SNMMI Procedure Standard/EANM Practice Guideline for Molecular Breast Imaging with Dedicated γ-Cameras

A. Problem Solving

MBI has been proven useful in patients with indeterminate breast abnormalities and remaining diagnostic concerns after physical examination and conventional radiologic work-up with mammography and ultrasound. MBI has been studied as a tool for directing management of benign and low suspicion findings. Use of MBI in other problem-solving scenarios is still being studied (6,10–15).

B. Local Staging

In patients recently diagnosed with breast cancer, MBI may be used to evaluate the extent of disease and to determine additional sites in the case of multifocal, multicentric as well as contralateral disease (6,16–22). MBI may be especially useful in the case of discrepancies between clinical and radiologic findings or indeterminate radiologic findings due to challenging conventional imaging (e.g., mammographically dense breast) and when MRI is contraindicated or unavailable.

C. Treatment Response Monitoring

MBI can be used to evaluate disease extent before and after neoadjuvant chemotherapy (23,24). Data have shown MBI to provide evaluation of disease extent similar to that acquired with MRI. Other studies have examined whether the change in tumor size or uptake on MBI could provide prognostic information that predicts tumor response to therapy (25,26). Investigations to standardize ^99mTc-sestamibi response criteria, to optimize timing and frequency of imaging, and to examine variability in response with tumor subtypes are ongoing.

D. Screening and Surveillance

As a screening tool, MBI has been useful in detecting mammographically occult breast cancer in women with dense breast tissue (heterogeneously or extremely dense on mammography (27)) and in women at elevated risk for breast cancer who are unable to undergo breast MRI screening (28–33).

MBI may be used in surveillance for recurrence in women with personal history of breast cancer, especially women whose previous breast cancer was occult on mammography or women who have dense breasts. MBI can help to differentiate between scar tissue and recurrence of disease in patients who underwent surgery, radiotherapy, or biopsy (34).

E. Additional Uses

MBI has shown usefulness as a supplement to mammography in patients with difficult conventional imaging, such as patients with mammographically dense breasts, implants and free silicone. MBI has been used as an alternative to MRI when breast MRI is contraindicated or unavailable (9,34).

A. Pregnancy

MBI should be postponed during pregnancy if possible. Because ^99mTc-sestamibi is known to cross the placental barrier, the fetus may be exposed to radiation if a pregnant patient undergoes MBI (see section XI).

B. Allergic Reaction to ^99mTc-Sestamibi

Allergic reaction to ^99mTc-sestamibi is rare and typically mild (see section VI.C). Nevertheless, if a patient presenting for MBI has a known history of hypersensitivity or allergic reaction to ^99mTc-sestamibi, an alternative test to MBI should be considered. If MBI is still pursued, special precautions such as premedication may be warranted to prevent allergic reaction.

A. Physician

In the United States and Canada, MBI examinations should be performed under the supervision of and interpreted by a physician certified in nuclear medicine or radiology by the applicable accrediting board, such as the American Board of Nuclear Medicine, the American Board of Radiology, the Royal College of Physicians and Surgeons of Canada, Le College des Medecins du Quebec, or the equivalent.

In Europe, MBI examinations should be performed by or under supervision of a physician specialized in nuclear medicine or nuclear radiology and certified by the accrediting boards. The certified nuclear medicine physician who authorizes the study and signs the report is responsible for the procedure according to national laws and rules.

The physician should participate in maintenance of certification in the field of radiology or nuclear medicine.

B. Technologist

MBI examinations should be performed by a nuclear medicine technologist who is registered/certified in nuclear medicine by the Nuclear Medicine Technology Certification Board (NMTCB), American Registry of Radiologic Technologists (ARRT), or the Canadian Association of Medical Radiation Technologists (CAMRT) or the equivalent. The nuclear medicine technologist works under the supervision of the physician as outlined above. Nuclear medicine technologists who perform MBI should receive additional training in mammographic positioning techniques (35). Alternatively, if U.S. state regulations allow, MBI examinations may be performed with radiopharmaceutical administration by a nuclear medicine technologist and image acquisition by a certified mammography technologist.

In Europe, the examination should be executed by qualified registered/certified nuclear medicine technologists (36).

C. Medical Physicist

The medical physicist should oversee instrumentation quality control, protocol development, and image processing of MBI examinations. The medical physicist should be able to practice independently in the subfield of nuclear medicine physics. Qualifications are as stated in the SNMMI Procedure Standard for General Imaging (37).The SNMMI recommends that medical physicists be certified in the appropriate subfield(s) by the American Board of Science in Nuclear Medicine or by the American Board of Radiology, or the equivalent.

The EANM states that a certified medical physics expert (MPE) is responsible for the quality assurance of MBI systems that are in clinical use and also for the identification of possible malfunctions of these systems. The MPE is also responsible for the optimal implementation of procedures considering national and international radiation protection safety standards both for patients and for personnel.

A. Request for MBI

• 1. Other relevant imaging, such as recent mammogram, should be made available for correlation with the MBI.

• 2. The interpreting physician should be aware of physical findings, symptoms, and clinical history.

• 3. The patient’s pregnancy and lactation status, date of last menses, and use of hormonal therapies should be determined.

  • i. If pregnancy is possible, the study should be delayed until the onset of menses or until a negative pregnancy test is obtained.

  • ii. Reporting of the patient’s menopausal status, phase of menstrual cycle, and any exogenous hormone therapy use may aid in the radiologist’s interpretation with regard to background parenchymal uptake (BPU). Premenopausal women may benefit from scheduling imaging during the follicular phase of their menstrual cycle (typically before day 14) to minimize BPU. In patients currently taking hormone therapy, BPU may be elevated.

• 4. Ideally, MBI should be performed before interventional procedures, such as biopsy, because ^99mTc-sestamibi may accumulate at sites of inflammation that may confound interpretation. However, MBI may still be performed after intervention as it can effectively evaluate the remainder of the ipsilateral breast tissue and the contralateral breast.

• 5. Care should be taken in scheduling MBI adjacent to other nuclear medicine studies or therapies that may interfere with imaging (35). In particular, MBI should not be scheduled within 24 h before a breast sentinel lymph node localization with a radiotracer.

B. Patient Preparation and Precautions

• 1. A thorough explanation of the test should be provided by the technologist or physician.

• 2. Patients should be encouraged to drink water before the MBI examination to stay hydrated for intravenous injection.

• 3. Although not required, patient fasting (no calorie intake) for approximately 3 h before MBI may increase uptake of ^99mTc-sestamibi in breast tissue by reducing splanchnic and hepatic blood flow (38). If fasting is used, special considerations may be needed for diabetic patients.

• 4. The patient should change into a gown, removing all clothing from the waist up, to better facilitate imaging.

• 5. Deodorants, lotions, powders, and jewelry (such as necklaces) do not need to be removed for the MBI examination.

• 6. Although not required, warming the patient’s upper torso by wrapping a warm blanket around the patient’s shoulders for at least 5 min before injection may increase peripheral blood flow and further increase uptake of ^99mTc-sestamibi in breast tissue (38).

• 7. Confirmation of no current pregnancy should be obtained from female patients of child-bearing capacity, according to local institutional procedures (see sections IV and XI).

• 8. Confirmation of no previous allergic reaction to ^99mTc-sestamibi should be obtained.

• 9. For patients who are breastfeeding, no interruption is necessary (see section XI) (39).

C. Radiopharmaceutical

• 1. Two single-photon radiopharmaceuticals, ^99mTc-sestamibi and ^99mTc-tetrofosmin, are EMA-approved for breast imaging indications. ^99mTc-sestamibi is also FDA-approved for breast imaging. In current practice, ^99mTc-sestamibi is most commonly used.

• 2. ^99mTc-sestamibi should be administered using an indwelling venous catheter or butterfly needle followed by 10 mL of saline to flush the vein.

• 3. When possible, the tracer should be administered via an upper-extremity vein on the opposite side of the suspected abnormality.

• 4. Administered activity

  • i. MBI has previously been performed with general purpose γ-cameras and administered activities of 740 to 1,100 MBq of ^99mTc-sestamibi per the FDA approval or 700 to 1,100 MBq per the EMA approval. However, the improved count sensitivity of modern MBI systems now facilitate lower administered activity, with many practices now administering 300 MBq or less.

  • ii. MBI performed with modern dedicated MBI systems, using approximately 300 MBq (8 mCi) of ^99mTc-sestamibi, will typically attain adequate count density with an acquisition time 7–10 min per view. Administered activity and acquisition time may vary depending on equipment used and practice preference.

  • iii. For MBI-guided biopsy procedures, a higher administered activity of 600–800 MBq (16–22 mCi) may be considered to ensure optimal visibility of the target and allow shorter acquisition time (40).

• 5. ^99mTc-sestamibi has been found to adhere to certain types of plastic syringe walls (41). Care in selection of a syringe with low ^99mTc-sestamibi adsorption is advised to minimize residual activity. If warranted, residual activity should be measured after injection to obtain an accurate assessment of the net administered activity.

• 6. Adverse events from ^99mTc-sestamibi are rare (1–6 events per 100,000; < 0.006%) and can include allergic reaction but are typically mild in severity (e.g., flushing, rash, injection site inflammation, or brief metallic taste) (42,43).

• 7. ^99mTc-sestamibi clears from the bloodstream within 2–3 min and is taken up largely by first-pass extraction, with minimal redistribution. ^99mTc-sestamibi uptake in breast tissue has minimal physical decay and minimal washout over a typical examination time (<1 h). Thus, MBI acquisition may begin approximately 5 min after injection, and minor delays between injection and imaging are not problematic (35).

D. Protocol/Image Acquisition

• 1. A detailed guide for MBI technologists has been previously published (35).

• 2. Technologists should verify with the patient the indication for the examination and ask the patient if she has any areas of breast concern. If applicable, the affected side should be imaged first in case the patient cannot tolerate the entire examination. The technologist should confirm that the area of concern will be included in the imaging field of view.

• 3. Breast positioning

•    i. The patient should be seated during the scan time. A specialized chair, such as those designed for seated mammography, is recommended.

•  ii.  Support the patient’s back with pillows as needed to make the scanning time as comfortable as possible.

• iii. The patient’s breast should be placed in direct contact with the γ-camera detector and light compression applied to immobilize the breast during image acquisition.

• 4. Imaging

•    i. Imaging may begin within 5 min of injection (see section VI.C.7).

•  ii.  Planar imaging should be acquired in 2 standard views: cranio-caudal (CC) and mediolateral oblique (MLO), analogous to mammographic views. For single-head systems, CC view is acquired with the detector under the breast, and the MLO view is acquired with the detector at approximately 45° oblique on the lateral side of the breast. If needed, additional views may be acquired.

• iii. Typical image acquisition time is between 7 and 10 min per view. The necessary acquisition time to achieve acceptable image quality will depend on administered activity and specifics of the MBI system, including γ-camera sensitivity and detector pixel size. For MBI detectors with 1.6 or 2.5 mm detector elements, it is suggested to select an acquisition time that will achieve at least 30 counts per pixel or 50 counts per pixel, respectively, in areas of normal breast tissue.

• iv. Images should be labeled with laterality (“left” or “right”). Radioactive ⁵⁷Co markers may be used.

• 5. Processing

For the correct interpretation of the images a computer workstation should be available that enables simultaneous display of the MBI and recent mammogram. Adjustment of the image contrast by the interpreting physician may be necessary.

Display parameters, including gray scale linear display and color logarithmic display, can be used in order to optimize interpretation.

E. Interpretation

• 1. The following relevant information should be considered in the interpretation.

  • i. The indication for MBI, clinical problems, history of breast interventions, risk factors, and menopausal state should be listed.

  • ii. Any limitations (e.g., suboptimal positioning or artifacts) that are determined to affect image interpretation must be reported.

  • iii. Correlation should be made with other available relevant imaging, such as mammography, and clinical findings.

• 2. A validated molecular breast imaging lexicon for interpretation has previously been published (8,44). This lexicon should be used when describing and interpreting imaging findings. The predictive value of MBI lexicon features is being examined (45–47).

  • i. Background parenchymal uptake (BPU) is defined as the degree of radiotracer uptake within the breast parenchyma in comparison to subcutaneous fat. BPU is assessed visually as photopenic, minimal/mild, moderate, or marked.

  • ii. If a lesion is identified, the intensity of uptake within the lesion (photopenic, mild, moderate, or marked), mass or nonmass uptake, and the distribution are described.

  • iii. The location and size of any finding are described by the quadrant or clock face position as well as depth or distance from the nipple.

  • iv. Lesion size is measured on the image where the finding is best visualized. By definition, x is the longest lesion measurement, y is orthogonal to x on the same image, and z is orthogonal to x and y on the image not used to measure x and y.

  • v. Associated findings such as nipple, axillary, or vascular uptake should be described.

• 3. The final assessment and management recommendations should be provided on every MBI examination.

  • i. Assessment categories parallel those of the Breast Imaging Reporting and Database System (BI-RADS) (27) and are described as category 0 (incomplete, needs additional imaging); category 1 (negative, routine follow-up); category 2 (benign, routine follow-up); category 3 (very low likelihood of malignancy); category 4 (suspicious, consider biopsy); category 5 (highly suggestive of malignancy, take appropriate action); and category 6 (known malignancy, take appropriate action).

  • ii. The assessment is based on the level of suspicion by the interpreting radiologist based on lesion distribution, intensity, and morphology.

  • iii. When a final assessment of 1 or 2 is given, no further imaging is necessary.

  • iv. Category 0 should be avoided, similar to breast MRI interpretation, and an assessment corresponding to the level of suspicion provided when possible.

    • a. All category 0, 3, 4, or 5 lesions undergo diagnostic mammography or ultrasound.

    • b. If a correlate is identified on mammography or ultrasound, biopsy can be performed with guidance from one of those modalities.

    • c. If no correlate is identified on conventional imaging for a category 3 finding, short-interval follow-up MBI, typically in 6 mo, is recommended. If the lesion decreases in size or intensity on follow-up, it is considered benign. If it increases in size or intensity, MRI- or MBI-guided biopsy is performed. If it remains the same, continued follow-up at 12 and 24 mo after the initial MBI is recommended.

    • d. For category 4 or 5 lesions, MBI-guided biopsy or MRI are recommended when conventional imaging does not show a correlate.

F. Interventions

MBI devices with stereotactic biopsy guidance capability are available. Common indications for MBI-guided biopsy include:

• 1. Suspicious MBI abnormalities that are occult on mammography and (targeted) ultrasound.

• 2. Mammographic abnormalities, occult on ultrasound but ^99mTc-sestamibi–avid, when stereotactic mammographically guided biopsy is technically challenging.

• 3. Cases of lesions recommended for MRI-guided biopsy that cannot be performed (e.g., MRI-guided biopsy is not available, is technically challenging, or attempted and unsuccessful).

Various previously published papers provide a detailed description of the MBI-guided biopsy methodology (40, 48–50).

G. Limitations and Pitfalls

• 1. Motion of the breast relative to the detector may result in image blurring, making small lesions more difficult to detect.

• 2. Small lesions, especially less than 5 mm, are difficult to detect with current MBI technology.

• 3. Posterior lesions close to the chest wall may be difficult to include in the MBI field of view. The axilla cannot be reliably imaged with planar MBI acquisitions due to positioning limitations.

• 4. Due to the smaller field of view of MBI cameras relative to mammography, additional views may be needed for patients with larger breasts.

• 5. False-positive uptake of ^99mTc-sestamibi is associated with the following etiologies:

  • i. Benign lesions (e.g., fibroadenomas, papillomas, fat necrosis, pseudoangiomatous stromal hyperplasia).

  • ii. Atypical lesions (e.g., atypical ductal hyperplasia, atypical lobular hyperplasia) and lobular carcinoma in situ.

  • iii. Normal axillary or intramammary lymph nodes.

  • iv. Inflammation after biopsy, surgery, or external beam radiation therapy.

  • v. Background parenchymal uptake that may fluctuate with menstrual cycle or exogenous hormone use.

• 6. Extravasation of the tracer injection may result in areas of abnormal uptake in ipsilateral lymph nodes (51).

A. Patient Exposure Considerations

See Section X of the SNMMI Procedure Standard for General Imaging (37).

^99mTc-sestamibi emits γ-rays with a principal photon energy of 140 keV and has a physical half-life of 6.01 h.

Dose estimates to adult patients and the fetus of pregnant patients are presented in Tables 1 and 2. For a typical administration of 296 MBq (8 mCi) of ^99mTc-sestamibi for MBI, the estimated dose to the breast is 1.1 mGy, the organ receiving the largest estimated dose is the gallbladder (11.5 mGy), and the effective dose is estimated as 2.1–2.7 mSv.

Regarding dose estimates to breastfeeding patients, ICRP Publication 106 (Annex D) suggests that no interruption is needed for breastfeeding patients administered ^99mTc-sestamibi or ^99mTc-tetrofosmin (39). However, because of possible free ^99mTc-pertechnetate it is advisable to interrupt the feeding for 4 h.

B. Personnel Exposure Considerations

The technologist total-body radiation exposure depends on the administered activity, the imaging time per patient, and the patient workload. Assuming an administered activity of 296 MBq (8 mCi) of ^99mTc-sestamibi per patient and an approximately 1-h total patient contact time, the total-body radiation dose for an MBI technologist who injects the radiopharmaceutical, performs breast positioning, and remains in the room with the patient during imaging is estimated to be <0.2 mrem per patient (58). For example, a modest technologist clinical workload of 1 MBI patient examination per day corresponds to an annual effective dose of approximately 48 mrem (0.48 mSv).

Exposure to radiologists and support staff performing MBI-guided biopsy has been reported as 0.03 mGy/h at a distance of 15 cm from the patient (40). Thus, estimated radiation exposure to a radiologist in close contact with the biopsy patient for 20 min is conservatively estimated at 0.01 mGy, which corresponds to an effective dose of 0.01 mSv.

C. MBI Room Shielding Requirements

The standard shielding as used in a mammography examination room is typically sufficient for MBI.