uterine sarcoma ONLY |
MRI pelvis | Indicated (note: especially useful prior to fertility-sparing treatment) | Indicated | Not indicated |
FDG-PET/CT | Indicated when standard imaging cannot be performed or is nondiagnostic for extent of metastatic disease | Indicated when standard imaging cannot be performed or is nondiagnostic for recurrent or progressive disease | Not indicated |
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Uterine cancer is the most common gynecologic cancer and fourth most common cancer among women in the U.S. The most common type of uterine cancer is endometrial, which originates in the uterine lining. Risk factors include exposure to estrogen, obesity, and genetic predisposition. The most common presentation is abnormal bleeding; the cancer may also be found incidentally on exam. Over 80% of endometrial cancers are confined to the uterus upon discovery. The initial staging of patients with suspected endometrial cancer includes local imaging with endovaginal ultrasound or MRI pelvis.
DIAGNOSTIC WORKUP
The staging system most widely adopted for uterine cancer is the International Federation of Gynecology and Obstetrics (FIGO) system, although the American Joint Committee on Cancer TNM system is also used. MRI pelvis is the preferred modality for assessing the extent of local disease and extension into the cervix.111, 416 For fertility-sparing therapy, an MRI pelvis is indicated prior to hormonal therapy and dilatation and curettage; a review comparing MRI to transvaginal ultrasound reported better sensitivity for evaluating myometrial invasion with MRI although statistically the two exams were equivalent.417 When evaluation of lymph nodes is required, both CT and MRI provide similar sensitivity and specificity.418, 419 In several small studies, PET has been shown to be equivalent or moderately better for detecting nodal disease when compared to MRI and CT; however, these differences rarely affect the decision for lymphadenectomy.420-425
As the majority of endometrial cancers are confined to the uterus (75%) and lymph nodes (10%), systemic imaging is reserved for high-risk patients.426 In an international prospective trial, the negative predictive value for low-risk endometrial cancer was 97%.427 There is insufficient data to recommend PET/CT for routine assessment. Based on the National Comprehensive Cancer Network (NCCN) uterine cancer guidelines, European Society for Medical Oncology-European Society of Gynecological Oncology-European Society for Therapeutic Radiology and Oncology Consensus, and American College of Radiology guidelines, additional imaging for metastatic workup is optional.187, 278, 428
MANAGEMENT
Follow-up imaging should be guided by patient symptoms, risk assessment, and clinical concern for recurrent or metastatic disease. For patients with endometrial carcinoma who have undergone fertility-sparing treatment, MRI pelvis with contrast is preferred after 6 months of failed medical therapy, especially if considering further fertility-sparing approaches. In a small prospective study from Korea, PET for suspected disease recurrence had a sensitivity, specificity, accuracy, positive predictive value, and negative predictive value of 100%, 83.3%, 96%, 95%, and 100%, respectively. PET/CT detected 3/24 (12.5%) recurrences in patients with elevated tumor markers but negative CT abdomen and pelvis findings.429
SURVEILLANCE
Following treatment for uterine sarcoma specifically, the NCCN recommends CT of the Chest, Abdomen and Pelvis every 3-6 months for the first 3 years, and then every 6-12 months for the next 2 years.14 Otherwise, the National Comprehensive Cancer Network, American College of Radiology, and Society of Gynecologic Oncology do not recommend routine use of surveillance imaging.278, 312, 428
The most important component for surveillance of asymptomatic uterine cancer is physician history and physical with vaginal cytology, as the vaginal cuff is the most common site of recurrence. Cancer antigen (CA) 125 may be used if initially elevated. In a systematic review by Fung et al., the overall risk of recurrence was 13% for all patients and 3% or less for patients at low risk. Approximately 70% of all recurrences were symptomatic. 430 In a retrospective study, recurrences in high-grade endometrial carcinomas were discovered by symptoms 56% of the time and physical exam 18% of the time. Surveillance CT only detected 15% of asymptomatic recurrences.431
Limited data is available for MRI and PET/CT in surveillance of asymptomatic patients.312 In a small prospective study, PET detected asymptomatic uterine cancer recurrence in only 4% of patients.429 A retrospective study evaluating adherence to Society of Gynecological Oncology guidelines resulted in an appreciable decline in CT imaging, CA 125, and clinical exams with no effect on outcomes.432
Suspected or Known Metastases
Advanced imaging is considered medically necessary for diagnostic workup, management, and surveillance of patients with a documented malignancy when clinical evaluation suggests metastatic disease.
Imaging Study | Diagnostic Workup | Management | Surveillance |
CT or MRI brain | Indicated for suspected brain or skull metastases, including high-risk staging (note: exam should be done with contrast; MRI brain preferred) | Indicated | Not indicated |
CT neck CT chest CT abdomen and pelvis | Indicated (note: refer to specific cancer section for guidance) | Indicated (note: refer to specific cancer section for guidance) | Indicated (note: refer to specific cancer section for guidance) |
MRI abdomen | See “Focal liver lesion” in Abdominal Imaging |
| Not indicated |
MRI axial skeleton (cervical, thoracic, or lumbar spine) | Indicated for evaluation of suspected or known vertebral or intradural metastases | Indicated for evaluation of suspected or known vertebral or intradural metastases | Not indicated |
MRI appendicular skeleton (pelvis, lower or upper extremity) |
|
| Not indicated |
FDG-PET/CT | Refer to specific tumor type indications | Refer to specific tumor type indications | Not indicated |
NaF PET/CT | When performed as part of coverage under evidence determination (CED) in Medicare beneficiaries | When performed as part of coverage under evidence determination (CED) in Medicare beneficiaries | When performed as part of coverage under evidence determination (CED) in Medicare beneficiaries |
Note: Criteria for the evaluation of known or suspected metastasis in specific tumor type indications supersede these criteria. These criteria should be used in patients with documented malignancy and with known or suspected metastatic disease when no criteria exist within the more specific tumor type indication
Note: MRI is considered medically necessary when criteria are met and CT is contraindicated or expected to be suboptimal (due to contrast allergy or anticipated contrast nephrotoxicity).
Rationale
Cancer metastasis is a leading cause of morbidity and accounts for approximately 90% of cancer-related mortality.433 Metastasis involves the spread of cancer cells from the primary tumor to surrounding tissues and to distant organs through direct extension, blood, or lymphatics. The rate at which cancers metastasize varies greatly based on initial stage and cancer type.
DIAGNOSTIC WORKUP
In patients with biopsy-proven malignancy, a thorough history and physical exam, laboratory evaluation, and/or imaging may prompt concern for metastases. Symptoms may vary according the specific area of organ involvement or biochemical derangement.
- Lymph nodes: lymphadenopathy
- Lungs: cough, hemoptysis, shortness of breath
- Liver: hepatomegaly, nausea, jaundice, pain, elevated liver enzymes
- Bones: pain and fracture
- Brain: focal neurological deficit, cognitive dysfunction, headaches, seizures, ataxia
When metastases are clinically suspected, localized imaging is often warranted. Imaging of the body should be targeted to the suspected area of metastases as opposed to simultaneous ordering of multiple studies. For confirmation and initial management of metastatic disease to the liver (especially when liver-directed therapy or surgery is contemplated), MRI Abdomen (with hepatic contrast protocol) is preferred over CT (and PET/CT) to assess the exact number and distribution of metastatic foci for local treatment planning.434 Appropriateness of additional imaging is dependent on the results of the lead study.
In patients with suspected brain metastases, both MRI and CT imaging with contrast may be used to evaluate CNS metastases; however, MRI is the preferred exam. Multiple studies have shown that contrast-enhanced MRI is more sensitive for detection of brain metastases as well as differentiating from primary CNS cancer than both CT imaging and non-contrast MRI.435 436, 437
In patients with suspected bone metastases, imaging studies may include plain radiographs, CT imaging, MRI imaging or PET imaging. Preliminary radiographs should be obtained for the distal extremities (hands/feet) as isolated metastatic disease presenting at these sites is less likely than within the axial and proximal appendicular skeleton, and findings may point to a different source for symptoms. In patients where there is concern for impending non-vertebral fracture or vertebral metastases, imaging should include a CT or MRI. MRI remains the imaging modality of choice due to its greater sensitivity to CT for detection of metastases, better delineation of the extent of tumor, and particularly its usefulness in patients with spine metastases to evaluate the extent of medullary and extraspinal disease.438-441 MRI can also be used to distinguish benign from malignant compression fractures with a sensitivity and specificity of over 90%.442, 443 In 2011 and 2017 meta-analyses comparing MRI, CT, PET, and bone scintigraphy, the sensitivity of MRI and PET were both statistically better than CT imaging and bone scintigraphy. On a per-patient basis, the pooled sensitivity and specificity estimates for PET, CT, MRI and BS were 89.7%, 72.9%, 90.6%, 86.0% and 96.8%, 94.8%, 95.4% and 81.4% respectively.444, 445 In patients where disseminated, non-vertebral metastases are suspected, plain films, bone scintigraphy, and PET are all reasonable choices. Additional guidance may be found in the specific cancer section.
MANAGEMENT
For patients with either active disease or localized disease in remission, follow-up frequency should be determined by clinical need with additional diagnostic tests based on symptomatology. In general terms, imaging used in the initial detection of the cancer may be used to assess for treatment response.
SURVEILLANCE
Refer to specific cancer section for guidance.
References
1. AJCC cancer staging manual. 8th ed. Amin MB, editor-in-chief, Edge SB, [and others], editors. Chicago, IL: American College of Surgeons; 2018.
2. Carbone PP, Kaplan HS, Musshoff K, et al. Report of the committee on Hodgkin’s disease staging classification. Cancer Res. 1971;31(11):1860-1.
3. Juweid ME, Stroobants S, Hoekstra OS, et al. Use of positron emission tomography for response assessment of lymphoma: consensus of the Imaging Subcommittee of International Harmonization Project in Lymphoma. J Clin Oncol. 2007;25(5):571-8.
4. Benedet JL, Bender H, Jones H, 3rd, et al. FIGO staging classifications and clinical practice guidelines in the management of gynecologic cancers. FIGO Committee on Gynecologic Oncology. Int J Gynaecol Obstet. 2000;70(2):209-62.
5. Cheson BD, Fisher RI, Barrington SF, et al. Recommendations for initial evaluation, staging, and response assessment of Hodgkin and non-Hodgkin lymphoma: the Lugano classification. J Clin Oncol. 2014;32(27):3059-68.
6. Therasse P, Arbuck SG, Eisenhauer EA, et al. New guidelines to evaluate the response to treatment in solid tumors. European Organization for Research and Treatment of Cancer, National Cancer Institute of the United States, National Cancer Institute of Canada. J Natl Cancer Inst. 2000;92(3):205-16.
7. Cho N, Han W, Han BK, et al. Breast cancer screening with mammography plus ultrasonography or magnetic resonance imaging in women 50 years or younger at diagnosis and treated with breast conservation therapy. JAMA Oncology. 2017;3(11):1495-502.
8. Brennan S, Liberman L, Dershaw DD, et al. Breast MRI screening of women with a personal history of breast cancer. AJR Am J Roentgenol. 2010;195(2):510-6.
9. Nelson HD, Pappas M, Cantor A, et al. Harms of breast cancer screening: systematic review to update the 2009 U.S. Preventive Services Task Force recommendation. Ann Intern Med. 2016;164(4):256-67.
10. Melnikow J, Fenton JJ, Whitlock EP, et al. Supplemental screening for breast cancer in women with dense breasts: a systematic review for the U.S. Preventive Services Task Force. Ann Intern Med. 2016;164(4):268-78.
11. Degnim AC, Visscher DW, Berman HK, et al. Stratification of breast cancer risk in women with atypia: a Mayo cohort study. J Clin Oncol. 2007;25(19):2671-7.
12. Zhou WB, Xue DQ, Liu XA, et al. The influence of family history and histological stratification on breast cancer risk in women with benign breast disease: a meta-analysis. J Cancer Res Clin Oncol. 2011;137(7):1053-60.
13. Friedlander LC, Roth SO, Gavenonis SC. Results of MR imaging screening for breast cancer in high-risk patients with lobular carcinoma in situ. Radiology. 2011;261(2):421-7.
14. Sung JS, Malak SF, Bajaj P, et al. Screening breast MR imaging in women with a history of lobular carcinoma in situ. Radiology. 2011;261(2):414-20.
15. Raikhlin A, Curpen B, Warner E, et al. Breast MRI as an adjunct to mammography for breast cancer screening in high-risk patients: retrospective review.[Erratum appears in AJR Am J Roentgenol. 2015 May;204(5):1137; PMID: 25905954]. AJR Am J Roentgenol. 2015;204(4):889-97.
16. Riedl CC, Luft N, Bernhart C, et al. Triple-modality screening trial for familial breast cancer underlines the importance of magnetic resonance imaging and questions the role of mammography and ultrasound regardless of patient mutation status, age, and breast density. J Clin Oncol. 2015;33(10):1128-35.
17. Hodgson DC, Cotton C, Crystal P, et al. Impact of early breast cancer screening on mortality among young survivors of childhood Hodgkin’s lymphoma.[Erratum appears in J Natl Cancer Inst. 2016 Apr;108(4). pii: djw102. doi: 10.1093/jnci/djw102; PMID: 27032726]. J Natl Cancer Inst. 2016;108(7).
18. Expert Panel on Breast Imaging: Weinstein SP, Slanetz PJ, Lewin AA, et al. ACR Appropriateness Criteria® supplemental breast cancer screening based on breast density. J Am Coll Radiol. 2021;18(11S):S456-S73.
19. Expert Panel on Breast Imaging: Brown A, Lourenco AP, Niell BL, et al. ACR Appropriateness Criteria® transgender breast cancer screening. J Am Coll Radiol. 2021;18(11S):S502-S15.
20. Hagen AI, Kvistad KA, Maehle L, et al. Sensitivity of MRI versus conventional screening in the diagnosis of BRCA-associated breast cancer in a national prospective series. Breast. 2007;16(4):367-74.
21. Evans DG, Howell A. Are we ready for online tools in decision making for BRCA1/2 mutation carriers? J Clin Oncol. 2012;30(5):471-3.
22. Leach MO, Boggis CR, Dixon AK, et al. Screening with magnetic resonance imaging and mammography of a UK population at high familial risk of breast cancer: a prospective multicentre cohort study (MARIBS).[Erratum appears in Lancet. 2005 May 28-Jun 3;365(9474):1848]. Lancet. 2005;365(9473):1769-78.
23. Sardanelli F, Podo F, Santoro F, et al. Multicenter surveillance of women at high genetic breast cancer risk using mammography, ultrasonography, and contrast-enhanced magnetic resonance imaging (the high breast cancer risk italian 1 study): final results. Invest Radiol. 2011;46(2):94-105.
24. Warner E, Messersmith H, Causer P, et al. Systematic review: using magnetic resonance imaging to screen women at high risk for breast cancer. Ann Intern Med. 2008;148(9):671-9.
25. Berg WA, Zhang Z, Lehrer D, et al. Detection of breast cancer with addition of annual screening ultrasound or a single screening MRI to mammography in women with elevated breast cancer risk. JAMA. 2012;307(13):1394-404.
26. Rijnsburger AJ, Obdeijn IM, Kaas R, et al. BRCA1-associated breast cancers present differently from BRCA2-associated and familial cases: long-term follow-up of the Dutch MRISC Screening Study. J Clin Oncol. 2010;28(36):5265-73.
27. Passaperuma K, Warner E, Causer PA, et al. Long-term results of screening with magnetic resonance imaging in women with BRCA mutations. Br J Cancer. 2012;107(1):24-30.
28. Port ER, Park A, Borgen PI, et al. Results of MRI screening for breast cancer in high-risk patients with LCIS and atypical hyperplasia. Ann Surg Oncol. 2007;14(3):1051-7.
29. Oeffinger KC, Fontham ET, Etzioni R, et al. Breast cancer screening for women at average risk: 2015 guideline update from the American Cancer Society.[Erratum appears in JAMA. 2016 Apr 5;315(13):1406; PMID: 27046378]. JAMA Intern Med. 2015;314(15):1599-614.
30. Expert Panel on Breast Imaging: Mainiero MB, Moy L, Baron P, et al. ACR Appropriateness Criteria® breast cancer screening. J Am Coll Radiol. 2017;14(11S):S383-S90.
31. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Breast Cancer (Version 4.2023. Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
32. Johnson CD, Chen MH, Toledano AY, et al. Accuracy of CT colonography for detection of large adenomas and cancers. N Engl J Med. 2008;359(12):1207-17.
33. Kim DH, Pickhardt PJ, Taylor AJ, et al. CT colonography versus colonoscopy for the detection of advanced neoplasia. N Engl J Med. 2007;357(14):1403-12.
34. Tutein Nolthenius CJ, Boellaard TN, de Haan MC, et al. Evolution of screen-detected small (6-9 mm) polyps after a 3-year surveillance interval: assessment of growth with CT colonography compared with histopathology. Am J Gastroenterol. 2015;110(12):1682-90.
35. Bibbins-Domingo K, Grossman DC, Curry SJ, et al. Screening for colorectal cancer: US Preventive Services Task Force recommendation statement.[Erratum appears in JAMA. 2016 Aug 2;316(5):545; PMID: 27483080], [Erratum appears in JAMA. 2017 Jun 6;317(21):2239; PMID: 28586871], [Summary for patients in JAMA. 2016 Jun 21;315(23):2635; PMID: 27305107],. JAMA. 2016;315(23):2564-75.
36. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Colorectal Cancer Screening (Version 1.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
37. Bach PB, Mirkin JN, Oliver TK, et al. Benefits and harms of CT screening for lung cancer: a systematic review. JAMA. 2012;307(22):2418-29.
38. Aberle DR, Adams AM, Berg CD, et al. Reduced lung-cancer mortality with low-dose computed tomographic screening. N Engl J Med. 2011;365(5):395-409.
39. Chiles C. Lung cancer screening with low-dose computed tomography. Radiol Clin North Am. 2014;52(1):27-46.
40. US Preventive Services Task Force (USPSTF). Screening for lung cancer: US Preventive Services Task Force recommendation statement [full recommendation statement]. 2021 [final Mar 9]. Available from: https://www.uspreventiveservicestaskforce.org/uspstf/recommendation/lung-cancer-screening.
41. Kato K, Gemba K, Ashizawa K, et al. Low-dose chest computed tomography screening of subjects exposed to asbestos. Eur J Radiol. 2018;101:124-8.
42. Mazzone PJ, Silvestri GA, Patel S, et al. Screening for lung cancer: CHEST guideline and expert panel report. Chest. 2018;153(4):954-85.
43. Canto MI, Almario JA, Schulick RD, et al. Risk of neoplastic progression in individuals at high risk for pancreatic cancer undergoing long-term surveillance. Gastroenterology. 2018;155(3):740-51.e2.
44. Vasen H, Ibrahim I, Ponce CG, et al. Benefit of surveillance for pancreatic cancer in high-risk individuals: outcome of long-term prospective follow-up studies from three European expert centers. J Clin Oncol. 2016;34(17):2010-9.
45. Canto MI, Hruban RH, Fishman EK, et al. Frequent detection of pancreatic lesions in asymptomatic high-risk individuals. Gastroenterology. 2012;142(4):796-804; quiz e14-5.
46. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Genetic/Familial High-Risk Assessment: Breast, Ovarian, and Pancreatic (Version 2.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
47. Singal AG, Llovet JM, Yarchoan M, et al. AASLD practice guidance on prevention, diagnosis, and treatment of hepatocellular carcinoma. Hepatology. 2023;22:22.
48. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Hepatocellular Carcinoma (Version 2.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
49. Expert Panel on Gastrointestinal Imaging: Bashir MR, Horowitz JM, Kamel IR, et al. ACR Appropriateness Criteria® chronic liver disease. J Am Coll Radiol. 2020;17(5S):S70-S80.
50. Simmons O, Fetzer DT, Yokoo T, et al. Predictors of adequate ultrasound quality for hepatocellular carcinoma surveillance in patients with cirrhosis. Aliment Pharmacol Ther. 2017;45(1):169-77.
51. Son JH, Choi SH, Kim SY, et al. Validation of US Liver Imaging Reporting and Data System version 2017 in patients at high risk for hepatocellular carcinoma. Radiology. 2019;292(2):390-7.
52. Tzartzeva K, Obi J, Rich NE, et al. Surveillance imaging and alpha fetoprotein for early detection of hepatocellular carcinoma in patients with cirrhosis: a meta-analysis. Gastroenterology. 2018;154(6):1706-18.e1.
53. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Anal Carcinoma (Version 3.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
54. Rao S, Guren MG, Khan K, et al. Anal cancer: ESMO clinical practice guidelines for diagnosis, treatment and follow-up. Ann Oncol. 2021;32(9):1087-100.
55. Jones M, Hruby G, Solomon M, et al. The role of FDG-PET in the initial staging and response assessment of anal cancer: a systematic review and meta-analysis. Ann Surg Oncol. 2015;22(11):3574-81.
56. Mahmud A, Poon R, Jonker D. PET imaging in anal canal cancer: a systematic review and meta-analysis. Br J Radiol. 2017;90(1080):20170370.
57. Mullen JT, Rodriguez-Bigas MA, Chang GJ, et al. Results of surgical salvage after failed chemoradiation therapy for epidermoid carcinoma of the anal canal. Ann Surg Oncol. 2007;14(2):478-83.
58. Chang SS, Bochner BH, Chou R, et al. Treatment of non-metastatic muscle-invasive bladder cancer: AUA/ASCO/ASTRO/SUO guideline. J Urol. 2017;198(3):552-9.
59. Tekes A, Kamel I, Imam K, et al. Dynamic MRI of bladder cancer: evaluation of staging accuracy. AJR Am J Roentgenol. 2005;184(1):121-7.
60. Barentsz JO, Jager GJ, van Vierzen PB, et al. Staging urinary bladder cancer after transurethral biopsy: value of fast dynamic contrast-enhanced MR imaging. Radiology. 1996;201(1):185-93.
61. Powles T, Bellmunt J, Comperat E, et al. Bladder cancer: ESMO clinical practice guideline for diagnosis, treatment and follow-up. Ann Oncol. 2022;33(3):244-58.
62. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Bladder Cancer (Version 3.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
63. Goodfellow H, Viney Z, Hughes P, et al. Role of fluorodeoxyglucose positron emission tomography (FDG PET)-computed tomography (CT) in the staging of bladder cancer. BJU Int. 2014;114(3):389-95.
64. Kollberg P, Almquist H, Blackberg M, et al. [18F]Fluorodeoxyglucose – positron emission tomography/computed tomography improves staging in patients with high-risk muscle-invasive bladder cancer scheduled for radical cystectomy. Scand J Urol. 2015;49(4):296-301.
65. Kibel AS, Dehdashti F, Katz MD, et al. Prospective study of [18F]fluorodeoxyglucose positron emission tomography/computed tomography for staging of muscle-invasive bladder carcinoma. J Clin Oncol. 2009;27(26):4314-20.
66. Lu YY, Chen JH, Liang JA, et al. Clinical value of FDG PET or PET/CT in urinary bladder cancer: a systemic review and meta-analysis. Eur J Radiol. 2012;81(9):2411-6.
67. Shinagare AB, Ramaiya NH, Jagannathan JP, et al. Metastatic pattern of bladder cancer: correlation with the characteristics of the primary tumor. AJR Am J Roentgenol. 2011;196(1):117-22.
68. Anderson TS, Regine WF, Kryscio R, et al. Neurologic complications of bladder carcinoma: a review of 359 cases. Cancer. 2003;97(9):2267-72.
69. Rouprêt M, Babjuk M, Burger M, et al. EAU guidelines on upper urinary tract urothelial carcinoma. 2023 [limited update 2023 Mar]. Arnhem, The Netherlands: EAU Guidelines Office. [46 p.]. Available from: https://uroweb.org/guidelines/upper-urinary-tract-urothelial-cell-carcinoma/chapter/citation-information.
70. Expert Panel on Urological Imaging: Allen BC, Oto A, Akin O, et al. ACR Appropriateness Criteria® post-treatment surveillance of bladder cancer: 2021 update. J Am Coll Radiol. 2021;18(5S):S126-S38.
71. Hillner BE, Siegel BA, Hanna L, et al. Impact of 18F-FDG PET used after initial treatment of cancer: comparison of the National Oncologic PET Registry 2006 and 2009 cohorts. J Nucl Med. 2012;53(5):831-7.
72. Soukup V, Babjuk M, Bellmunt J, et al. Follow-up after surgical treatment of bladder cancer: a critical analysis of the literature. Eur Urol. 2012;62(2):290-302.
73. Giannarini G, Kessler TM, Thoeny HC, et al. Do patients benefit from routine follow-up to detect recurrences after radical cystectomy and ileal orthotopic bladder substitution? Eur Urol. 2010;58(4):486-94.
74. Young RM, Jamshidi A, Davis G, et al. Current trends in the surgical management and treatment of adult glioblastoma. Ann Transl Med. 2015;3(9):121.
75. Mohile NA, Deangelis LM, Abrey LE. The utility of body FDG PET in staging primary central nervous system lymphoma. Neuro-oncol. 2008;10(2):223-8.
76. Blum RH, Seymour JF, Wirth A, et al. Frequent impact of [18F]fluorodeoxyglucose positron emission tomography on the staging and management of patients with indolent non-Hodgkin’s lymphoma. Clin Lymphoma. 2003;4(1):43-9.
77. Wohrer S, Jaeger U, Kletter K, et al. 18F-fluoro-deoxy-glucose positron emission tomography (18F-FDG-PET) visualizes follicular lymphoma irrespective of grading. Ann Oncol. 2006;17(5):780-4.
78. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Central Nervous System Cancers (Version 1.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
79. Wen PY, Macdonald DR, Reardon DA, et al. Updated response assessment criteria for high-grade gliomas: response assessment in neuro-oncology working group. J Clin Oncol. 2010;28(11):1963-72.
80. Lai PH, Hsu SS, Ding SW, et al. Proton magnetic resonance spectroscopy and diffusion-weighted imaging in intracranial cystic mass lesions. Surg Neurol. 2007;68 Suppl 1:S25-36.
81. Wang X, Hu X, Xie P, et al. Comparison of magnetic resonance spectroscopy and positron emission tomography in detection of tumor recurrence in posttreatment of glioma: a diagnostic meta-analysis. Asia Pac J Clin Oncol. 2015;11(2):97-105.
82. Stupp R, Brada M, van den Bent MJ, et al. High-grade glioma: ESMO clinical practice guidelines for diagnosis, treatment and follow-up. Ann Oncol. 2014;25 Suppl 3:iii93-101.
83. Li CI, Uribe DJ, Daling JR. Clinical characteristics of different histologic types of breast cancer. Br J Cancer. 2005;93(9):1046-52.
84. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Occult Primary (Cancer of Unknown Primary [CUP]) (Version 1.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
85. Puglisi F, Follador A, Minisini AM, et al. Baseline staging tests after a new diagnosis of breast cancer: further evidence of their limited indications. Ann Oncol. 2005;16(2):263-6.
86. Myers RE, Johnston M, Pritchard K, et al. Baseline staging tests in primary breast cancer: a practice guideline. CMAJ. 2001;164(10):1439-44.
87. Kumar R, Chauhan A, Zhuang H, et al. Clinicopathologic factors associated with false negative FDG-PET in primary breast cancer. Breast Cancer Res Treat. 2006;98(3):267-74.
88. Podoloff DA, Advani RH, Allred C, et al. NCCN task force report: positron emission tomography (PET)/computed tomography (CT) scanning in cancer. J Natl Compr Canc Netw. 2007;5 Suppl 1:S1-22; quiz S3-2.
89. Rosen EL, Eubank WB, Mankoff DA. FDG PET, PET/CT, and breast cancer imaging. Radiographics. 2007;27 Suppl 1:S215-29.
90. Wahl RL, Siegel BA, Coleman RE, et al. Prospective multicenter study of axillary nodal staging by positron emission tomography in breast cancer: a report of the staging breast cancer with PET Study Group. J Clin Oncol. 2004;22(2):277-85.
91. Jeong YJ, Kang DY, Yoon HJ, et al. Additional value of F-18 FDG PET/CT for initial staging in breast cancer with clinically negative axillary nodes. Breast Cancer Res Treat. 2014;145(1):137-42.
92. Peters NH, van Esser S, van den Bosch MA, et al. Preoperative MRI and surgical management in patients with nonpalpable breast cancer: the MONET – randomised controlled trial. Eur J Cancer. 2011;47(6):879-86.
93. Turnbull LW, Brown SR, Olivier C, et al. Multicentre randomised controlled trial examining the cost-effectiveness of contrast-enhanced high field magnetic resonance imaging in women with primary breast cancer scheduled for wide local excision (COMICE). Health Technol Assess. 2010;14(1):1-182.
94. Houssami N, Turner R, Macaskill P, et al. An individual person data meta-analysis of preoperative magnetic resonance imaging and breast cancer recurrence. J Clin Oncol. 2014;32(5):392-401.
95. Expert Panel on Breast Imaging: Le-Petross HT, Slanetz PJ, Lewin AA, et al. ACR Appropriateness Criteria® imaging of the axilla. J Am Coll Radiol. 2022;19(5S):S87-S113.
96. Huyge V, Garcia C, Alexiou J, et al. Heterogeneity of metabolic response to systemic therapy in metastatic breast cancer patients. Clin Oncol. 2010;22(10):818-27.
97. Lee CI, Gold LS, Nelson HD, et al. Comparative effectiveness of imaging modalities to determine metastatic breast cancer treatment response. Breast. 2015;24(1):3-11.
98. U.S. Food & Drug Administration (FDA). CERIANNA™ (fluoroestradiol F 18) injection, for intravenous use. 2020 [revised 2020 May]. Available from: https://www.accessdata.fda.gov/drugsatfda_docs/label/2020/212155s000lbl.pdf.
99. Evangelista L, Guarneri V, Conte PF. 18F-Fluoroestradiol Positron Emission Tomography in Breast Cancer Patients: Systematic Review of the Literature & Meta-Analysis. Curr Radiopharm. 2016;9(3):244-57.
100. Ulaner GA, Mankoff DA, Clark AS, et al. Summary: appropriate use criteria for estrogen receptor-targeted PET Imaging with 16alpha-18F-fluoro-17beta-fluoroestradiol. J Nucl Med. 2023;64(3):351-4.
101. Bottoni G, Fiz F, Puntoni M, et al. Diagnostic effectiveness of [18F]Fluoroestradiol PET/CT in oestrogen receptor-positive breast cancer: the key role of histopathology. Evidence from an international multicentre prospective study. Eur J Nucl Med Mol Imaging. 2023;50(8):2477-85.
102. Runowicz CD, Leach CR, Henry NL, et al. American Cancer Society/American Society of Clinical Oncology breast cancer survivorship care guideline. CA Cancer J Clin. 2016;66(1):43-73.
103. Expert Panel on Breast Imaging: Heller SL, Lourenco AP, Niell BL, et al. ACR Appropriateness Criteria® imaging after mastectomy and breast reconstruction. J Am Coll Radiol. 2020;17(11S):S403-S14.
104. Losa F, Soler G, Casado A, et al. SEOM clinical guideline on unknown primary cancer (2017). Clin Transl Oncol. 2018;20(1):89-96.
105. Kim KW, Krajewski KM, Jagannathan JP, et al. Cancer of unknown primary sites: what radiologists need to know and what oncologists want to know. AJR Am J Roentgenol. 2013;200(3):484-92.
106. Kwee TC, Kwee RM. Combined FDG-PET/CT for the detection of unknown primary tumors: systematic review and meta-analysis. Eur Radiol. 2009;19(3):731-44.
107. Ambrosini V, Nanni C, Rubello D, et al. 18F-FDG PET/CT in the assessment of carcinoma of unknown primary origin. Radiol Med (Torino). 2006;111(8):1146-55.
108. Seve P, Billotey C, Broussolle C, et al. The role of 2-deoxy-2-[F-18]fluoro-D-glucose positron emission tomography in disseminated carcinoma of unknown primary site. Cancer. 2007;109(2):292-9.
109. Zhu L, Wang N. 18F-fluorodeoxyglucose positron emission tomography-computed tomography as a diagnostic tool in patients with cervical nodal metastases of unknown primary site: a meta-analysis. Surg Oncol. 2013;22(3):190-4.
110. Adegoke O, Kulasingam S, Virnig B. Cervical cancer trends in the United States: a 35-year population-based analysis. J Womens Health (Larchmt). 2012;21(10):1031-7.
111. Sala E, Rockall AG, Freeman SJ, et al. The added role of MR imaging in treatment stratification of patients with gynecologic malignancies: what the radiologist needs to know. Radiology. 2013;266(3):717-40.
112. Patel S, Liyanage SH, Sahdev A, et al. Imaging of endometrial and cervical cancer. Insights Imaging. 2010;1(5-6):309-28.
113. Hricak H, Gatsonis C, Coakley FV, et al. Early invasive cervical cancer: CT and MR imaging in preoperative evaluation – ACRIN/GOG comparative study of diagnostic performance and interobserver variability. Radiology. 2007;245(2):491-8.
114. Mitchell DG, Snyder B, Coakley F, et al. Early invasive cervical cancer: tumor delineation by magnetic resonance imaging, computed tomography, and clinical examination, verified by pathologic results, in the ACRIN 6651/GOG 183 Intergroup Study. J Clin Oncol. 2006;24(36):5687-94.
115. Lakhman Y, Akin O, Park KJ, et al. Stage IB1 cervical cancer: role of preoperative MR imaging in selection of patients for fertility-sparing radical trachelectomy. Radiology. 2013;269(1):149-58.
116. Wang F, Tang Q, Lv G, et al. Comparison of computed tomography and magnetic resonance imaging in cervical cancer brachytherapy: a systematic review. Brachytherapy. 2017;16(2):353-65.
117. Subak LL, Hricak H, Powell CB, et al. Cervical carcinoma: computed tomography and magnetic resonance imaging for preoperative staging. Obstet Gynecol. 1995;86(1):43-50.
118. Pannu HK, Fishman EK. Evaluation of cervical cancer by computed tomography: current status. Cancer. 2003;98(9 Suppl):2039-43.
119. Lin WC, Hung YC, Yeh LS, et al. Usefulness of (18)F-fluorodeoxyglucose positron emission tomography to detect para-aortic lymph nodal metastasis in advanced cervical cancer with negative computed tomography findings. Gynecol Oncol. 2003;89(1):73-6.
120. Havrilesky LJ, Kulasingam SL, Matchar DB, et al. FDG-PET for management of cervical and ovarian cancer. Gynecol Oncol. 2005;97(1):183-91.
121. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Cervical Cancer (Version 1.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
122. Liu FY, Lai CH, Yang LY, et al. Utility of (18)F-FDG PET/CT in patients with advanced squamous cell carcinoma of the uterine cervix receiving concurrent chemoradiotherapy: a parallel study of a prospective randomized trial. Eur J Nucl Med Mol Imaging. 2016;43(10):1812-23.
123. Sironi S, Picchio M, Landoni C, et al. Post-therapy surveillance of patients with uterine cancers: value of integrated FDG PET/CT in the detection of recurrence. Eur J Nucl Med Mol Imaging. 2007;34(4):472-9.
124. Chung HH, Jo H, Kang WJ, et al. Clinical impact of integrated PET/CT on the management of suspected cervical cancer recurrence. Gynecol Oncol. 2007;104(3):529-34.
125. Sahdev A, Jones J, Shepherd JH, et al. MR imaging appearances of the female pelvis after trachelectomy. Radiographics. 2005;25(1):41-52.
126. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Colon Cancer (Version 3.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
127. Cervantes A, Adam R, Rosello S, et al. Metastatic colorectal cancer: ESMO clinical practice guideline for diagnosis, treatment and follow-up. Ann Oncol. 2023;34(1):10-32.
128. Dighe S, Purkayastha S, Swift I, et al. Diagnostic precision of CT in local staging of colon cancers: a meta-analysis. Clin Radiol. 2010;65(9):708-19.
129. Dighe S, Blake H, Koh MD, et al. Accuracy of multidetector computed tomography in identifying poor prognostic factors in colonic cancer. Br J Surg. 2010;97(9):1407-15.
130. Dighe S, Swift I, Magill L, et al. Accuracy of radiological staging in identifying high-risk colon cancer patients suitable for neoadjuvant chemotherapy: a multicentre experience. Colorectal Dis. 2012;14(4):438-44.
131. Hundt W, Braunschweig R, Reiser M. Evaluation of spiral CT in staging of colon and rectum carcinoma. Eur Radiol. 1999;9(1):78-84.
132. McAndrew MR, Saba AK. Efficacy of routine preoperative computed tomography scans in colon cancer. Am Surg. 1999;65(3):205-8.
133. Nerad E, Lahaye MJ, Maas M, et al. Diagnostic accuracy of CT for local staging of colon cancer: a systematic review and meta-analysis. AJR Am J Roentgenol. 2016;207(5):984-95.
134. Smith NJ, Bees N, Barbachano Y, et al. Preoperative computed tomography staging of nonmetastatic colon cancer predicts outcome: implications for clinical trials. Br J Cancer. 2007;96(7):1030-6.
135. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Rectal Cancer (Version 5.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
136. Battersby NJ, How P, Moran B, et al. Prospective validation of a low rectal cancer magnetic resonance imaging staging system and development of a local recurrence risk stratification model: the MERCURY II study. Ann Surg. 2016;263(4):751-60.
137. Furukawa H, Ikuma H, Seki A, et al. Positron emission tomography scanning is not superior to whole body multidetector helical computed tomography in the preoperative staging of colorectal cancer. Gut. 2006;55(7):1007-11.
138. Moulton CA, Gu CS, Law CH, et al. Effect of PET before liver resection on surgical management for colorectal adenocarcinoma metastases: a randomized clinical trial. JAMA. 2014;311(18):1863-9.
139. Maffione AM, Lopci E, Bluemel C, et al. Diagnostic accuracy and impact on management of (18)F-FDG PET and PET/CT in colorectal liver metastasis: a meta-analysis and systematic review. Eur J Nucl Med Mol Imaging. 2015;42(1):152-63.
140. Park IJ, You YN, Agarwal A, et al. Neoadjuvant treatment response as an early response indicator for patients with rectal cancer. J Clin Oncol. 2012;30(15):1770-6.
141. Das P, Skibber JM, Rodriguez-Bigas MA, et al. Predictors of tumor response and downstaging in patients who receive preoperative chemoradiation for rectal cancer. Cancer. 2007;109(9):1750-5.
142. Patel UB, Taylor F, Blomqvist L, et al. Magnetic resonance imaging-detected tumor response for locally advanced rectal cancer predicts survival outcomes: MERCURY experience. J Clin Oncol. 2011;29(28):3753-60.
143. de Jong EA, ten Berge JC, Dwarkasing RS, et al. The accuracy of MRI, endorectal ultrasonography, and computed tomography in predicting the response of locally advanced rectal cancer after preoperative therapy: a metaanalysis. Surgery. 2016;159(3):688-99.
144. Akhurst T, Kates TJ, Mazumdar M, et al. Recent chemotherapy reduces the sensitivity of [18F]fluorodeoxyglucose positron emission tomography in the detection of colorectal metastases. J Clin Oncol. 2005;23(34):8713-6.
145. van Kessel CS, Buckens CF, van den Bosch MA, et al. Preoperative imaging of colorectal liver metastases after neoadjuvant chemotherapy: a meta-analysis. Ann Surg Oncol. 2012;19(9):2805-13.
146. Glazer ES, Beaty K, Abdalla EK, et al. Effectiveness of positron emission tomography for predicting chemotherapy response in colorectal cancer liver metastases. Arch Surg. 2010;145(4):340-5; discussion 5.
147. Litvak A, Cercek A, Segal N, et al. False-positive elevations of carcinoembryonic antigen in patients with a history of resected colorectal cancer. J Natl Compr Canc Netw. 2014;12(6):907-13.
148. Nicholson BD, Shinkins B, Mant D. Blood measurement of carcinoembryonic antigen level for detecting recurrence of colorectal cancer. JAMA. 2016;316(12):1310-1.
149. Lu YY, Chen JH, Chien CR, et al. Use of FDG-PET or PET/CT to detect recurrent colorectal cancer in patients with elevated CEA: a systematic review and meta-analysis. Int J Colorectal Dis. 2013;28(8):1039-47.
150. Hyder O, Dodson RM, Mayo SC, et al. Post-treatment surveillance of patients with colorectal cancer with surgically treated liver metastases. Surgery. 2013;154(2):256-65.
151. Meyerhardt JA, Mangu PB, Flynn PJ, et al. Follow-up care, surveillance protocol, and secondary prevention measures for survivors of colorectal cancer: American Society of Clinical Oncology clinical practice guideline endorsement. J Clin Oncol. 2013;31(35):4465-70.
152. Enzinger PC, Mayer RJ. Esophageal cancer. N Engl J Med. 2003;349(23):2241-52.
153. Young PE, Gentry AB, Acosta RD, et al. Endoscopic ultrasound does not accurately stage early adenocarcinoma or high-grade dysplasia of the esophagus. Clin Gastroenterol Hepatol. 2010;8(12):1037-41.
154. van Vliet EP, Heijenbrok-Kal MH, Hunink MG, et al. Staging investigations for oesophageal cancer: a meta-analysis. Br J Cancer. 2008;98(3):547-57.
155. Keswani RN, Early DS, Edmundowicz SA, et al. Routine positron emission tomography does not alter nodal staging in patients undergoing EUS-guided FNA for esophageal cancer. Gastrointest Endosc. 2009;69(7):1210-7.
156. Flamen P, Lerut A, Van Cutsem E, et al. Utility of positron emission tomography for the staging of patients with potentially operable esophageal carcinoma. J Clin Oncol. 2000;18(18):3202-10.
157. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Esophageal and Esophagogastric Cancers (Version 3.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
158. Meyers BF, Downey RJ, Decker PA, et al. The utility of positron emission tomography in staging of potentially operable carcinoma of the thoracic esophagus: results of the American College of Surgeons Oncology Group Z0060 trial. J Thorac Cardiovasc Surg. 2007;133(3):738-45.
159. Flanagan FL, Dehdashti F, Siegel BA, et al. Staging of esophageal cancer with 18F-fluorodeoxyglucose positron emission tomography. AJR Am J Roentgenol. 1997;168(2):417-24.
160. Lordick F, Ott K, Krause BJ, et al. PET to assess early metabolic response and to guide treatment of adenocarcinoma of the oesophagogastric junction: the MUNICON phase II trial. Lancet Oncol. 2007;8(9):797-805.
161. Cremonesi M, Garibaldi C, Timmerman R, et al. Interim 18F-FDG-PET/CT during chemo-radiotherapy in the management of oesophageal cancer patients. a systematic review. Radiother Oncol. 2017;125(2):200-12.
162. Mocellin S, Pasquali S. Diagnostic accuracy of endoscopic ultrasonography (EUS) for the preoperative locoregional staging of primary gastric cancer. Cochrane Database Syst Rev. 2015(2):CD009944.
163. Cardoso R, Coburn N, Seevaratnam R, et al. A systematic review and meta-analysis of the utility of EUS for preoperative staging for gastric cancer. Gastric Cancer. 2012;15 Suppl 1:S19-26.
164. Kwee RM, Kwee TC. Imaging in local staging of gastric cancer: a systematic review. J Clin Oncol. 2007;25(15):2107-16.
165. Expert Panel on Gastrointestinal Imaging: Vij A, Zaheer A, Kamel IR, et al. ACR Appropriateness Criteria® epigastric pain. J Am Coll Radiol. 2021;18(11S):S330-S9.
166. Blencowe NS, Whistance RN, Strong S, et al. Evaluating the role of fluorodeoxyglucose positron emission tomography-computed tomography in multi-disciplinary team recommendations for oesophago-gastric cancer. Br J Cancer. 2013;109(6):1445-50.
167. Smyth E, Schoder H, Strong VE, et al. A prospective evaluation of the utility of 2-deoxy-2-[(18) F]fluoro-D-glucose positron emission tomography and computed tomography in staging locally advanced gastric cancer. Cancer. 2012;118(22):5481-8.
168. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Gastric Cancer (Version 2.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
169. Vallbohmer D, Holscher AH, Schneider PM, et al. [18F]-fluorodeoxyglucose-positron emission tomography for the assessment of histopathologic response and prognosis after completion of neoadjuvant chemotherapy in gastric cancer. J Surg Oncol. 2010;102(2):135-40.
170. Ott K, Herrmann K, Lordick F, et al. Early metabolic response evaluation by fluorine-18 fluorodeoxyglucose positron emission tomography allows in vivo testing of chemosensitivity in gastric cancer: long-term results of a prospective study. Clin Cancer Res. 2008;14(7):2012-8.
171. Wu LM, Hu JN, Hua J, et al. 18 F-fluorodeoxyglucose positron emission tomography to evaluate recurrent gastric cancer: a systematic review and meta-analysis. J Gastroenterol Hepatol. 2012;27(3):472-80.
172. Baiocchi GL, Marrelli D, Verlato G, et al. Follow-up after gastrectomy for cancer: an appraisal of the Italian research group for gastric cancer. Ann Surg Oncol. 2014;21(6):2005-11.
173. Cardoso R, Coburn NG, Seevaratnam R, et al. A systematic review of patient surveillance after curative gastrectomy for gastric cancer: a brief review. Gastric Cancer. 2012;15 Suppl 1:S164-7.
174. Prehn RB, Pasic TR, Harari PM, et al. Influence of computed tomography on pretherapeutic tumor staging in head and neck cancer patients. Otolaryngol Head Neck Surg. 1998;119(6):628-33.
175. Kuno H, Onaya H, Iwata R, et al. Evaluation of cartilage invasion by laryngeal and hypopharyngeal squamous cell carcinoma with dual-energy CT. Radiology. 2012;265(2):488-96.
176. Don DM, Anzai Y, Lufkin RB, et al. Evaluation of cervical lymph node metastases in squamous cell carcinoma of the head and neck. Laryngoscope. 1995;105(7 Pt 1):669-74.
177. Driessen JPvK, P. M.;van der Heijden, G. J.;Philippens, M. E.;Pameijer, F. A.;Stegeman, I.;Terhaard, C. H.;Janssen, L. M.;Grolman, W. Diffusion-weighted imaging in head and neck squamous cell carcinomas: a systematic review. Head Neck. 2015;37(3):440-8.
178. Fleming AJ, Jr., Smith SP, Jr., Paul CM, et al. Impact of [18F]-2-fluorodeoxyglucose-positron emission tomography/computed tomography on previously untreated head and neck cancer patients. Laryngoscope. 2007;117(7):1173-9.
179. Xu G, Li J, Zuo X, et al. Comparison of whole body positron emission tomography (PET)/PET-computed tomography and conventional anatomic imaging for detecting distant malignancies in patients with head and neck cancer: a meta-analysis. Laryngoscope. 2012;122(9):1974-8.
180. Stoeckli SJ, Steinert H, Pfaltz M, et al. Is there a role for positron emission tomography with 18F-fluorodeoxyglucose in the initial staging of nodal negative oral and oropharyngeal squamous cell carcinoma. Head Neck. 2002;24(4):345-9.
181. Liao LJ, Hsu WL, Wang CT, et al. Analysis of sentinel node biopsy combined with other diagnostic tools in staging cN0 head and neck cancer: A diagnostic meta-analysis. Head Neck. 2016;38(4):628-34.
182. Mehanna H, Wong WL, McConkey CC, et al. PET-CT surveillance versus neck dissection in advanced head and neck cancer. N Engl J Med. 2016;374(15):1444-54.
183. Isles MG, McConkey C, Mehanna HM. A systematic review and meta-analysis of the role of positron emission tomography in the follow up of head and neck squamous cell carcinoma following radiotherapy or chemoradiotherapy. Clin Otolaryngol. 2008;33(3):210-22.
184. Abgral R, Querellou S, Potard G, et al. Does 18F-FDG PET/CT improve the detection of posttreatment recurrence of head and neck squamous cell carcinoma in patients negative for disease on clinical follow-up? J Nucl Med. 2009;50(1):24-9.
185. Nayak JV, Walvekar RR, Andrade RS, et al. Deferring planned neck dissection following chemoradiation for stage IV head and neck cancer: the utility of PET-CT. Laryngoscope. 2007;117(12):2129-34.
186. Ong SC, Schoder H, Lee NY, et al. Clinical utility of 18F-FDG PET/CT in assessing the neck after concurrent chemoradiotherapy for locoregional advanced head and neck cancer. J Nucl Med. 2008;49(4):532-40.
187. Colombo N, Creutzberg C, Amant F, et al. ESMO-ESGO-ESTRO consensus conference on endometrial cancer: diagnosis, treatment and follow-up. Ann Oncol. 2016;27(1):16-41.
188. Marrero JA, Kulik LM, Sirlin CB, et al. Diagnosis, staging, and management of hepatocellular carcinoma: 2018 practice guidance by the American Association for the Study of Liver Diseases. Hepatology. 2018;68(2):723-50.
189. Lee YJ, Lee JM, Lee JS, et al. Hepatocellular carcinoma: diagnostic performance of multidetector CT and MR imaging-a systematic review and meta-analysis. Radiology. 2015;275(1):97-109.
190. Cho Y, Lee DH, Lee YB, et al. Does 18F-FDG positron emission tomography-computed tomography have a role in initial staging of hepatocellular carcinoma? PLoS ONE. 2014;9(8):e105679.
191. Lin CY, Chen JH, Liang JA, et al. 18F-FDG PET or PET/CT for detecting extrahepatic metastases or recurrent hepatocellular carcinoma: a systematic review and meta-analysis. Eur J Radiol. 2012;81(9):2417-22.
192. Sun DW, An L, Wei F, et al. Prognostic significance of parameters from pretreatment (18)F-FDG PET in hepatocellular carcinoma: a meta-analysis. Abdom Radiol. 2016;41(1):33-41.
193. Hyodo T, Kumano S, Kushihata F, et al. CT and MR cholangiography: advantages and pitfalls in perioperative evaluation of biliary tree. Br J Radiol. 2012;85(1015):887-96.
194. Szklaruk J, Tamm E, Charnsangavej C. Preoperative imaging of biliary tract cancers. Surg Oncol Clin N Am. 2002;11(4):865-76.
195. Vogl TJ, Schwarz WO, Heller M, et al. Staging of Klatskin tumours (hilar cholangiocarcinomas): comparison of MR cholangiography, MR imaging, and endoscopic retrograde cholangiography. Eur Radiol. 2006;16(10):2317-25.
196. Yeh TS, Jan YY, Tseng JH, et al. Malignant perihilar biliary obstruction: magnetic resonance cholangiopancreatographic findings. Am J Gastroenterol. 2000;95(2):432-40.
197. Zidi SH, Prat F, Le Guen O, et al. Performance characteristics of magnetic resonance cholangiography in the staging of malignant hilar strictures. Gut. 2000;46(1):103-6.
198. Zhang H, Zhu J, Ke F, et al. Radiological imaging for assessing the respectability of hilar cholangiocarcinoma: a systematic review and meta-analysis. Biomed Res Int. 2015;2015:497942.
199. Corvera CU, Blumgart LH, Akhurst T, et al. 18F-fluorodeoxyglucose positron emission tomography influences management decisions in patients with biliary cancer. J Am Coll Surg. 2008;206(1):57-65.
200. Petrowsky H, Wildbrett P, Husarik DB, et al. Impact of integrated positron emission tomography and computed tomography on staging and management of gallbladder cancer and cholangiocarcinoma. J Hepatol. 2006;45(1):43-50.
201. Ruys AT, Bennink RJ, van Westreenen HL, et al. FDG-positron emission tomography/computed tomography and standardized uptake value in the primary diagnosis and staging of hilar cholangiocarcinoma. HPB. 2011;13(4):256-62.
202. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Biliary Tract Cancers (Version 3.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
203. Vogel A, Bridgewater J, Edeline J, et al. Biliary tract cancer: ESMO clinical practice guideline for diagnosis, treatment and follow-up. Ann Oncol. 2023;34(2):127-40.
204. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Histiocytic Neoplasms (Version 1.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
205. Walter C, Kruessell M, Gindele A, et al. Imaging of renal lesions: evaluation of fast MRI and helical CT. Br J Radiol. 2003;76(910):696-703.
206. Hallscheidt PJ, Bock M, Riedasch G, et al. Diagnostic accuracy of staging renal cell carcinomas using multidetector-row computed tomography and magnetic resonance imaging: a prospective study with histopathologic correlation. J Comput Assist Tomogr. 2004;28(3):333-9.
207. Hallscheidt PJ, Fink C, Haferkamp A, et al. Preoperative staging of renal cell carcinoma with inferior vena cava thrombus using multidetector CT and MRI: prospective study with histopathological correlation. J Comput Assist Tomogr. 2005;29(1):64-8.
208. Kang DE, White RL, Jr., Zuger JH, et al. Clinical use of fluorodeoxyglucose F 18 positron emission tomography for detection of renal cell carcinoma. J Urol. 2004;171(5):1806-9.
209. Majhail NS, Urbain JL, Albani JM, et al. F-18 fluorodeoxyglucose positron emission tomography in the evaluation of distant metastases from renal cell carcinoma. J Clin Oncol. 2003;21(21):3995-4000.
210. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Kidney Cancer (Version 1.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
211. Expert Panel on Urological Imaging: Ganeshan D, Khatri G, Ali N, et al. ACR Appropriateness Criteria® staging of renal cell carcinoma: 2022 update. J Am Coll Radiol. 2023;20(5S):S246-S64.
212. Fielding JR, Aliabadi N, Renshaw AA, et al. Staging of 119 patients with renal cell carcinoma: the yield and cost-effectiveness of pelvic CT. AJR Am J Roentgenol. 1999;172(1):23-5.
213. Khaitan A, Gupta NP, Hemal AK, et al. Is there a need for pelvic CT scan in cases of renal cell carcinoma? Int Urol Nephrol. 2002;33(1):13-5.
214. Lim DJ, Carter MF. Computerized tomography in the preoperative staging for pulmonary metastases in patients with renal cell carcinoma. J Urol. 1993;150(4):1112-4.
215. Larcher A, Dell’Oglio P, Fossati N, et al. When to perform preoperative chest computed tomography for renal cancer staging. BJU Int. 2017;120(4):490-6.
216. Donat SM, Diaz M, Bishoff JT, et al. Follow-up for clinically localized renal neoplasms: AUA Guideline. J Urol. 2013;190(2):407-16.
217. McLoud TC, Bourgouin PM, Greenberg RW, et al. Bronchogenic carcinoma: analysis of staging in the mediastinum with CT by correlative lymph node mapping and sampling. Radiology. 1992;182(2):319-23.
218. Seely JM, Mayo JR, Miller RR, et al. T1 lung cancer: prevalence of mediastinal nodal metastases and diagnostic accuracy of CT. Radiology. 1993;186(1):129-32.
219. Chin R, Jr., Ward R, Keyes JW, et al. Mediastinal staging of non-small-cell lung cancer with positron emission tomography. Am J Respir Crit Care Med. 1995;152(6 Pt 1):2090-6.
220. Kernstine KH, Stanford W, Mullan BF, et al. PET, CT, and MRI with Combidex for mediastinal staging in non-small cell lung carcinoma. Ann Thorac Surg. 1999;68(3):1022-8.
221. Fischer B, Lassen U, Mortensen J, et al. Preoperative staging of lung cancer with combined PET-CT.[Erratum appears in N Engl J Med. 2011 Mar 10;364(10):982]. N Engl J Med. 2009;361(1):32-9.
222. Bradley J, Bae K, Choi N, et al. A phase II comparative study of gross tumor volume definition with or without PET/CT fusion in dosimetric planning for non-small-cell lung cancer (NSCLC): primary analysis of Radiation Therapy Oncology Group (RTOG) 0515. Int J Radiat Oncol Biol Phys. 2012;82(1):435-41.e1.
223. Yuan S, Sun X, Li M, et al. A randomized study of involved-field irradiation versus elective nodal irradiation in combination with concurrent chemotherapy for inoperable stage III nonsmall cell lung cancer. Am J Clin Oncol. 2007;30(3):239-44.
224. Cerfolio RJ, Bryant AS, Ojha B. Restaging patients with N2 (stage IIIa) non-small cell lung cancer after neoadjuvant chemoradiotherapy: a prospective study.[Erratum appears in J Thorac Cardiovasc Surg. 2006 Sep;132(3):565-7]. J Thorac Cardiovasc Surg. 2006;131(6):1229-35.
225. Ohri N, Bodner WR, Halmos B, et al. 18F-fluorodeoxyglucose/positron emission tomography predicts patterns of failure after definitive chemoradiation therapy for locally advanced non-small cell lung cancer. Int J Radiat Oncol Biol Phys. 2017;97(2):372-80.
226. Roy S, Pathy S, Kumar R, et al. Efficacy of 18F-fluorodeoxyglucose positron emission tomography/computed tomography as a predictor of response in locally advanced non-small-cell carcinoma of the lung. Nucl Med Commun. 2016;37(2):129-38.
227. Pan Y, Brink C, Schytte T, et al. Planned FDG PET-CT scan in follow-up detects disease progression in patients with locally advanced NSCLC receiving curative chemoradiotherapy earlier than standard CT. Medicine (Baltimore). 2015;94(43):e1863.
228. Ulaner GA, Lyall A. Identifying and distinguishing treatment effects and complications from malignancy at FDG PET/CT. Radiographics. 2013;33(6):1817-34.
229. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Non-Small Cell Lung Cancer (Version 5.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
230. Kalemkerian GP. Staging and imaging of small cell lung cancer. Cancer Imaging. 2012;11:253-8.
231. Jett JR, Schild SE, Kesler KA, et al. Treatment of small cell lung cancer: diagnosis and management of lung cancer, 3rd ed: American College of Chest Physicians evidence-based clinical practice guidelines. Chest. 2013;143(5 Suppl):e400S-e19S.
232. Bradley JD, Dehdashti F, Mintun MA, et al. Positron emission tomography in limited-stage small-cell lung cancer: a prospective study. J Clin Oncol. 2004;22(16):3248-54.
233. Xanthopoulos EP, Corradetti MN, Mitra N, et al. Impact of PET staging in limited-stage small-cell lung cancer.[Erratum appears in J Thorac Oncol. 2013 Aug;8(8):1106]. J Thorac Oncol. 2013;8(7):899-905.
234. Shirvani SM, Komaki R, Heymach JV, et al. Positron emission tomography/computed tomography-guided intensity-modulated radiotherapy for limited-stage small-cell lung cancer. Int J Radiat Oncol Biol Phys. 2012;82(1):e91-7.
235. van Loon J, De Ruysscher D, Wanders R, et al. Selective nodal irradiation on basis of (18)FDG-PET scans in limited-disease small-cell lung cancer: a prospective study. Int J Radiat Oncol Biol Phys. 2010;77(2):329-36.
236. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Small Cell Lung Cancer (Version 1.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
237. Naumann R, Beuthien-Baumann B, Reiss A, et al. Substantial impact of FDG PET imaging on the therapy decision in patients with early-stage Hodgkin’s lymphoma. Br J Cancer. 2004;90(3):620-5.
238. Barrington SF, Kirkwood AA, Franceschetto A, et al. PET-CT for staging and early response: results from the Response-Adapted Therapy in Advanced Hodgkin Lymphoma study. Blood. 2016;127(12):1531-8.
239. Andre MPE, Girinsky T, Federico M, et al. Early positron emission tomography response-adapted treatment in stage I and II Hodgkin lymphoma: final results of the randomized EORTC/LYSA/FIL H10 trial. J Clin Oncol. 2017;35(16):1786-94.
240. Radford J, Illidge T, Counsell N, et al. Results of a trial of PET-directed therapy for early-stage Hodgkin’s lymphoma. N Engl J Med. 2015;372(17):1598-607.
241. Gallamini A, Hutchings M, Rigacci L, et al. Early interim 2-[18F]fluoro-2-deoxy-D-glucose positron emission tomography is prognostically superior to international prognostic score in advanced-stage Hodgkin’s lymphoma: a report from a joint Italian-Danish study. J Clin Oncol. 2007;25(24):3746-52.
242. Cerci JJ, Pracchia LF, Linardi CC, et al. 18F-FDG PET after 2 cycles of ABVD predicts event-free survival in early and advanced Hodgkin lymphoma.[Erratum appears in J Nucl Med. 2010 Oct;51(10):1658]. J Nucl Med. 2010;51(9):1337-43.
243. Bartlett NL. Fine-tuning the treatment of Hodgkin’s lymphoma. N Engl J Med. 2016;1(25):2490-2.
244. Johnson P, Federico M, Kirkwood A, et al. Adapted treatment guided by interim PET-CT scan in advanced Hodgkin’s lymphoma. N Engl J Med. 2016;374(25):2419-29.
245. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Hodgkin Lymphoma (Version 1.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
246. Picardi M, Pugliese N, Cirillo M, et al. Advanced-stage Hodgkin lymphoma: US/chest radiography for detection of relapse in patients in first complete remission–a randomized trial of routine surveillance imaging procedures. Radiology. 2014;272(1):262-74.
247. El-Galaly TC, Mylam KJ, Brown P, et al. Positron emission tomography/computed tomography surveillance in patients with Hodgkin lymphoma in first remission has a low positive predictive value and high costs. Haematologica. 2012;97(6):931-6.
248. Mocikova H, Obrtlikova P, Vackova B, et al. Positron emission tomography at the end of first-line therapy and during follow-up in patients with Hodgkin lymphoma: a retrospective study. Ann Oncol. 2010;21(6):1222-7.
249. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Acute Lymphoblastic Leukemia (Version 3.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
250. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Acute Myeloid Leukemia (Version 6.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
251. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Chronic Lymphocytic Leukemia/Small Lymphocytic Lymphoma (Version 1.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
252. Weiler-Sagie M, Bushelev O, Epelbaum R, et al. (18)F-FDG avidity in lymphoma readdressed: a study of 766 patients. J Nucl Med. 2010;51(1):25-30.
253. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for B-Cell Lymphomas (Version 6.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
254. Gomez Leon N, Delgado-Bolton RC, Del Campo Del Val L, et al. Multicenter comparison of contrast-enhanced FDG PET/CT and 64-slice multi-detector-row CT for initial staging and response evaluation at the end of treatment in patients with lymphoma. Clin Nucl Med. 2017;42(8):595-602.
255. Schaefer NG, Hany TF, Taverna C, et al. Non-Hodgkin lymphoma and Hodgkin disease: coregistered FDG PET and CT at staging and restaging–do we need contrast-enhanced CT? Radiology. 2004;232(3):823-9.
256. Isasi CR, Lu P, Blaufox MD. A metaanalysis of 18F-2-deoxy-2-fluoro-D-glucose positron emission tomography in the staging and restaging of patients with lymphoma. Cancer. 2005;104(5):1066-74.
257. Juweid ME. FDG-PET/CT in lymphoma. Methods Mol Biol. 2011;727:1-19.
258. Eichhorst BF, Fischer K, Fink AM, et al. Limited clinical relevance of imaging techniques in the follow-up of patients with advanced chronic lymphocytic leukemia: results of a meta-analysis. Blood. 2011;117(6):1817-21.
259. Le Dortz L, De Guibert S, Bayat S, et al. Diagnostic and prognostic impact of 18F-FDG PET/CT in follicular lymphoma. Eur J Nucl Med Mol Imaging. 2010;37(12):2307-14.
260. Haioun C, Itti E, Rahmouni A, et al. [18F]fluoro-2-deoxy-D-glucose positron emission tomography (FDG-PET) in aggressive lymphoma: an early prognostic tool for predicting patient outcome. Blood. 2005;106(4):1376-81.
261. Mamot C, Klingbiel D, Hitz F, et al. Final results of a prospective evaluation of the predictive value of interim positron emission tomography in patients with diffuse large B-cell lymphoma treated with R-CHOP-14 (SAKK 38/07).[Erratum appears in J Clin Oncol. 2015 Sep 20;33(27):3074; PMID: 26381873]. J Clin Oncol. 2015;33(23):2523-9.
262. Yancovitz M, Finelt N, Warycha MA, et al. Role of radiologic imaging at the time of initial diagnosis of stage T1b-T3b melanoma. Cancer. 2007;110(5):1107-14.
263. Gold JS, Jaques DP, Busam KJ, et al. Yield and predictors of radiologic studies for identifying distant metastases in melanoma patients with a positive sentinel lymph node biopsy. Ann Surg Oncol. 2007;14(7):2133-40.
264. Johnson TM, Fader DJ, Chang AE, et al. Computed tomography in staging of patients with melanoma metastatic to the regional nodes. Ann Surg Oncol. 1997;4(5):396-402.
265. Kuvshinoff BW, Kurtz C, Coit DG. Computed tomography in evaluation of patients with stage III melanoma. Ann Surg Oncol. 1997;4(3):252-8.
266. Xing Y, Bronstein Y, Ross MI, et al. Contemporary diagnostic imaging modalities for the staging and surveillance of melanoma patients: a meta-analysis. J Natl Cancer Inst. 2011;103(2):129-42.
267. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Melanoma: Uveal (Version 1.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
268. Podlipnik S, Carrera C, Sanchez M, et al. Performance of diagnostic tests in an intensive follow-up protocol for patients with American Joint Committee on Cancer (AJCC) stage IIB, IIC, and III localized primary melanoma: a prospective cohort study. J Am Acad Dermatol. 2016;75(3):516-24.
269. Meyers MO, Yeh JJ, Frank J, et al. Method of detection of initial recurrence of stage II/III cutaneous melanoma: analysis of the utility of follow-up staging. Ann Surg Oncol. 2009;16(4):941-7.
270. Moore Dalal K, Zhou Q, Panageas KS, et al. Methods of detection of first recurrence in patients with stage I/II primary cutaneous melanoma after sentinel lymph node biopsy. Ann Surg Oncol. 2008;15(8):2206-14.
271. Romano E, Scordo M, Dusza SW, et al. Site and timing of first relapse in stage III melanoma patients: implications for follow-up guidelines. J Clin Oncol. 2010;28(18):3042-7.
272. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Melanoma: Cutaneous (Version 3.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
273. Mathews JD, Forsythe AV, Brady Z, et al. Cancer risk in 680,000 people exposed to computed tomography scans in childhood or adolescence: data linkage study of 11 million Australians. BMJ. 2013;346:f2360.
274. Harms KL, Healy MA, Nghiem P, et al. Analysis of prognostic factors from 9387 merkel cell carcinoma cases forms the basis for the new 8th Edition AJCC Staging System. Ann Surg Oncol. 2016;23(11):3564-71.
275. Hawryluk EB, O’Regan KN, Sheehy N, et al. Positron emission tomography/computed tomography imaging in Merkel cell carcinoma: a study of 270 scans in 97 patients at the Dana-Farber/Brigham and Women’s Cancer Center. J Am Acad Dermatol. 2013;68(4):592-9.
276. Treglia G, Kakhki VR, Giovanella L, et al. Diagnostic performance of fluorine-18-fluorodeoxyglucose positron emission tomography in patients with Merkel cell carcinoma: a systematic review and meta-analysis. Am J Clin Dermatol. 2013;14(6):437-47.
277. Alexander E, 3rd, Rossitch E, Jr., Small K, et al. Merkel cell carcinoma: long term survival in a patient with proven brain metastasis and presumed choroid metastasis. Clin Neurol Neurosurg. 1989;91(4):317-20.
278. Expert Panel on GYN and OB Imaging: Reinhold C, Ueno Y, Akin EA, et al. ACR Appropriateness Criteria® pretreatment evaluation and follow-up of endometrial cancer. J Am Coll Radiol. 2020;17(11S):S472-S86.
279. Walker R, Barlogie B, Haessler J, et al. Magnetic resonance imaging in multiple myeloma: diagnostic and clinical implications. J Clin Oncol. 2007;25(9):1121-8.
280. Moulopoulos LA, Dimopoulos MA, Weber D, et al. Magnetic resonance imaging in the staging of solitary plasmacytoma of bone. J Clin Oncol. 1993;11(7):1311-5.
281. Hillengass J, Fechtner K, Weber MA, et al. Prognostic significance of focal lesions in whole-body magnetic resonance imaging in patients with asymptomatic multiple myeloma. J Clin Oncol. 2010;28(9):1606-10.
282. Schirrmeister H, Bommer M, Buck AK, et al. Initial results in the assessment of multiple myeloma using 18F-FDG PET. Eur J Nucl Med Mol Imaging. 2002;29(3):361-6.
283. Kato T, Tsukamoto E, Nishioka T, et al. Early detection of bone marrow involvement in extramedullary plasmacytoma by whole-body F-18 FDG positron emission tomography. Clin Nucl Med. 2000;25(11):870-3.
284. Dimopoulos MA, Moreau P, Terpos E, et al. Multiple myeloma: EHA-ESMO clinical practice guidelines for diagnosis, treatment and follow-up. Ann Oncol. 2021;32(3):309-22.
285. Hillengass J, Ayyaz S, Kilk K, et al. Changes in magnetic resonance imaging before and after autologous stem cell transplantation correlate with response and survival in multiple myeloma. Haematologica. 2012;97(11):1757-60.
286. Bannas P, Hentschel HB, Bley TA, et al. Diagnostic performance of whole-body MRI for the detection of persistent or relapsing disease in multiple myeloma after stem cell transplantation. Eur Radiol. 2012;22(9):2007-12.
287. Zamagni E, Nanni C, Mancuso K, et al. PET/CT improves the definition of complete response and allows to detect otherwise unidentifiable skeletal progression in multiple myeloma. Clin Cancer Res. 2015;21(19):4384-90.
288. Spinnato P, Bazzocchi A, Brioli A, et al. Contrast enhanced MRI and 18F-FDG PET-CT in the assessment of multiple myeloma: a comparison of results in different phases of the disease. Eur J Radiol. 2012;81(12):4013-8.
289. Moreau P, Attal M, Caillot D, et al. Prospective evaluation of magnetic Resonance imaging and 18fluorodeoxyglucose positron emission tomography-computed tomography at diagnosis and before maintenance therapy in symptomatic patients with multiple myeloma included in the IFM/DFCI 2009 trial: results of the IMAJEM study. J Clin Oncol. 2017;35(25):2911-8.
290. Sung YM, Lee KS, Kim BT, et al. 18F-FDG PET/CT of thymic epithelial tumors: usefulness for distinguishing and staging tumor subgroups. J Nucl Med. 2006;47(10):1628-34.
291. Paulson EK, McDermott VG, Keogan MT, et al. Carcinoid metastases to the liver: role of triple-phase helical CT. Radiology. 1998;206(1):143-50.
292. Fishbein L, Del Rivero J, Else T, et al. The North American Neuroendocrine Tumor Society consensus guidelines for surveillance and management of metastatic and/or unresectable pheochromocytoma and paraganglioma. Pancreas. 2021;50(4):469-93.
293. Singh S, Bergsland EK, Card CM, et al. Commonwealth Neuroendocrine Tumour Research Collaboration and the North American Neuroendocrine Tumor Society guidelines for the diagnosis and management of patients with lung neuroendocrine tumors: an international collaborative endorsement and update of the 2015 European Neuroendocrine Tumor Society expert consensus guidelines. J Thorac Oncol. 2020;15(10):1577-98.
294. Hope TA, Bergsland EK, Bozkurt MF, et al. Appropriate use criteria for somatostatin receptor PET imaging in neuroendocrine tumors. 2020. Society of Nuclear Medicine & Molecular Imaging (SNMMI). [9 p.]. Available from: http://www.snmmi.org/ClinicalPractice/content.aspx?ItemNumber=23260.
295. Albanus DR, Apitzsch J, Erdem Z, et al. Clinical value of 68Ga-DOTATATE-PET/CT compared to stand-alone contrast enhanced CT for the detection of extra-hepatic metastases in patients with neuroendocrine tumours (NET). Eur J Radiol. 2015;84(10):1866-72.
296. Sadowski SM, Millo C, Cottle-Delisle C, et al. Results of (68)gallium-DOTATATE PET/CT scanning in patients with multiple endocrine neoplasia type 1. J Am Coll Surg. 2015;221(2):509-17.
297. Deppen SA, Blume J, Bobbey AJ, et al. 68Ga-DOTATATE compared with 111In-DTPA-octreotide and conventional imaging for pulmonary and gastroenteropancreatic neuroendocrine tumors: a systematic review and meta-analysis. J Nucl Med. 2016;57(6):872-8.
298. Menda Y, O’Dorisio TM, Howe JR, et al. Localization of unknown primary site with 68Ga-DOTATOC PET/CT in patients with metastatic neuroendocrine tumor. J Nucl Med. 2017;58(7):1054-7.
299. Sadowski SM, Neychev V, Millo C, et al. Prospective study of 68Ga-DOTATATE positron emission tomography/computed tomography for detecting gastro-entero-pancreatic neuroendocrine tumors and unknown primary sites. J Clin Oncol. 2016;34(6):588-96.
300. Delpassand ES, Ranganathan D, Wagh N, et al. 64Cu-DOTATATE PET/CT for imaging patients with known or suspected somatostatin receptor-positive neuroendocrine tumors: results of the first U.S. prospective, reader-masked clinical trial. J Nucl Med. 2020;61(6):890-6.
301. Johnbeck CB, Knigge U, Loft A, et al. Head-to-head comparison of 64Cu-DOTATATE and 68Ga-DOTATOC PET/CT: a prospective study of 59 patients with neuroendocrine tumors. J Nucl Med. 2017;58(3):451-7.
302. Abgral R, Leboulleux S, Deandreis D, et al. Performance of (18)fluorodeoxyglucose-positron emission tomography and somatostatin receptor scintigraphy for high Ki67 (>=10%) well-differentiated endocrine carcinoma staging. J Clin Endocrinol Metab. 2011;96(3):665-71.
303. Adams S, Baum R, Rink T, et al. Limited value of fluorine-18 fluorodeoxyglucose positron emission tomography for the imaging of neuroendocrine tumours. Eur J Nucl Med. 1998;25(1):79-83.
304. Pasquali C, Rubello D, Sperti C, et al. Neuroendocrine tumor imaging: can 18F-fluorodeoxyglucose positron emission tomography detect tumors with poor prognosis and aggressive behavior? World J Surg. 1998;22(6):588-92.
305. U.S. Food & Drug Administration (FDA). NETSPOT (kit for the preparation of gallium Ga 68 dotatate injection), for intravenous use. 2016 [revised 2023 Oct]. Available from: https://www.accessdata.fda.gov/drugsatfda_docs/label/2023/208547s027lbl.pdf.
306. Forstner R, Hricak H, Occhipinti KA, et al. Ovarian cancer: staging with CT and MR imaging. Radiology. 1995;197(3):619-26.
307. Tempany CM, Zou KH, Silverman SG, et al. Staging of advanced ovarian cancer: comparison of imaging modalities–report from the Radiological Diagnostic Oncology Group. Radiology. 2000;215(3):761-7.
308. Low RN, Semelka RC, Worawattanakul S, et al. Extrahepatic abdominal imaging in patients with malignancy: comparison of MR imaging and helical CT, with subsequent surgical correlation. Radiology. 1999;210(3):625-32.
309. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Ovarian Cancer Including Fallopian Tube Cancer and Primary Peritoneal Cancer (Version 2.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
310. Expert Panel on Women’s Imaging: Kang SK, Reinhold C, Atri M, et al. ACR Appropriateness Criteria® staging and follow-up of ovarian cancer. J Am Coll Radiol. 2018;15(5S):S198-S207.
311. Armstrong A, Otvos B, Singh S, et al. Evaluation of the cost of CA-125 measurement, physical exam, and imaging in the diagnosis of recurrent ovarian cancer. Gynecol Oncol. 2013;131(3):503-7.
312. Salani R, Khanna N, Frimer M, et al. An update on post-treatment surveillance and diagnosis of recurrence in women with gynecologic malignancies: Society of Gynecologic Oncology (SGO) recommendations. Gynecol Oncol. 2017;146(1):3-10.
313. Gadducci A, Fuso L, Cosio S, et al. Are surveillance procedures of clinical benefit for patients treated for ovarian cancer?: a retrospective Italian multicentric study. Int J Gynecol Cancer. 2009;19(3):367-74.
314. Lindemann K, Kristensen G, Mirza MR, et al. Poor concordance between CA-125 and RECIST at the time of disease progression in patients with platinum-resistant ovarian cancer: analysis of the AURELIA trial. Ann Oncol. 2016;27(8):1505-10.
315. Rustin GJ, van der Burg ME, Griffin CL, et al. Early versus delayed treatment of relapsed ovarian cancer (MRC OV05/EORTC 55955): a randomised trial. Lancet. 2010;376(9747):1155-63.
316. Al-Hawary MM, Francis IR, Chari ST, et al. Pancreatic ductal adenocarcinoma radiology reporting template: consensus statement of the society of abdominal radiology and the american pancreatic association. Gastroenterology. 2014;146(1):291-304.e1.
317. Walters DM, Lapar DJ, de Lange EE, et al. Pancreas-protocol imaging at a high-volume center leads to improved preoperative staging of pancreatic ductal adenocarcinoma. Ann Surg Oncol. 2011;18(10):2764-71.
318. Treadwell JR, Zafar HM, Mitchell MD, et al. Imaging tests for the diagnosis and staging of pancreatic adenocarcinoma: a meta-analysis. Pancreas. 2016;45(6):789-95.
319. Farma JM, Santillan AA, Melis M, et al. PET/CT fusion scan enhances CT staging in patients with pancreatic neoplasms. Ann Surg Oncol. 2008;15(9):2465-71.
320. Zhu D, Wang L, Zhang H, et al. Prognostic value of 18F-FDG-PET/CT parameters in patients with pancreatic carcinoma: a systematic review and meta-analysis. Medicine (Baltimore). 2017;96(33):e7813.
321. Expert Panel on Gastrointestinal Imaging: Qayyum A, Tamm EP, Kamel IR, et al. ACR Appropriateness Criteria® staging of pancreatic ductal adenocarcinoma. J Am Coll Radiol. 2017;14(11S):S560-S9.
322. Ramanathan RK, Goldstein D, Korn RL, et al. Positron emission tomography response evaluation from a randomized phase III trial of weekly nab-paclitaxel plus gemcitabine versus gemcitabine alone for patients with metastatic adenocarcinoma of the pancreas. Ann Oncol. 2016;27(4):648-53.
323. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Pancreatic Adenocarcinoma (Version 2.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
324. Kannoth S. Paraneoplastic neurologic syndrome: a practical approach. Ann Indian Acad Neurol. 2012;15(1):6-12.
325. Titulaer MJ, Soffietti R, Dalmau J, et al. Screening for tumours in paraneoplastic syndromes: report of an EFNS task force. Eur J Neurol. 2011;18(1):19-e3.
326. Patel RR, Subramaniam RM, Mandrekar JN, et al. Occult malignancy in patients with suspected paraneoplastic neurologic syndromes: value of positron emission tomography in diagnosis. Mayo Clin Proc. 2008;83(8):917-22.
327. McKeon A, Apiwattanakul M, Lachance DH, et al. Positron emission tomography-computed tomography in paraneoplastic neurologic disorders: systematic analysis and review. Arch Neurol. 2010;67(3):322-9.
328. Sheikhbahaei S, Marcus CV, Fragomeni RS, et al. Whole-body 18F-FDG PET and 18F-FDG PET/CT in patients with suspected paraneoplastic syndrome: a systematic review and meta-analysis of diagnostic accuracy. J Nucl Med. 2017;58(7):1031-6.
329. Sheikhbahaei S, Trahan TJ, Xiao J, et al. FDG-PET/CT and MRI for evaluation of pathologic response to neoadjuvant chemotherapy in patients with breast cancer: a meta-analysis of diagnostic accuracy studies. Oncologist. 2016;21(8):931-9.
330. Kataoka MY, Sala E, Baldwin P, et al. The accuracy of magnetic resonance imaging in staging of vulvar cancer: a retrospective multi-centre study. Gynecol Oncol. 2010;117(1):82-7.
331. Chang YC, Hricak H, Thurnher S, et al. Vagina: evaluation with MR imaging. Part II. Neoplasms. Radiology. 1988;169(1):175-9.
332. Taylor MB, Dugar N, Davidson SE, et al. Magnetic resonance imaging of primary vaginal carcinoma. Clin Radiol. 2007;62(6):549-55.
333. Cohn DE, Dehdashti F, Gibb RK, et al. Prospective evaluation of positron emission tomography for the detection of groin node metastases from vulvar cancer. Gynecol Oncol. 2002;85(1):179-84.
334. Robertson NL, Hricak H, Sonoda Y, et al. The impact of FDG-PET/CT in the management of patients with vulvar and vaginal cancer. Gynecol Oncol. 2016;140(3):420-4.
335. Lamoreaux WT, Grigsby PW, Dehdashti F, et al. FDG-PET evaluation of vaginal carcinoma. Int J Radiat Oncol Biol Phys. 2005;62(3):733-7.
336. Expert Panel on GYN and OB Imaging: Kilcoyne A, Gottumukkala RV, Kang SK, et al. ACR Appropriateness Criteria® staging and follow-up of primary vaginal cancer. J Am Coll Radiol. 2021;18(11S):S442-S55.
337. Expert Panel on GYN and OB Imaging: Lakhman Y, Vargas HA, Reinhold C, et al. ACR Appropriateness Criteria® staging and follow-up of vulvar cancer. J Am Coll Radiol. 2021;18(5S):S212-S28.
338. Ornellas AA, Kinchin EW, Nobrega BL, et al. Surgical treatment of invasive squamous cell carcinoma of the penis: Brazilian National Cancer Institute long-term experience. J Surg Oncol. 2008;97(6):487-95.
339. Tabatabaei S, Harisinghani M, McDougal WS. Regional lymph node staging using lymphotropic nanoparticle enhanced magnetic resonance imaging with ferumoxtran-10 in patients with penile cancer. J Urol. 2005;174(3):923-7; discussion 7.
340. Mueller-Lisse UG, Scher B, Scherr MK, et al. Functional imaging in penile cancer: PET/computed tomography, MRI, and sentinel lymph node biopsy. Curr Opin Urol. 2008;18(1):105-10.
341. Scher B, Seitz M, Reiser M, et al. 18F-FDG PET/CT for staging of penile cancer. J Nucl Med. 2005;46(9):1460-5.
342. Sadeghi R, Gholami H, Zakavi SR, et al. Accuracy of 18F-FDG PET/CT for diagnosing inguinal lymph node involvement in penile squamous cell carcinoma: systematic review and meta-analysis of the literature. Clin Nucl Med. 2012;37(5):436-41.
343. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Vulvar Cancer (Squamous Cell Carcinoma) (Version 2.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
344. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Penile Cancer (Version 1.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
345. Mottet N, Cornford P, van den Bergh R, et al. EAU-EANM-ESTRO-ESUR-ISUP-SIOG guidelines on prostate cancer. 2023 [limited update 2023 Mar]. Arnhem, The Netherlands: EAU Guidelines Office. [234 p.]. Available from: https://uroweb.org/guidelines/prostate-cancer.
346. Kasivisvanathan V, Rannikko AS, Borghi M, et al. MRI-targeted or standard biopsy for prostate-cancer diagnosis. N Engl J Med. 2018;378(19):1767-77.
347. de Rooij M, Hamoen EH, Witjes JA, et al. Accuracy of magnetic resonance imaging for local staging of prostate cancer: a diagnostic meta-analysis. Eur Urol. 2016;70(2):233-45.
348. Hovels AM, Heesakkers RA, Adang EM, et al. The diagnostic accuracy of CT and MRI in the staging of pelvic lymph nodes in patients with prostate cancer: a meta-analysis. Clin Radiol. 2008;63(4):387-95.
349. Heck MM, Souvatzoglou M, Retz M, et al. Prospective comparison of computed tomography, diffusion-weighted magnetic resonance imaging and [11C]choline positron emission tomography/computed tomography for preoperative lymph node staging in prostate cancer patients. Eur J Nucl Med Mol Imaging. 2014;41(4):694-701.
350. Hofman MS, Lawrentschuk N, Francis RJ, et al. Prostate-specific membrane antigen PET-CT in patients with high-risk prostate cancer before curative-intent surgery or radiotherapy (proPSMA): a prospective, randomised, multicentre study. Lancet. 2020;395(10231):1208-16.
351. Stabile A, Pellegrino A, Mazzone E, et al. Can negative prostate-specific membrane antigen positron emission tomography/computed tomography avoid the need for pelvic lymph node dissection in newly diagnosed prostate cancer patients? a systematic review and meta-analysis with backup histology as reference standard. Eur Urol Oncol. 2022;5(1):[17 p.].
352. Eastham JA, Auffenberg GB, Barocas DA, et al. Clinically localized prostate cancer: AUA/ASTRO Guideline 2022 endorsed by SUO [unabridged]. 2022. American Urological Association Education and Research, Inc. [46 p.]. Available from: https://www.auanet.org/guidelines-and-quality/guidelines/clinically-localized-prostate-cancer-aua/astro-guideline-2022.
353. Trabulsi EJ, Rumble RB, Jadvar H, et al. Optimum imaging strategies for advanced prostate cancer: ASCO guideline. J Clin Oncol. 2020;38(17):1963-96.
354. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Prostate Cancer (Version 4.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
355. Jadvar H. PET of glucose metabolism and cellular proliferation in prostate cancer. J Nucl Med. 2016;57(Suppl 3):25S-9S.
356. Crocerossa F, Marchioni M, Novara G, et al. Detection rate of prostate specific membrane antigen tracers for positron emission tomography/computerized tomography in prostate cancer biochemical recurrence: a systematic review and network meta-analysis. J Urol. 2021;205(2):356-69.
357. Ren J, Yuan L, Wen G, et al. The value of anti-1-amino-3-18F-fluorocyclobutane-1-carboxylic acid PET/CT in the diagnosis of recurrent prostate carcinoma: a meta-analysis. Acta Radiol. 2016;57(4):487-93.
358. Yu CY, Desai B, Ji L, et al. Comparative performance of PET tracers in biochemical recurrence of prostate cancer: a critical analysis of literature. Am J Nucl Med Mol Imaging. 2014;4(6):580-601.
359. Scarsbrook AF, Bottomley D, Teoh EJ, et al. Effect of 18F-fluciclovine positron emission tomography on the management of patients with recurrence of prostate cancer: results from the FALCON trial. Int J Radiat Oncol Biol Phys. 2020;107(2):316-24.
360. Alberts IL, Seide SE, Mingels C, et al. Comparing the diagnostic performance of radiotracers in recurrent prostate cancer: a systematic review and network meta-analysis. Eur J Nucl Med Mol Imaging. 2021;48(9):2978-89.
361. Sartor O, de Bono J, Chi KN, et al. Lutetium-177-PSMA-617 for metastatic castration-resistant prostate cancer. N Engl J Med. 2021;1(12):1091-103.
362. Felker ER, Wu J, Natarajan S, et al. Serial magnetic resonance imaging in active surveillance of prostate cancer: incremental value. J Urol. 2016;195(5):1421-7.
363. Lai WS, Gordetsky JB, Thomas JV, et al. Factors predicting prostate cancer upgrading on magnetic resonance imaging-targeted biopsy in an active surveillance population. Cancer. 2017;123(11):1941-8.
364. Rais-Bahrami S, Turkbey B, Rastinehad AR, et al. Natural history of small index lesions suspicious for prostate cancer on multiparametric MRI: recommendations for interval imaging follow-up. Diagn Interv Radiol. 2014;20(4):293-8.
365. Aisen AM, Martel W, Braunstein EM, et al. MRI and CT evaluation of primary bone and soft-tissue tumors. AJR Am J Roentgenol. 1986;146(4):749-56.
366. Demas BE, Heelan RT, Lane J, et al. Soft-tissue sarcomas of the extremities: comparison of MR and CT in determining the extent of disease. AJR Am J Roentgenol. 1988;150(3):615-20.
367. Manaster BJ. Soft-tissue masses: optimal imaging protocol and reporting. AJR Am J Roentgenol. 2013;201(3):505-14.
368. Sundaram M, McGuire MH, Herbold DR. Magnetic resonance imaging of soft tissue masses: an evaluation of fifty-three histologically proven tumors. Magn Reson Imaging. 1988;6(3):237-48.
369. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Gastrointestinal Stromal Tumors (GISTs) (Version 1.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
370. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Soft Tissue Sarcoma (Version 2.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
371. Panicek DM, Gatsonis C, Rosenthal DI, et al. CT and MR imaging in the local staging of primary malignant musculoskeletal neoplasms: report of the Radiology Diagnostic Oncology Group. Radiology. 1997;202(1):237-46.
372. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Bone Cancer (Version 1.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
373. Treglia G, Salsano M, Stefanelli A, et al. Diagnostic accuracy of 18F-FDG-PET and PET/CT in patients with Ewing sarcoma family tumours: a systematic review and a meta-analysis. Skeletal Radiol. 2012;41(3):249-56.
374. Liu F, Zhang Q, Zhu D, et al. Performance of positron emission tomography and positron emission tomography/computed tomography using fluorine-18-fluorodeoxyglucose for the diagnosis, staging, and recurrence assessment of bone sarcoma: a systematic review and meta-analysis.[Erratum appears in Medicine (Baltimore). 2016 Jan;95(2):e187a Note: Liu, Fengxia [Added]]. Medicine (Baltimore). 2015;94(36):e1462.
375. Li YJ, Dai YL, Cheng YS, et al. Positron emission tomography (18)F-fluorodeoxyglucose uptake and prognosis in patients with bone and soft tissue sarcoma: a meta-analysis. Eur J Surg Oncol. 2016;42(8):1103-14.
376. Chen L, Wu X, Ma X, et al. Prognostic value of 18F-FDG PET-CT-based functional parameters in patients with soft tissue sarcoma: a meta-analysis. Medicine (Baltimore). 2017;96(6):e5913.
377. Patel SR, Zagars GK, Pisters PW. The follow-up of adult soft-tissue sarcomas. Semin Oncol. 2003;30(3):413-6.
378. Leibovitch L, Foster RS, Kopecky KK, et al. Improved accuracy of computerized tomography based clinical staging in low stage nonseminomatous germ cell cancer using size criteria of retroperitoneal lymph nodes. J Urol. 1995;154(5):1759-63.
379. Ellis JH, Bies JR, Kopecky KK, et al. Comparison of NMR and CT imaging in the evaluation of metastatic retroperitoneal lymphadenopathy from testicular carcinoma. J Comput Assist Tomogr. 1984;8(4):709-19.
380. Hogeboom WR, Hoekstra HJ, Mooyaart EL, et al. The role of magnetic resonance imaging and computed tomography in the treatment evaluation of retroperitoneal lymph-node metastases of non-seminomatous testicular tumors. Eur J Radiol. 1991;13(1):31-6.
381. de Wit M, Brenner W, Hartmann M, et al. [18F]-FDG-PET in clinical stage I/II non-seminomatous germ cell tumours: results of the German multicentre trial. Ann Oncol. 2008;19(9):1619-23.
382. Huddart RA, O’Doherty MJ, Padhani A, et al. 18fluorodeoxyglucose positron emission tomography in the prediction of relapse in patients with high-risk, clinical stage I nonseminomatous germ cell tumors: preliminary report of MRC Trial TE22–the NCRI Testis Tumour Clinical Study Group. J Clin Oncol. 2007;25(21):3090-5.
383. De Santis M, Becherer A, Bokemeyer C, et al. 2-18fluoro-deoxy-D-glucose positron emission tomography is a reliable predictor for viable tumor in postchemotherapy seminoma: an update of the prospective multicentric SEMPET trial. J Clin Oncol. 2004;22(6):1034-9.
384. Treglia G, Sadeghi R, Annunziata S, et al. Diagnostic performance of fluorine-18-fluorodeoxyglucose positron emission tomography in the postchemotherapy management of patients with seminoma: systematic review and meta-analysis. Biomed Res Int. 2014;2014(Article ID 852681):[11 p.].
385. Oechsle K, Hartmann M, Brenner W, et al. [18F]fluorodeoxyglucose positron emission tomography in nonseminomatous germ cell tumors after chemotherapy: the German multicenter positron emission tomography study group. J Clin Oncol. 2008;26(36):5930-5.
386. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Testicular Cancer (Version 1.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
387. Kollmannsberger C, Tandstad T, Bedard PL, et al. Patterns of relapse in patients with clinical stage I testicular cancer managed with active surveillance. J Clin Oncol. 2015;33(1):51-7.
388. Oldenburg J, Berney DM, Bokemeyer C, et al. Testicular seminoma and non-seminoma: ESMO-EURACAN clinical practice guideline for diagnosis, treatment and follow-up. Ann Oncol. 2022;33(4):362-75.
389. Heelan RT, Rusch VW, Begg CB, et al. Staging of malignant pleural mesothelioma: comparison of CT and MR imaging. AJR Am J Roentgenol. 1999;172(4):1039-47.
390. Expert Panel on Thoracic Imaging: Ackman JB, Chung JH, Walker CM, et al. ACR Appropriateness Criteria® imaging of mediastinal masses. J Am Coll Radiol. 2021;18(5S):S37-S51.
391. Flores RM, Akhurst T, Gonen M, et al. Positron emission tomography defines metastatic disease but not locoregional disease in patients with malignant pleural mesothelioma. J Thorac Cardiovasc Surg. 2003;126(1):11-6.
392. Sharif S, Zahid I, Routledge T, et al. Does positron emission tomography offer prognostic information in malignant pleural mesothelioma? Interact Cardiovasc Thorac Surg. 2011;12(5):806-11.
393. Sorensen JB, Ravn J, Loft A, et al. Preoperative staging of mesothelioma by 18F-fluoro-2-deoxy-D-glucose positron emission tomography/computed tomography fused imaging and mediastinoscopy compared to pathological findings after extrapleural pneumonectomy. Eur J Cardiothorac Surg. 2008;34(5):1090-6.
394. Wilcox BE, Subramaniam RM, Peller PJ, et al. Utility of integrated computed tomography-positron emission tomography for selection of operable malignant pleural mesothelioma. Clin Lung Cancer. 2009;10(4):244-8.
395. Zahid I, Sharif S, Routledge T, et al. What is the best way to diagnose and stage malignant pleural mesothelioma? Interact Cardiovasc Thorac Surg. 2011;12(2):254-9.
396. Abdel Razek AA, Khairy M, Nada N. Diffusion-weighted MR imaging in thymic epithelial tumors: correlation with World Health Organization classification and clinical staging. Radiology. 2014;273(1):268-75.
397. Yabuuchi H, Matsuo Y, Abe K, et al. Anterior mediastinal solid tumours in adults: characterisation using dynamic contrast-enhanced MRI, diffusion-weighted MRI, and FDG-PET/CT. Clin Radiol. 2015;70(11):1289-98.
398. Treglia G, Sadeghi R, Giovanella L, et al. Is (18)F-FDG PET useful in predicting the WHO grade of malignancy in thymic epithelial tumors? a meta-analysis. Lung Cancer. 2014;86(1):5-13.
399. Kindler HL, Ismaila N, Armato SG, 3rd, et al. Treatment of malignant pleural mesothelioma: American Society of Clinical Oncology clinical practice guideline. J Clin Oncol. 2018;36(13):1343-73.
400. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Mesothelioma: Pleural (Version 1.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2022.
401. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Thymomas and Thymic Carcinomas (Version 1.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2022.
402. Kouvaraki MA, Shapiro SE, Fornage BD, et al. Role of preoperative ultrasonography in the surgical management of patients with thyroid cancer. Surgery. 2003;134(6):946-54; discussion 54-5.
403. Stulak JM, Grant CS, Farley DR, et al. Value of preoperative ultrasonography in the surgical management of initial and reoperative papillary thyroid cancer. Arch Surg. 2006;141(5):489-94; discussion 94-6.
404. Choi JS, Kim J, Kwak JY, et al. Preoperative staging of papillary thyroid carcinoma: comparison of ultrasound imaging and CT. AJR Am J Roentgenol. 2009;193(3):871-8.
405. Ahn JE, Lee JH, Yi JS, et al. Diagnostic accuracy of CT and ultrasonography for evaluating metastatic cervical lymph nodes in patients with thyroid cancer. World J Surg. 2008;32(7):1552-8.
406. Chen Q, Raghavan P, Mukherjee S, et al. Accuracy of MRI for the diagnosis of metastatic cervical lymphadenopathy in patients with thyroid cancer. Radiol Med (Torino). 2015;120(10):959-66.
407. Haugen BR, Alexander EK, Bible KC, et al. 2015 American Thyroid Association management guidelines for adult patients with thyroid nodules and differentiated thyroid cancer: the American Thyroid Association guidelines task force on thyroid nodules and differentiated thyroid cancer. Thyroid. 2016;26(1):1-133.
408. Bible KC, Kebebew E, Brierley J, et al. 2021 American Thyroid Association guidelines for management of patients with anaplastic thyroid cancer. Thyroid. 2021;31(3):337-86.
409. Poisson T, Deandreis D, Leboulleux S, et al. 18F-fluorodeoxyglucose positron emission tomography and computed tomography in anaplastic thyroid cancer. Eur J Nucl Med Mol Imaging. 2010;37(12):2277-85.
410. Bogsrud TV, Karantanis D, Nathan MA, et al. 18F-FDG PET in the management of patients with anaplastic thyroid carcinoma. Thyroid. 2008;18(7):713-9.
411. Caetano R, Bastos CR, de Oliveira IA, et al. Accuracy of positron emission tomography and positron emission tomography-CT in the detection of differentiated thyroid cancer recurrence with negative (131) I whole-body scan results: a meta-analysis. Head Neck. 2016;38(2):316-27.
412. Giraudet AL, Vanel D, Leboulleux S, et al. Imaging medullary thyroid carcinoma with persistent elevated calcitonin levels. J Clin Endocrinol Metab. 2007;92(11):4185-90.
413. Khan N, Oriuchi N, Higuchi T, et al. Review of fluorine-18-2-fluoro-2-deoxy-D-glucose positron emission tomography (FDG-PET) in the follow-up of medullary and anaplastic thyroid carcinomas. Cancer Control. 2005;12(4):254-60.
414. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Thyroid Carcinoma (Version 4.2023). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
415. Yeh MW, Bauer AJ, Bernet VA, et al. American Thyroid Association statement on preoperative imaging for thyroid cancer surgery. Thyroid. 2015;25(1):3-14.
416. Kinkel K, Kaji Y, Yu KK, et al. Radiologic staging in patients with endometrial cancer: a meta-analysis. Radiology. 1999;212(3):711-8.
417. Alcazar JL, Gaston B, Navarro B, et al. Transvaginal ultrasound versus magnetic resonance imaging for preoperative assessment of myometrial infiltration in patients with endometrial cancer: a systematic review and meta-analysis. J Gynecol Oncol. 2017;28(6):e86.
418. Connor JP, Andrews JI, Anderson B, et al. Computed tomography in endometrial carcinoma. Obstet Gynecol. 2000;95(5):692-6.
419. Rockall AG, Meroni R, Sohaib SA, et al. Evaluation of endometrial carcinoma on magnetic resonance imaging. Int J Gynecol Cancer. 2007;17(1):188-96.
420. Bese T, Sal V, Demirkiran F, et al. The combination of preoperative fluorodeoxyglucose positron emission tomography/computed tomography and sentinel lymph node mapping in the surgical management of endometrioid endometrial cancer. Int J Gynecol Cancer. 2016;26(7):1228-38.
421. Bollineni VR, Ytre-Hauge S, Bollineni-Balabay O, et al. High diagnostic value of 18F-FDG PET/CT in endometrial cancer: systematic review and meta-analysis of the literature. J Nucl Med. 2016;57(6):879-85.
422. Kitajima K, Murakami K, Yamasaki E, et al. Accuracy of 18F-FDG PET/CT in detecting pelvic and paraaortic lymph node metastasis in patients with endometrial cancer. AJR Am J Roentgenol. 2008;190(6):1652-8.
423. Kitajima K, Suzuki K, Senda M, et al. Preoperative nodal staging of uterine cancer: is contrast-enhanced PET/CT more accurate than non-enhanced PET/CT or enhanced CT alone? Ann Nucl Med. 2011;25(7):511-9.
424. Park JY, Kim EN, Kim DY, et al. Comparison of the validity of magnetic resonance imaging and positron emission tomography/computed tomography in the preoperative evaluation of patients with uterine corpus cancer. Gynecol Oncol. 2008;108(3):486-92.
425. Signorelli M, Crivellaro C, Buda A, et al. Staging of high-risk endometrial cancer with PET/CT and sentinel lymph node mapping. Clin Nucl Med. 2015;40(10):780-5.
426. Chan JK, Cheung MK, Huh WK, et al. Therapeutic role of lymph node resection in endometrioid corpus cancer: a study of 12,333 patients. Cancer. 2006;107(8):1823-30.
427. Kang S, Nam JH, Bae DS, et al. Preoperative assessment of lymph node metastasis in endometrial cancer: A Korean Gynecologic Oncology Group study. Cancer. 2017;123(2):263-72.
428. NCCN Clinical Practice Guidelines in Oncology (NCCN Guidelines®) for Uterine Neoplasms (Version 1.2024). Available at http://www.nccn.org. ©National Comprehensive Cancer Network, 2023.
429. Park JY, Kim EN, Kim DY, et al. Clinical impact of positron emission tomography or positron emission tomography/computed tomography in the posttherapy surveillance of endometrial carcinoma: evaluation of 88 patients. Int J Gynecol Cancer. 2008;18(6):1332-8.
430. Fung-Kee-Fung M, Dodge J, Elit L, et al. Follow-up after primary therapy for endometrial cancer: a systematic review. Gynecol Oncol. 2006;101(3):520-9.
431. Hunn J, Tenney ME, Tergas AI, et al. Patterns and utility of routine surveillance in high grade endometrial cancer. Gynecol Oncol. 2015;137(3):485-9.
432. Schwartz ZP, Frey MK, Philips S, et al. Endometrial cancer surveillance adherence reduces utilization and subsequent costs. Gynecol Oncol. 2017;146(3):514-8.
433. Hanahan D, Weinberg RA. The hallmarks of cancer. Cell. 2000;100(1):57-70.
434. Niekel MC, Bipat S, Stoker J. Diagnostic imaging of colorectal liver metastases with CT, MR imaging, FDG PET, and/or FDG PET/CT: a meta-analysis of prospective studies including patients who have not previously undergone treatment. Radiology. 2010;257(3):674-84.
435. Davis PC, Hudgins PA, Peterman SB, et al. Diagnosis of cerebral metastases: double-dose delayed CT vs contrast-enhanced MR imaging. AJNR Am J Neuroradiol. 1991;12(2):293-300.
436. Schaefer PW, Budzik RF, Jr., Gonzalez RG. Imaging of cerebral metastases. Neurosurg Clin N Am. 1996;7(3):393-423.
437. Sze G, Milano E, Johnson C, et al. Detection of brain metastases: comparison of contrast-enhanced MR with unenhanced MR and enhanced CT. AJNR Am J Neuroradiol. 1990;11(4):785-91.
438. Frank JA, Ling A, Patronas NJ, et al. Detection of malignant bone tumors: MR imaging vs scintigraphy. AJR Am J Roentgenol. 1990;155(5):1043-8.
439. Godersky JC, Smoker WR, Knutzon R. Use of magnetic resonance imaging in the evaluation of metastatic spinal disease. Neurosurgery. 1987;21(5):676-80.
440. Steinborn MM, Heuck AF, Tiling R, et al. Whole-body bone marrow MRI in patients with metastatic disease to the skeletal system. J Comput Assist Tomogr. 1999;23(1):123-9.
441. Baur-Melnyk A, Buhmann S, Becker C, et al. Whole-body MRI versus whole-body MDCT for staging of multiple myeloma. AJR Am J Roentgenol. 2008;190(4):1097-104.
442. Luo Z, Litao L, Gu S, et al. Standard-b-value vs low-b-value DWI for differentiation of benign and malignant vertebral fractures: a meta-analysis. Br J Radiol. 2016;89(1058):20150384.
443. Suh CH, Yun SJ, Jin W, et al. ADC as a useful diagnostic tool for differentiating benign and malignant vertebral bone marrow lesions and compression fractures: a systematic review and meta-analysis. Eur Radiol. 2018;28(7):2890-902.
444. Liu T, Wang S, Liu H, et al. Detection of vertebral metastases: a meta-analysis comparing MRI, CT, PET, BS and BS with SPECT. J Cancer Res Clin Oncol. 2017;143(3):457-65.
445. Yang HL, Liu T, Wang XM, et al. Diagnosis of bone metastases: a meta-analysis comparing 18FDG PET, CT, MRI and bone scintigraphy. Eur Radiol. 2011;21(12):2604-17.
Codes
The following code list is not meant to be all-inclusive. Authorization requirements will vary by health plan. Please consult the applicable health plan for guidance on specific procedure codes.
Specific CPT codes for services should be used when available. Nonspecific or not otherwise classified codes may be subject to additional documentation requirements and review.
CPT/HCPCS
CPT® (Current Procedural Terminology) is a registered trademark of the American Medical Association (AMA). CPT® five digit codes, nomenclature and other data are copyright by the American Medical Association. All Rights Reserved. AMA does not directly or indirectly practice medicine or dispense medical services. AMA assumes no liability for the data contained herein or not contained herein.
70450 | CT head/brain, without contrast |
70460 | CT head/brain, with contrast |
70470 | CT head/brain, without contrast, followed by re-imaging with contrast |
70480 | CT of orbit, sella, or posterior fossa and outer, middle or inner ear, without contrast |
70481 | CT of orbit, sella, or posterior fossa and outer, middle or inner ear, with contrast |
70482 | CT of orbit, sella, or posterior fossa and outer, middle or inner ear, without contrast, followed by re-imaging with contrast |
70486 | CT of maxillofacial area, without contrast |
70487 | CT of maxillofacial area, with contrast |
70488 | CT of maxillofacial area, without contrast, followed by re-imaging with contrast |
70490 | CT, soft tissue neck, without contrast |
70491 | CT, soft tissue neck, with contrast |
70492 | CT, soft tissue neck, without contrast, followed by re-imaging with contrast |
70540 | MRI orbit, face and neck, without contrast |
70542 | MRI orbit, face and neck, with contrast |
70543 | MRI orbit, face and neck, without contrast, followed by re-imaging with contrast |
70551 | MRI brain (including brain stem), without contrast |
70552 | MRI brain (including brain stem), with contrast |
70553 | MRI brain (including brain stem), without contrast, followed by re-imaging with contrast |
70554 | MRI brain functional, not requiring physician or psychologist administration |
70555 | MRI brain functional, requiring physician or psychologist administration of entire neurofunctional testing |
71250 | Computed tomography, thorax, diagnostic; without contrast material |
71260 | Computed tomography, thorax, diagnostic; with contrast material(s) |
71270 | Computed tomography, thorax, diagnostic; without contrast material, followed by contrast material(s) and further sections |
71271 | Computed tomography, thorax, low dose for lung cancer screening, without contrast material(s) |
71550 | MRI chest, without contrast |
71551 | MRI chest, with contrast |
71552 | MRI chest, without contrast, followed by re-imaging with contrast |
72125 | CT cervical spine, without contrast |
72126 | CT cervical spine, with contrast |
72127 | CT cervical spine, without contrast, followed by reimaging with contrast |
72128 | CT thoracic spine, without contrast |
72129 | CT thoracic spine, with contrast |
72130 | CT thoracic spine, without contrast, followed by reimaging with contrast |
72131 | CT lumbar spine, without contrast |
72132 | CT lumbar spine, with contrast |
72133 | CT lumbar spine, without contrast, followed by reimaging with contrast |
72141 | MRI cervical spine, without contrast |
72142 | MRI cervical spine, with contrast |
72146 | MRI thoracic spine, without contrast |
72147 | MRI thoracic spine, with contrast |
72148 | MRI lumbar spine, without contrast |
72149 | MRI lumbar spine, with contrast |
72156 | MRI cervical spine, without contrast, followed by reimaging with contrast |
72157 | MRI thoracic spine, without contrast, followed by reimaging with contrast |
72158 | MRI lumbar spine, without contrast, followed by reimaging with contrast |
72192 | CT pelvis without contrast |
72193 | CT pelvis with contrast |
72194 | CT pelvis without contrast, followed by re-imaging with contrast |
72195 | MRI pelvis without contrast |
72196 | MRI pelvis with contrast |
72197 | MRI pelvis without contrast, followed by re-imaging with contrast |
73200 | CT upper extremity, without contrast |
73201 | CT upper extremity, with contrast |
73202 | CT upper extremity, without contrast, followed by re-imaging with contrast |
73218 | MRI upper extremity non-joint, without contrast |
73219 | MRI upper extremity non-joint, with contrast |
73220 | MRI upper extremity non-joint, without contrast, followed by re-imaging with contrast |
73221 | MRI upper extremity any joint, without contrast |
73222 | MRI upper extremity any joint, with contrast |
73223 | MRI upper extremity any joint, without contrast, followed by re-imaging with contrast |
73700 | CT lower extremity, without contrast |
73701 | CT lower extremity, with contrast |
73702 | CT lower extremity, without contrast, followed by re-imaging with contrast |
73718 | MRI lower extremity non-joint, without contrast |
73719 | MRI lower extremity non-joint, with contrast |
73720 | MRI lower extremity non-joint, without contrast, followed by re-imaging with contrast |
73721 | MRI lower extremity any joint, without contrast |
73722 | MRI lower extremity any joint, with contrast |
73723 | MRI lower extremity any joint, without contrast, followed by re-imaging with contrast |
74150 | CT abdomen without contrast |
74160 | CT abdomen with contrast |
74170 | CT abdomen without contrast, followed by re-imaging with contrast |
74176 | CT abdomen and pelvis without contrast |
74177 | CT abdomen and pelvis with contrast |
74178 | CT abdomen and pelvis without contrast in one or both body regions, followed by re-imaging with contrast |
74181 | MRI abdomen without contrast |
74182 | MRI abdomen with contrast |
74183 | MRI abdomen without contrast, followed by re-imaging with contrast |
74261 | CT colonography diagnostic, including image post-processing, without contrast |
74262 | CT colonography diagnostic, including image post-processing, with contrast including non-contrast images, if performed |
74263 | CT colonography screening, including image post-processing |
76390 | MRI spectroscopy |
77046 | MRI breast without contrast material(s); unilateral |
77047 | MRI breast without contrast material(s); bilateral |
77048 | MRI breast without and with contrast with CAD; unilateral |
77049 | MRI breast without and with contrast with CAD; bilateral |
77084 | MRI, bone marrow blood supply |
78608 | Brain imaging PET, metabolic evaluation |
78609 | Brain imaging PET, perfusion evaluation |
78811 | PET imaging, limited area |
78812 | PET imaging, skull to mid-thigh |
78813 | PET imaging, whole body |
78814 | PET imaging, with concurrently acquired CT for attenuation correction and anatomic localization; limited area |
78815 | PET imaging, with concurrently acquired CT for attenuation correction and anatomic localization; skull base to mid-thigh |
78816 | PET imaging, with concurrently acquired CT for attenuation correction and anatomic localization; whole body |
A9515 | Choline c-11, diagnostic, per study dose up to 20 millicuries |
A9552 | Fluorodeoxyglucose f-18 fdg, diagnostic, per study dose, up to 45 millicuries |
A9580 | Sodium Fluoride F-18, Diagnostic, Per Study Dose, Up To 30 Millicuries |
A9587 | Gallium ga-68, dotatate, diagnostic, 0.1 millicurie |
A9588 | Fluciclovine f-18, diagnostic, 1 millicurie |
A9591 | Fluoroestradiol f 18, diagnostic, 1 millicurie |
A9592 | Copper cu-64, dotatate, diagnostic, 1 millicurie |
A9593 | Gallium ga-68 psma-11, diagnostic, (ucsf), 1 millicurie |
A9594 | Gallium ga-68 psma-11, diagnostic, (ucla), 1 millicurie |
A9595 | Piflufolastat f-18, diagnostic, 1 millicurie |
A9596 | Gallium ga-68 gozetotide, diagnostic, (illuccix), 1 millicurie |
A9597 | Positron emission tomography radiopharmaceutical, diagnostic, for tumor identification, not otherwise classified |
A9598 | Positron emission tomography radiopharmaceutical, diagnostic, for non-tumor identification, not otherwise classified |
A9800 | Gallium ga-68 gozetotide, diagnostic, (locametz), 1 millicurie |
C8903 | MRI with contrast, breast; unilateral |
C8905 | MRI without contrast followed by with contrast, breast; unilateral |
C8906 | MRI with contrast, breast; bilateral |
C8908 | MRI without contrast followed by with contrast, breast; bilateral |
G0219 | PET imaging whole body; melanoma for non-covered indications |
G0235 | PET imaging, any site, not otherwise specified |
G0252 | PET imaging, full and partial-ring PET scanners only, for initial diagnosis of breast cancer and/or surgical planning for breast cancer (e.g., initial staging of axillary lymph nodes) |
S8037 | Magnetic resonance cholangiopancreatography (mrcp) |
S8085 | Fluorine-18 fluorodeoxyglucose (f-18 fdg) imaging using dual-head coincidence detection system (non-dedicated PET scan) |
0633T | CT Breast w/3d rendering uni without contrast |
0634T | CT Breast w/3d rendering uni with contrast |
0635T | CT Brst w/3d rendering uni wo cntrst flwd cntrst |
0636T | CT Breast w/3d rendering bi without contrast |
0637T | CT Breast w/3d rendering bi with contrast |
0638T | CT Brst w/3d rendering bi wo cntrst flwd cntrst |
ICD-10 Diagnosis
Refer to the ICD-10 CM manual
History
Status | Review Date | Effective Date | Action |
---|---|---|---|
Revised | 07/18/2023 | 04/14/2024* *Not for LA Medicaid | Independent Multispecialty Physician Panel (IMPP) review. Revised indications: Breast cancer screening, Lung cancer screening, Pancreatic cancer screening, Breast Cancer, Cervical Cancer, Hepatocellular and Biliary Tract Cancers, Lung Cancer- Non-Small Cell, Lung Cancer- Small Cell, Lymphoma- Non-Hodgkin and Leukemia, Melanoma, Prostate Cancer, and Sarcomas of Bone/Soft Tissue. |
Updated | 01/23/2024 | Unchanged | Expanded guideline rationale. Added required language per new Medicare regulations. |
Revised | 05/09/2022 | 04/09/2023 for commercial, Medicare, and Medicaid except LA; 06/18/2023 for LA Medicaid | IMPP review. Revised indications: Cancer screening, Cervical cancer, Head and neck cancer, Histiocytic neoplasms, Lymphoma- Non-Hodgkin and leukemia, Multiple myeloma, Prostate cancer, Cancers of the pleura, thymus, heart, and mediastinum, and Thyroid cancer. |
Updated | – | 12/18/2022 | Added code A9800. |
Revised | 05/09/2022 | 11/07/2022 for commercial, Medicare, and non-Anthem Medicaid; 04/09/2023 for Anthem Medicaid except LA Medicaid | IMPP review. Revised indications: Prostate cancer. |
Updated | – | 09/01/2022 | Added code A9596. |
Revised | 05/26/2021 | 03/13/2022 | IMPP review. Revised indications: Cancer screening, Bladder cancer, Breast cancer, Colorectal cancer, Esophageal cancer, Hepatobiliary cancer, Lung cancer- Non-small cell, Lymphoma-Hodgkin, Lymphoma- Non-Hodgkin and Leukemia, Melanoma, Neuroendocrine tumors, Prostate cancer, Sarcoma of bone and soft tissue, Testicular cancer, Thyroid cancer, and Suspected or known metastases. Added indication: Histiocytic neoplasms. Added codes A9515, A9552, A9580, A9587, A9588, A9591, A9592, A9593, A9594, A9595, A9597, A9598, 0633T, 0634T, 0635T, 0636T, 0637T, and 0638T. |
Revised | 05/26/2021 | 11/07/2021 | IMPP review. Revised indications: Cancer screening and Prostate cancer. |
Revised | 03/17/2021 | 05/01/2021 | IMPP review. Revised criteria for Cancer Screening. |
Revised | 05/11/2020, 07/08/2020 | 03/14/2021 | Independent Multispecialty Physician Panel (IMPP) review. Revised criteria for Cancer Screening, Anal, Bladder/renal pelvis/ureter, Breast, Cervical, Colorectal, Esophageal/gastroesophageal junction, Gastric, Germ Cell (now Testicular), Hepatobiliary, Kidney, Lung, Lymphoma- Hodgkin, Lymphoma- Non Hodgkin, Melanoma, Multiple myeloma, Neuroendocrine, Ovarian, Pancreatic, Penile/vaginal/vulvar, Prostate, Sarcoma of Bone and Soft Tissue, Thyroid, Uterine, and Suspected metastases, not otherwise specified. Added codes C8903, C8905, C8906, C8908, G0219, G0235, G0252, S8037, and S8085. |
Revised | – | 01/01/2021 | Annual CPT code update: added 71271; revised descriptions for 71250, 71260, 71270. Removed code G0297. |
Revised | 10/28/2019 | 08/17/2020 | IMPP review. Revised criteria for Cancer screening and Breast Cancer. |
Revised | 01/28/2019, 03/25/2019 | 11/10/2019 | IMPP review. Revised criteria for Anal, Bladder/renal pelvis/ureter, Brain/spinal cord, Breast, Cervical, Colorectal, Esophageal/gastroesophageal junction, Germ cell tumors, Head and neck, Kidney, Lung, Lymphoma- Hodgkin, Lymphoma- Non Hodgkin, Mucosal melanoma, Multiple myeloma, Pancreatic, Penile/vaginal/vulvar, Prostate, and Uterine. New sections added for Hepatobiliary and Suspected metastases, not otherwise specified. |
Revised | 09/12/2018 | 07/14/2019 | IMPP review. Guidelines for 11C-Choline and 18F-Fluciclovine added for Prostate Cancer. Guideline for 68Ga-Dotatate added for Neuroendocrine Cancer. |
Restructured | 09/12/2018 | 01/01/2019 | IMPP review. Advanced Imaging guidelines redesigned and reorganized to a condition-based structure. |
Revised | 07/11/2018 | 03/09/2019 | IMPP review. Renamed the Administrative Guidelines to “General Clinical Guideline.” Retitled Pretest Requirements to “Clinical Appropriateness Framework” to summarize the components of a decision to pursue diagnostic testing. Revised to expand applicability beyond diagnostic imaging, retitled Ordering of Multiple Studies to “Ordering of Multiple Diagnostic or Therapeutic Interventions” and replaced imaging-specific terms with “diagnostic or therapeutic intervention.” Repeated Imaging split into two subsections, “repeat diagnostic testing” and “repeat therapeutic intervention.” |
Revised | 09/07/2017 | 03/12/2018 | IMPP review. Revised criteria for Anal, Bladder, Bone/cartilage, Central nervous system, Cervical, Colorectal, Germ cell tumors, Lung cancer, Neuroendocrine tumor, Other cancers, Pancreatic, Skin, Thorax, Thyroid, Uterine, and Vaginal/vulvar/penile cancers. |
Created | – | 03/30/2005 | Original effective date |