Positron Emission Mammography (PEM) - CAM 60152

Description:
Positron emission mammography (PEM) is a form of positron emission tomography that uses high-resolution, mini-camera detection technology for imaging the breast. As with positron emission tomography, PEM provides functional rather than anatomic information about the breast. PEM has been studied primarily for use in presurgical planning and evaluation of breast lesions.

For individuals who are being screened for breast cancer, the evidence includes a retrospective study. The relevant outcomes are overall survival, disease-specific survival, test accuracy and validity, and resource utilization. It has not been demonstrated that PEM provides better diagnostic accuracy than the relevant comparators nor has PEM been shown to provide clinical utility. In addition, without demonstrated advantages in clinical utility, the relatively high radiation dosage associated with PEM does not favor its use given that alternative tests deliver lower doses. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals with clinically localized breast cancer undergoing presurgical evaluation, the evidence includes prospective studies. The relevant outcomes are overall survival, disease-specific survival, test accuracy and validity, and resource utilization. It has not been demonstrated that PEM provides better diagnostic accuracy than the relevant comparators nor has PEM been shown to provide clinical utility. In addition, without demonstrated advantages in clinical utility, the relatively high radiation dosage associated with PEM does not favor its use given that alternative tests deliver lower doses. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals with a suspicious breast lesion on conventional breast cancer evaluation, the evidence includes prospective studies as well as a meta-analysis. The relevant outcomes are overall survival, disease-specific survival, test accuracy and validity, and resource utilization. It has not been demonstrated that PEM provides better diagnostic accuracy than the relevant comparators nor has PEM been shown to provide clinical utility. In addition, without demonstrated advantages in clinical utility, the relatively high radiation dosage associated with PEM does not favor its use given that alternative tests deliver lower doses. The evidence is insufficient to determine the effects of the technology on health outcomes.

Background
Positron Emission Mammography
PEM is a form of positron emission tomography (PET) that uses a high-resolution, mini-camera detection technology for imaging the breast. As with PET, a radiotracer (usually fluorine 18 fluorodeoxyglucose) is administered, and the camera is used to provide a higher-resolution image of a limited section of the body than would be achievable with fluorine 18 fluorodeoxyglucose PET. Gentle compression is used, and the detector(s) are mounted directly on the compression paddle(s).^1,^2,3

PEM was developed to overcome the limitations of PET for detecting breast cancer tumors. Patients are usually supine for PET procedures; further, breast tissue may spread over the chest wall, making it potentially difficult to differentiate breast lesions from other organs that take up the radiotracer. PET’s resolution is generally limited to approximately 5 mm, which may not detect early breast cancer tumors.⁴ PEM allows for the detection of lesions as small as 2 to 3 mm and creates images that are more easily compared with mammography because they are acquired in the same position.^2,⁵ Three-dimensional reconstruction of PEM images also is possible. As with PET, PEM provides functional rather than anatomic information about the breast.^1,^2,³ In PEM studies, exclusion criteria have included some patients with diabetes (e.g., Berg et al. [2011; 2012]^6,⁷).

Radiation Dose Associated With PEM
The label-recommended dose of fluorine 18 fluorodeoxyglucose for PEM is 370 MBq (10 mCi). Hendrick (2010) calculated mean glandular doses, and from the doses was able to determine lifetime attributable risk (LAR) of cancer for film mammography, digital mammography, breast-specific gamma imaging (BSGI), and PEM.⁸ The author used BEIR VII Group risk estimates⁹ to gauge the risks of radiation-induced cancer incidence and mortality from breast imaging studies. Estimated LAR of cancer for a patient with an average-sized compressed breast during mammography of 5.3 cm (risks would be higher for larger breasts) for a single breast procedure at age 40 years was calculated as:

5 per 100,000 for digital mammography (breast cancer only).
7 per 100,000 for screen-film mammography (breast cancer only).
55 to 82 per 100,000 for BSGI (depending on the dose of technetium 99m sestamibi).
75 per 100,000 for PEM.

The corresponding LAR of cancer mortality at age 40 years was:

1.3 per 100,000 for digital mammography (breast cancer only).
1.7 per 100,000 for screen-film mammography (breast cancer only).
26 to 39 per 100,000 for BSGI.
31 per 100,000 for PEM.

A major difference in the impact of radiation between mammography and BSGI or PEM is that in mammography radiation dose is limited to the breast; whereas with BSGI and PEM, all organs are irradiated. Furthermore, as one ages, the risk of cancer induction from radiation exposure decreases more rapidly for the breast than for other radiosensitive organs. Organs at highest risk for cancer are the bladder with PEM and the colon with BSGI; these cancers, along with lung cancer, are also less curable than breast cancer. Thus, the distribution of radiation throughout the body adds to the risks associated with BSGI and PEM. Hendrick concluded that⁸ "... BSGI and PEM are not good candidate procedures for breast cancer screening because of the associated higher risks for cancer induction per study compared with the risks associated with existing modalities such as mammography, breast US [ultrasound] and breast MR [magnetic resonance] imaging. The benefit-to-risk ratio for BSGI and PEM may be different in women known to have breast cancer, in whom additional information about the extent of disease may better guide treatment."

O’Connor et al. (2010) estimated the LAR of cancer and cancer mortality from the use of digital mammography, screen-film mammography, PEM and molecular breast imaging.¹⁰ Only results for digital mammography and PEM are reported here. The authors concluded that, in a group of 100,000 women at age 80 years, a single digital mammogram at age 40 years would induce 4.7 cancers with 1.0 cancer deaths; 2.2 cancers with 0.5 cancer deaths for a mammogram at age 50; 0.9 cancers with 0.2 cancer deaths for a mammogram at age 60; and 0.2 cancers with 0.0 cancer deaths for a mammogram at age 70. Comparable numbers for PEM would be 36 cancers and 17 cancer deaths for PEM at age 40; 30 cancers and 15 cancer deaths for PEM at age 50; 22 cancers and 12 cancer deaths for PEM at age 60; and 9.5 cancers and 5.2 cancer deaths for PEM at age 70. The authors also analyzed the cumulative effect of annual screening between the ages of 40 and 80, as well as between the ages of 50 and 80. For women at age 80 who were screened annually from the ages of 40 to 80, digital mammography would induce 56 cancers with 15 cancer deaths; for PEM, the analogous numbers were 800 cancers and 408 cancer deaths. For women at age 80 who were screened annually from the ages of 50 to 80, digital mammography would induce 21 cancers with 6 cancer deaths; for PEM, the analogous numbers were 442 cancers and 248 cancer deaths. However, background radiation from age 0 to 80 is estimated to induce 2,174 cancers and 1,011 cancer deaths.

These calculations, like all estimated health effects of radiation exposure, are based on several assumptions. When comparing digital mammography with PEM, two conclusions become clear: Many more cancers are induced by PEM than by digital mammography, and for both modalities, adding annual screening from age 40 to 49 roughly doubles the number of induced cancers. In a benefit-risk calculation performed for digital mammography but not for PEM, O’Connor et al. (2010) nevertheless reported that the benefit-risk ratio of annual screening is still approximately 3 to 1 for women in their 40s, although it is much higher for women age 50 and older. Like Hendrick (2010),⁸ the authors concluded that “if molecular imaging techniques [including PEM] are to be of value in screening for breast cancer, then the administered doses need to be substantially reduced to better match the effective doses of mammography.”¹⁰

The American College of Radiology has assigned a relative radiation level (effective dose) of 10 to 30 mSv to PEM.¹¹ The college has also stated that, because of radiation dose, PEM and BSGI in their present form are not indicated for screening.

Because the use of BSGI and molecular breast imaging have been proposed for women at high-risk of breast cancer, it should be noted there is controversy and speculation whether some women (e.g., those with BRCA variants) have heightened radiosensitivity.^12,¹³ If women with BRCA variants are more radiosensitive than the general population, the previous estimates may underestimate the risks they face from breast imaging with ionizing radiation (i.e., mammography, BSGI, molecular breast imaging, PEM, single-photon emission computed tomography, breast-specific computed tomography and tomosynthesis; ultrasound and magnetic resonance imaging do not use radiation). More research will be needed to resolve this issue. Also, risks associated with radiation exposure will be greater for women at high risk of breast cancer (regardless of whether they are more radiosensitive) because they start screening at a younger age when the risks associated with radiation exposure are increased.

Regulatory Status
In 2003, the PEM 2400 PET Scanner (PEM Technologies) was cleared for marketing by the U.S. Food and Drug Administration (FDA) through the 510(k) process. The FDA determined that this device was substantially equivalent to existing devices for “medical purposes to image and measure the distribution of injected positron-emitting radiopharmaceuticals in human beings for the purpose of determining various metabolic and physiologic functions within the human body.”¹⁴

In 2009, the Naviscan PEM Flex™ Solo II™ High Resolution PET Scanner (Naviscan) was cleared for marketing by the FDA through the 510(k) process for the same indication. The PEM 2400 PET Scanner was the predicate device. The newer device has been described by the manufacturer as “a high spatial resolution, small field-of-view PET imaging system specifically developed for close-range, spot, i.e., limited field, imaging.”

In 2013, Naviscan was acquired by Compañía Mexicana de Radiología SA,¹⁵ which currently markets the Naviscan Solo II™ Breast PET Scanner in the U.S. (CMR Naviscan). FDA product code: KPS.

Related Policies:
60118 Scintimammography/Breast-Specific Gamma Imaging/Molecular Breast Imaging
60126 Oncologic Applications of PET Scanning
60129 Magnetic Resonance Imaging (MRI) of the Breast
60153 Digital Breast Tomosynthesis

Policy
The use of positron emission mammography (PEM) is investigational and/or unproven and therefore is considered NOT MEDICALLY NECESSARY.

Policy Guidelines
There are no specific CPT codes for PEM.

The most appropriate code would probably be the unlisted diagnostic nuclear medicine code (78999) or the PET imaging limited area code might be used:
78811: Positron emission tomography (PET) imaging; limited area (e.g., chest, head/neck).

Benefit Application
BlueCard/National Account Issues
State or federal mandates (e.g., FEP) may dictate that all FDA-approved devices, drugs, or biologics may not be considered investigational, and thus these devices may be assessed only on the basis of their medical necessity.

Rationale
Evidence reviews assess whether a medical test is clinically useful. A useful test provides information to make a clinical management decision that improves the net health outcome. That is, the balance of benefits and harms is better when the test is used to manage the condition than when another test or no test is used to manage the condition.

The first step in assessing a medical test is to formulate the clinical context and purpose of the test. The test must be technically reliable, clinically valid, and clinically useful for that purpose. Evidence reviews assess the evidence on whether a test is clinically valid and clinically useful. Technical reliability is outside the scope of these reviews, and credible information on technical reliability is available from other sources.

Positron Emission Mammography as a Screening Test for Breast Cancer
Clinical Context and Test Purpose
The purpose of PEM in patients who undergo breast cancer screening is to inform a decision whether to proceed to further diagnostic testing.

The question addressed in this evidence review is: Does the use of PEM improve the net health outcome?

The following PICO was used to select literature to inform this review.

Population
The relevant population of interest are women who are at average or high risk of breast cancer and scheduled for routine screening.

Interventions
The test being considered is PEM.

PEM is administered in a dedicated breast imaging unit.

Comparators
The following tests are currently being used to make decisions about managing breast screening: mammography, ultrasound and magnetic resonance imaging (MRI).

Outcomes
The general outcomes of interest are diagnostic accuracy measures including sensitivity, specificity. positive predictive value (PPV), and negative predictive value (NPV). Additional outcomes are the occurrence of breast cancer and breast cancer-related survival.

Beneficial outcomes of a true-positive test result are early diagnosis and treatment. Beneficial outcomes of a true-negative test result are the avoidance of additional testing, including biopsy.

The harmful outcome of a false-positive test is further testing including biopsy. Harmful outcomes of a false-negative test are a late diagnosis of breast cancer leading to a requirement for adjunctive treatment with chemotherapy or radiotherapy and poorer outcomes.

Direct harms of the test are from radiation exposure. The American College of Radiology has assigned a relative radiation level (effective dose) of 10 to 30 mSv to PEM, which the college considers too high for a screening test.¹¹

The reference standard is histopathology or at least one year of follow-up for women with negative findings. Follow-up over 10 to 20 years would be needed to monitor for the occurrence of breast cancer, breast cancer-related survival and overall survival (OS).

Technically Reliable
Assessment of technical reliability focuses on specific tests and operators and requires a review of unpublished and often proprietary information. Review of specific tests, operators and unpublished data are outside the scope of this evidence review and alternative sources exist. This evidence review focuses on the clinical validity and clinical utility.

Clinically Valid
A test must detect the presence or absence of a condition, the risk of developing a condition in the future, or treatment response (beneficial or adverse).

Yamamoto et al. (2016) retrospectively reviewed the opportunistic use of PEM for breast cancer screening in 265 women with breast symptoms.¹⁶ Images were evaluated by agreement between two experienced readers who had access to clinical information. The maximum PEM uptake value (PUVmax) was calculated by tissue concentration (mCi/g) × body weight (g)/injected fluorine 18 fluorodeoxyglucose (FDG) dose (in millicuries [mCi]). Using a threshold of 1.97, 22 (8.3%) women had abnormal uptake and were recalled. Six (2.3%) cancers were found by PEM. Although higher than the usual detection rate with mammography and physical examination, this was not a general screening population. Sensitivity (76%) and specificity (85%) were calculated by clinical follow-up for this population.

A few studies have reported mixed results whether the sensitivity of PEM is affected by breast tissue density and how PEM compares with MRI of the breast.^6,17

Clinically Useful
A test is clinically useful if the use of the results informs management decisions that improve the net health outcome of care. The net health outcome can be improved if patients receive correct therapy, or more effective therapy, or avoid unnecessary therapy, or avoid unnecessary testing.

Direct Evidence
Direct evidence of clinical utility is provided by studies that have compared health outcomes for patients managed with and without the test. Because these are intervention studies, the preferred evidence would be from RCTs.

No RCTs were identified assessing the clinical utility of PEM as a screening test for breast cancer.

Chain of Evidence
Indirect evidence on clinical utility rests on clinical validity. If the evidence is insufficient to demonstrate test performance, no inferences can be made about clinical utility.

Because the clinical validity of PEM as a screening test for breast cancer has not been established, a chain of evidence supporting PEM’s clinical utility cannot be constructed.

Section Summary: Positron Emission Mammography as a Screening Test for Breast Cancer
A single study was identified that evaluated the use of PEM for breast cancer screening, which is insufficient evidence on which to draw conclusions.

Positron Emission Mammography for Pre-surgical Evaluation of Clinically Localized Breast Cancer
Clinical Context and Test Purpose
The purpose of PEM in patients who have a malignant breast lesion is to inform the surgical approach. Testing seeks to identify if there are multifocal or contralateral cancerous lesions that may lead to different treatment recommendations such as mastectomy instead of breast-conserving surgery.

The question addressed in this evidence review is: Does the use of PEM improve the net health outcome?

The following PICO was used to select literature to inform this review.

Population
The relevant population of interest are individuals with clinically localized breast cancer undergoing pre-surgical evaluation who receive PEM.

Interventions
The test being considered is PEM.

PEM is administered in a dedicated breast imaging unit.

Comparators
The following practices are currently being used to make decisions about the pre-surgical evaluation of breast cancer: mammography and breast MRI are established imaging modalities for pre-surgical evaluation. Histopathology of an identified lesion is the criterion standard for evaluating the test.

Outcomes
The general outcomes of interest are diagnostic accuracy measures including sensitivity, specificity, PPV, and NPV. Test sensitivity is important for pre-surgical clinical decision making.

Beneficial outcomes of a true-positive test include the successful removal of a cancerous lesion. Beneficial outcomes of a true-negative test are the avoidance of an unnecessary biopsy.

Harmful outcomes of a false-negative test result are missing lesions, leading to more advanced cancer and reduced survival. A false-positive test is less critical since biopsy confirmation would resolve lesion status as part of developing a cancer management recommendation.

Direct harms of the test are from radiation exposure, which has been reported by the American College of Radiology to be high at 10 to 30 mSv.

Follow-up over 10 to 20 years would be needed to monitor for the occurrence of breast cancer and breast cancer-related survival.

Technically Reliable
Assessment of technical reliability focuses on specific tests and operators and requires a review of unpublished and often proprietary information. Review of specific tests, operators, and unpublished data are outside the scope of this evidence review and alternative sources exist. This evidence review focuses on the clinical validity and clinical utility.

Clinically Valid
A test must detect the presence or absence of a condition, the risk of developing a condition in the future, or treatment response (beneficial or adverse).

Prospective Studies
Schilling et al. (2011) conducted a single-site, prospective study comparing PEM with MRI (1.5 tesla) for pre-surgical planning in 182 patients.¹⁷The performances of PEM, MRI and whole-body positron emission tomography (WBPET) were compared with final surgical histopathology in women with newly diagnosed, biopsy-proven breast cancer. For PEM and WBPET (performed consecutively), median FDG dose was 432.9 MBq (equivalent to 11.7 mCi); four- to six-hour fasting glucose less than 7.8 mmol/L was required for study entry. One of the six readers evaluated PEM, radiographic mammography, and magnetic resonance images with access to conventional imaging (mammography or ultrasound) results “but without influence of the alternative (PEM or MRI) imaging modality;” WBPET images were interpreted by a nuclear medicine physician. Almost half (46%) of lesions were clinically palpable. On pathology, 78% of patients had an invasive disease, 21% had ductal carcinoma in situ (DCIS), and 2% had Paget disease. For index lesions, both PEM and MRI had a sensitivity of 93% (p = NS), which was greater than the sensitivity of WBPET (68%; p < 0.001). The specificity was not reported because only malignant index lesions were analyzed. The sensitivity of PEM and MRI was not affected by breast density, menopausal status or use of hormone replacement therapy. Correlation between tumor size on histopathology vs. size on PEM or MRI was the same (r=0.61). Twelve lesions were missed on both PEM and MRI; three were not in the PEM field-of-view due to patient positioning. For 67 additional ipsilateral lesions detected (40 malignancies), the sensitivity of PEM and MRI was 85% and 98% (p = 0.074), respectively; and the specificity of PEM and MRI was 74% and 48% (p = 0.096), respectively. Further investigation is needed to determine whether these are two points along the same operating curve (i.e., whether PEM is being read to emphasize specificity compared with MRI).

Berg et al. (2011) compared PEM with MRI in a multicenter study of 388 women who had newly diagnosed breast lesions confirmed with core-needle or vacuum-assisted biopsy.⁶ The study was funded in part by the manufacturer and the National Institutes of Health. Mean FDG dose with PEM was 10.9 mCi, and the mean blood glucose level was 91 g/dL. PEM and MRI were read by different investigators; some but not all readers were blinded to results of the other test. PEM results with a Breast Imaging-Reporting and Data System score of 4a or higher or a score of 3 with a recommendation for biopsy were considered positive. Negative cases included those with negative pathology or follow-up of at least six months with no suspicious change. After surgery, 386 lesion sites in 370 breasts were confirmed. Among 386 surgically confirmed lesion sites, there was no statistically significant difference in the sensitivity of PEM (93%) and MRI (89%) when only tumor sites were included (p=0.79). When tumors and biopsy sites were visualized, MRI had higher sensitivity (98%) than PEM (95%; p = 0.004). Of 388 enrolled women, 82 (21%) had additional tumor foci after study entry. Sensitivity for identifying breasts with these lesions was 60% for MRI and 51% for PEM. Of 82 additional lesions, 21 (26%) were detected only with MRI, 14 (17%) only with PEM (p = 0.31), and 7 (8.5%) only with conventional imaging. Adding PEM to MRI increased sensitivity from 60% to 72% (p < 0.01). Twelve women who had additional foci in the breast with the primary tumor were not identified by any of the imaging techniques. Among women with an index tumor and no additional lesions in the ipsilateral breast, PEM (91%) was more specific than MRI (86%; p = 0.032). The statistical difference between PEM and MRI area under the receiver operating characteristic curve did not differ significantly. As in the study by Schilling et al. (2011), the question arises whether differences in sensitivity and specificity between the two tests arose from selecting different operating points along the receiver operating characteristic curve.

Of 116 malignant lesions unknown at study entry, 53% were reported as suspicious on MRI vs 41% on PEM (p = 0.04). There was no difference between PEM and MRI in detecting DCIS in this study (41% vs. 39%; p = 0.83). Adding PEM to MRI would increase the sensitivity for detecting DCIS from 39% (MRI alone) to 57% (combined; p = 0.001); another seven DCIS foci were seen only on conventional imaging. MRI was more sensitive than PEM in detecting invasive cancer (64% vs. 41%; p = 0.004), but the two combined had a higher sensitivity than MRI alone (73% vs. 64%; p = 0.025). MRI was more sensitive than PEM in dense breasts (57% vs. 37%; p = 0.031).

In a second report from the Berg et al. (2012) study (discussed above), the respective performance of PEM and MRI for detecting lesions in the contralateral breast were compared.⁷ In this case, readers were blinded to results of the other test but knew the results of conventional imaging and pathology from pre-study biopsies. After recording results for a single modality, readers then assessed results across all modalities. The final patient sample size was 367; nine patients were excluded because the highest scored lesion was a Breast Imaging-Reporting and Data System 3 (probably benign) based on all imaging. No follow-up or histopathology was performed. The contralateral breast could not be assessed in 12 women (e.g., due to prior mastectomy or lumpectomy and radiotherapy).

Fifteen (4%) of the 367 participants had contralateral cancer. PEM detected cancer in three of these women and MRI in 14. The sensitivity of PEM and MRI was 20% and 93%, respectively (p < 0.001), and the specificity was 95% and 90%, respectively (p = 0.002). The area under the receiver operating characteristic curve was 68% for PEM and 96% for MRI (p < 0.001). Among women undergoing biopsies, the PPV did not differ statistically between modalities (21% for PEM vs. 28% for MRI; p = 0.58). There were more benign biopsies based on MRI results (39 biopsies in 34/367 women) than on PEM results (11 biopsies in 11/367 women; p < 0.001). The authors discussed possible improvements in interpreting PEM, based in part on results of having the lead investigators reread the PEM images. The authors determined that 7 of 12 false-negative PEM results were due to investigator error. The error could only be confirmed through further study. The authors also noted that a substantial proportion of contralateral lesions could be effectively treated by chemotherapy and that PEM cannot optimally evaluate the extreme posterior breast. Additional articles have assessed the same study, focusing on identifying malignant characteristics on PEM and on training and evaluating readers of PEM.^18,19

In an early four-site clinical study, Tafra et al. (2005) imaged 94 women with suspected (n = 50) or proven (n = 44) breast cancer with PEM.²⁰ Additional study details are reviewed in the next section. Of note, PEM correctly detected multifocality in 64% of 31 patients evaluated for it and correctly predicted its absence in 17 patients.

No RCTs were identified assessing the clinical utility of PEM as a pre-surgical test to localize breast lesions.

Because the clinical validity of PEM as a pre-surgical test to localize breast lesions has not been established, the chain of evidence supporting the clinical utility of this test cannot be constructed.

Section Summary: Positron Emission Mammography for Pre-surgical Evaluation of Clinically Localized Breast Cancer
Results for diagnostic performance of PEM in the pre-surgical evaluation of clinically localized breast cancer from three multicenter and one single-site studies have reported that PEM may be able to detect ipsilateral cancer lesions or lesions in the contralateral breast with moderate sensitivity but usually low specificity. Studies that compared PEM with MRI, which may be used in this clinical context, generally found that MRI was more sensitive than PEM. Test sensitivity is important for pre-surgical clinical decision making since additional testing seeks to identify if there are multifocal or contralateral cancerous lesions that may lead to different treatment such as mastectomy instead of breast-conserving surgery. Specificity is less critical because biopsy confirmation would resolve lesion status as part of developing a cancer management recommendation.

Positron Emission Mammography for a Suspicious Breast Lesion on Conventional Breast Cancer Evaluation
Clinical Context and Test Purpose
The purpose of PEM in patients who have a suspicious breast lesion is to inform a decision of whether to proceed with a biopsy. Suspicious breast lesions on conventional breast cancer evaluation would generally be recommended for biopsy.

The question addressed in this evidence review is: Does the use of PEM improve the net health outcome?

The following PICO was used to select literature to inform this review.

Population
The relevant population of interest are women who have localized suspicious breast lesion identified during the conventional evaluation.

Interventions
The test being considered is PEM.

PEM is administered in a dedicated breast imaging unit.

Comparators
The following practices are currently being used to make decisions about managing suspicious breast lesions breast cancer: biopsy, diagnostic mammography views and MRI. Biopsy with histopathology of identified lesions is the criterion standard for evaluating the test.

Outcomes
Outcomes of interest are diagnostic validity (sensitivity, specificity, PPV and NPV).

The beneficial outcome of a true-negative test is to avoid biopsy by downgrading suspicion of malignancy. The beneficial outcome of a true-positive test is appropriate biopsy and treatment.

Harmful outcomes of a false-negative result include failure to proceed to diagnosis and treatment. Harmful outcomes of a false-positive test are an unnecessary biopsy.

Direct harms of the test are from radiation exposure, which has been reported by the American College of Radiology to be high at 10 to 30 mSv.

Follow-up of at least one year would be needed to monitor suspicious breast findings on mammography that are not biopsied. A clinical pathway for repeat use of PEM has not been identified. Follow-up over 10 to 20 years would be needed to monitor for the occurrence of breast cancer and breast cancer-related survival.

Clinically Valid
A test must detect the presence or absence of a condition, the risk of developing a condition in the future or treatment response (beneficial or adverse).

Systematic Reviews
Caldarella et al. (2014) conducted a meta-analysis of PEM studies in women with newly discovered breast lesions suspicious for malignancy.²¹ Literature was searched through January 2013. Eight studies (total n = 873 patients) of 10 or more patients (range, 16 – 388 patients) that used the histologic review as the criterion standard, including three studies described in detail next, were included. The pooled sensitivity and specificity were 85% (95% confidence interval, 83% to 88%; I2 = 74%) and 79% (95% confidence interval, 74% to 83%; I2 = 63%), respectively. The pooled PPV and NPV were 92% and 64%, respectively. Comparator arms were not pooled. Other limitations of selected studies included substantial statistical heterogeneity and lack of blinding of both PEM and histopathology readers.

In a four-site clinical study, Tafra et al. (2005) imaged 94 women who had suspected (n = 50) or proven (n = 44) breast cancer with PEM.²⁰ The median dose of FDG was 13 mCi; median patient age was 57 years, and median tumor size was 22 mm on pathology review. Seventy-seven percent of primary lesions were nonpalpable. Cases deemed “unevaluable” were excluded (not reported). Eight readers had access to mammography and clinical breast examination results as well as clinical information but no information on surgical planning or outcomes. At least two readers evaluated each case in random order. The performance of PEM in this study is listed next; results are detailed to illustrate potential uses of PEM:

A Breast Imaging-Reporting and Data System category of 4b, 4c or 5 (probably malignant) was assigned to 39 (89%) of 44 pathologically confirmed breast cancers. Five missed lesions ranged in size from 1 to 10 mm, and four were low grade.
Extensive DCIS was predicted in three cases and confirmed to be malignant; the tumors were not detected by other imaging modalities.
Among 44 patients with proven breast cancer, five incidental benign lesions were correctly classified, and 4 of 5 incidental malignant tumors were detected, three of which were not detected with other imaging modalities (it was not evident whether MRI was performed on these specific patients).
PEM correctly detected multifocality in 64% of 31 patients evaluated for it and correctly predicted its absence in 17 patients.
PEM correctly predicted 6 of 8 patients undergoing partial mastectomy who had positive margins and 11 of 11 who had negative margins.

Berg et al. (2006) published an evaluation of PEM in 77 patients.²² Patients with Type 1 or Type 2 diabetes were excluded because FDG is glucose-based, and diabetic patients must have well-controlled glucose for the test to work. Median age was 53 years. Of 77 patients, 33 had suspicious findings on core biopsy before PEM, 38 had abnormalities on radiographic mammography, and six had suspicious findings on clinical breast exam. Five women had personal histories of breast cancer, one of whom had reconstructive surgery. Readers had access to mammographic and clinical findings because it was assumed they would in clinical practice. The median dose of FDG was 12 mCi (range, 8.2 – 21.5 mCi). Forty-two of 77 cases were malignant, and two had atypical ductal hyperplasia. Sensitivity and specificity rates for PEM were 93% and 85%, respectively, for index lesions, and 90% and 86%, respectively, for index and incidental lesions. These values were similar or higher if lesions were clearly benign on conventional imaging. Adding PEM to radiographic mammography and ultrasound (when available) yielded sensitivity and specificity of 98% and 41%, respectively. (The specificity of PEM combined with conventional imaging was lower than PEM alone due to a large number of false-positive lesions prompted by conventional imaging.)

Muller et al. (2016) evaluated the diagnostic accuracy of PEM using PUVmax as a threshold (instead of a ratio) in 108 patients with 151 suspected lesions.²³ FDG dose was 3.5 MBq/kg of body weight, with a mean of 231.8 MBq. PUV in lesions, tumors, benign lesions and healthy tissue on the contralateral side were assessed. The biopsy could be performed at the same time as the PEM using the same machine, and suspected carcinoma was compared with histopathology. The mean PUVmax for malignant tumors was 3.78, and the mean PUVmax for normal breast tissue was 1.17 (p < 0.001). Using a PUV of more than 1.9 as a threshold, 31 (20.5%) of 151 lesions were identified as malignant and underwent biopsy. Histopathologic evaluation showed 26 malignant (true-positive) and five benign (false-positive) lesions. No false-negative lesions were reported, although only lesions suspected of carcinoma by PEM underwent histopathologic analysis. Patients not biopsied had a clinical follow-up for three years. The threshold of 1.9 was found via receiver operating characteristic analysis. At this threshold, PEM was reported to have 100% sensitivity and 96% specificity. Based on these positive results, the German health administration has funded a follow-up multicenter study.

No RCTs were identified assessing the clinical utility of PEM as a test to identify suspicious breast lesions.

Because the clinical validity of PEM as a pre-surgical test to identify suspicious lesions has not been established, the chain of evidence supporting the clinical utility of this test cannot be constructed.

Section Summary: Positron Emission Mammography for Suspicious Breast Lesion on Conventional Breast Cancer Evaluation
Results for diagnostic performance of PEM in the evaluation of suspicious breast lesions on conventional breast cancer evaluation are available from a meta-analysis as well as three other studies. Pooled results from the meta-analysis showed moderate sensitivity and specificity and reasonably high PPV given the population of suspicious lesions. However, the NPV was relatively low (64%). Because suspicious breast lesions on conventional breast cancer evaluation would generally be recommended for biopsy, the proposed clinical use for PEM would be to avoid biopsy by ruling out malignancy. The diagnostic performance from the available studies and low NPV in this population would not support clinical utility in these patients.

Other Indications
No full-length, published studies were identified that addressed management of breast cancer and evaluation for breast cancer recurrence.

Summary of Evidence
For individuals who are being screened for breast cancer, the evidence includes a retrospective study. Relevant outcomes are overall survival, disease-specific survival, test accuracy and validity, and resource utilization. It has not been demonstrated that PEM provides better diagnostic accuracy than the relevant comparators nor has PEM been shown to provide clinical utility. In addition, without demonstrated advantages in clinical utility, the relatively high radiation dosage associated with PEM does not favor its use given that alternative tests deliver lower doses. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals with clinically localized breast cancer undergoing pre-surgical evaluation, the evidence includes prospective studies. Relevant outcomes are overall survival, disease-specific survival, test accuracy and validity, and resource utilization. It has not been demonstrated that PEM provides better diagnostic accuracy than the relevant comparators nor has PEM been shown to provide clinical utility. In addition, without demonstrated advantages in clinical utility, the relatively high radiation dosage associated with PEM does not favor its use given that alternative tests deliver lower doses. The evidence is insufficient to determine the effects of the technology on health outcomes.

For individuals with a suspicious breast lesion on conventional breast cancer evaluation, the evidence includes prospective studies as well as a meta-analysis. Relevant outcomes are overall survival, disease-specific survival, test accuracy and validity, and resource utilization. It has not been demonstrated that PEM provides better diagnostic accuracy than the relevant comparators nor has PEM been shown to provide clinical utility. In addition, without demonstrated advantages in clinical utility, the relatively high radiation dosage associated with PEM does not favor its use given that alternative tests deliver lower doses. The evidence is insufficient to determine the effects of the technology on health outcomes.

Practice Guidelines and Position Statements
American College of Radiology
In 2017, the American College of Radiology has included positron emission mammography (PEM) in its criteria on breast screening.¹¹ PEM was rated as “usually not appropriate” for screening women at average or high risk for breast cancer. The college has also assigned a relative radiation level (effective dose) of 10 to 30 mSv to PEM and stated that PEM is limited “by radiation dose and lack of evidence in large screening population.”

National Comprehensive Cancer Network
Current National Comprehensive Cancer Network(v.1.2019) guidelines for breast cancer screening and diagnosis do not include PEM.²⁴

U.S. Preventive Services Task Force Recommendations
No U.S. Preventive Services Task Force recommendations for PEM have been identified.

Ongoing and Unpublished Clinical Trials
Some currently ongoing and unpublished trials that might influence this review are listed in Table 1.

Table 1. Summary of Key Trials

NCT No.	Trial Name	Planned Enrollment	Completion Date
Ongoing
NCT03520218	A Pilot Study to Evaluate Low-Dose Positron Emission Mammography Imaging in Visualization and Characterization of Suspicious Breast Abnormalities	100	Jun 2020
Unpublished
NCT01241721	Clinical Value of Pre-Surgery Positron Emission Mammography (PEM) in Patients With Newly Diagnosed Breast Cancer	34	Apr 2016(completed)
NCT00896649	Impact of Dedicated Breast Positron Emission Mammography vs. Conventional Two-View Digital Mammography on Recall Rates and Cancer Detection as a Screening Examination in Underserved Women	193	Jan 2017(completed)
NCT02770586	Comparison of Positron Emission Mammography and Contrast- enhanced Breast MRI in Women With a High Suspicion of Breast Cancer	50	Oct 2019 (completed)

NCT: national clinical trial.
^a Denotes industry-sponsored or cosponsored trial.

References:

Birdwell RL, Mountford CE, Iglehart JD. Molecular imaging of the breast. AJR Am J Roentgenol. Aug 2009; 193(2):367- 76. PMID 19620433
Eo JS, Chun IK, Paeng JC, et al. Imaging sensitivity of dedicated positron emission mammography in relation to tumor size. Breast. Feb 2012; 21(1): 66-71. PMID 21871801
Tafreshi NK, Kumar V, Morse DL, et al. Molecular and functional imaging of breast cancer. Cancer Control. Jul 2010; 17(3): 143-55. PMID 20664511
Prekeges J. Breast imaging devices for nuclear medicine. J Nucl Med Technol. Jun 2012; 40(2): 71-8. PMID 22562462
Shkumat NA, Springer A, Walker CM, et al. Investigating the limit of detectability of a positron emission mammography device: a phantom study. Med Phys. Sep 2011; 38(9): 5176-85. PMID 21978062
Berg WA, Madsen KS, Schilling K, et al. Breast cancer: comparative effectiveness of positron emission mammography and MR imaging in presurgical planning for the ipsilateral breast. Radiology. Jan 2011; 258(1): 59-72. PMID 21076089
Berg WA, Madsen KS, Schilling K, et al. Comparative effectiveness of positron emission mammography and MRI in the contralateral breast of women with newly diagnosed breast cancer. AJR Am J Roentgenol. Jan 2012; 198(1): 219- 32. PMID 22194501
Hendrick RE. Radiation doses and cancer risks from breast imaging studies. Radiology. Oct 2010; 257(1): 246-53. PMID 20736332
Research Council of the National Academies. Health risks from exposure to low levels of ionizing radiation: BEIR VII, Phase 2--Committee to Assess Health Risks for Exposure to Low Levels of Ionizing Radiation. Washington, DC: National Academies Press; 2006.
O'Connor MK, Li H, Rhodes DJ, et al. Comparison of radiation exposure and associated radiation-induced cancer risks from mammography and molecular imaging of the breast. Med Phys. Dec 2010; 37(12): 6187-98. PMID 21302775
American College of Radiology (ACR). ACR Appropriateness Criteria breast cancer screening. 2017; https://acsearch.acr.org/docs/70910/Narrative/. Accessed August 23, 2018.
Berrington de Gonzalez A, Berg CD, Visvanathan K, et al. Estimated risk of radiation-induced breast cancer from mammographic screening for young BRCA mutation carriers. J Natl Cancer Inst. Feb 04 2009; 101(3): 205-9. PMID 19176458
Ernestos B, Nikolaos P, Koulis G, et al. Increased chromosomal radiosensitivity in women carrying BRCA1/BRCA2 mutations assessed with the G2 assay. Int J Radiat Oncol Biol Phys. Mar 15 2010; 76(4): 1199-205. PMID 20206018
Food and Drug Administration (FDA). 510(k) Summary: PEM 2400 PET Scanner. 2003; https://www.accessdata.fda.gov/cdrh_docs/pdf3/K032063.pdf. Accessed August 23, 2018.
Fikes BJ. Naviscan's assets sold to Mexican company San Diego Union-Tribune. Dec 11, 2013; http://www.utsandiego.com/news/2013/Dec/11/naviscan-sold-mexican-cmr-positron/.
Yamamoto Y, Tasaki Y, Kuwada Y, et al. A preliminary report of breast cancer screening by positron emission mammography. Ann Nucl Med. Feb 2016; 30(2): 130-7. PMID 26586370
Schilling K, Narayanan D, Kalinyak JE, et al. Positron emission mammography in breast cancer presurgical planning: comparisons with magnetic resonance imaging. Eur J Nucl Med Mol Imaging. Jan 2011; 38(1): 23-36. PMID 20871992
Narayanan D, Madsen KS, Kalinyak JE, et al. Interpretation of positron emission mammography and MRI by experienced breast imaging radiologists: performance and observer reproducibility. AJR Am J Roentgenol. Apr 2011; 196(4): 971-81. PMID 21427351
Narayanan D, Madsen KS, Kalinyak JE, et al. Interpretation of positron emission mammography: feature analysis and rates of malignancy. AJR Am J Roentgenol. Apr 2011; 196(4): 956-70. PMID 21427350
Tafra L, Cheng Z, Uddo J, et al. Pilot clinical trial of 18F-fluorodeoxyglucose positron-emission mammography in the surgical management of breast cancer. Am J Surg. Oct 2005; 190(4): 628-32. PMID 16164937
Caldarella C, Treglia G, Giordano A. Diagnostic performance of dedicated positron emission mammography using fluorine-18-fluorodeoxyglucose in women with suspicious breast lesions: a meta-analysis. Clin Breast Cancer. Aug 2014; 14(4): 241-8. PMID 24472718
Berg WA, Weinberg IN, Narayanan D, et al. High-resolution fluorodeoxyglucose positron emission tomography with compression ( positron emission mammography ) is highly accurate in depicting primary breast cancer. Breast J. Jul-Aug 2006; 12(4): 309-23. PMID 16848840
Muller FH, Farahati J, Muller AG, et al. Positron emission mammography in the diagnosis of breast cancer. Is maximum PEM uptake value a valuable threshold for malignant breast cancer detection?. Nuklearmedizin. 2016; 55(1): 15-20. PMID 26627876
National Comprehensive Cancer Network (NCCN). NCCN Clinical Practice Guidelines in Oncology: Breast Cancer Screening and Diagnosis. Version 1.2019. https://www.nccn.org/professionals/physician_gls/pdf/breast-screening.pdf. Accessed August 31, 2020.

Coding Section

Codes	Number	Description
CPT	78999	Unlisted miscellaneous procedure, diagnostic nuclear medicine
	78111	Positron emission tomography (PET) imaging; limited area (e.g., chest, head/neck)
ICD-10-CM		Investigational for all diagnoses
	C50.011-C50.929	Malignant neoplasm of nipple and breast, code range
	C79.81	Secondary malignant neoplasm of breast
	D05.01-D05.99	Carcinoma in situ of breast; code range
	R92.0-R92.8	Abnormal and inconclusive findings on diagnostic imaging of breast code range
	Z12.31; Z12.39	Encounter for screening for malignant neoplasm of breast codes
	Z85.3	Personal history of malignant neoplasm of breast, female or male
	Z85.43	Personal history of malignant neoplasm of ovary
	Z80.3	Family history of malignant neoplasm of breast
ICD-10-PCS		ICD-10-PCS codes are only used for inpatient services. There is no specific ICD- 10-PCS code for this imaging.
Type of service	Radiology
Place of service	Outpatient

Procedure and diagnosis codes on Medical Policy documents are included only as a general reference tool for each policy. They may not be all-inclusive.

This medical policy was developed through consideration of peer-reviewed medical literature generally recognized by the relevant medical community, U.S. FDA approval status, nationally accepted standards of medical practice and accepted standards of medical practice in this community, Blue Cross Blue Shield Association technology assessment program (TEC) and other non-affiliated technology evaluation centers, reference to federal regulations, other plan medical policies and accredited national guidelines.

History From 2014 Forward

02/09/2023	Annual review, no change to policy intent.
02/01/2022	Annual review, no change to policy intent.
02/01/2021	Annual review, no change to policy intent. Updating rationale.
02/05/2020	Annual review, no change to policy intent. Updating background, description, rationale and references.
02/17/2019	Annual review, no change to policy intent. Updating background, rationale, references and coding.
03/06/2018	Annual review, no change to policy intent. Updating rationale and references.
02/01/2017	Annual review, no change to policy intent. Updating background, description, rationale and references.
02/10/2016	Annual review, no change to policy intent. Updating background, description, regulatory status, rationale and references.
02/24/2015	Annual review, no change to policy intent. Updated regulatory status, rationale and references. Added guidelines and coding.
02/6/2014	Annual Review. Added related policies. Updated background, rationale and references. No change to policy intent.

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Positron Emission Mammography (PEM) - CAM 60152