Next Article in Journal
Clinical Significance of Tumor Size in Gross Extrathyroidal Extension to Strap Muscles (T3b) in Papillary Thyroid Carcinoma: Comparison with T2
Next Article in Special Issue
Diagnostic and Practical Value of Abbreviated Contrast Enhanced Magnetic Resonance Imaging in Breast Cancer Diagnostics
Previous Article in Journal
Circulating Neoplastic-Immune Hybrid Cells Predict Metastatic Progression in Uveal Melanoma
Previous Article in Special Issue
Radiomic Signatures Derived from Hybrid Contrast-Enhanced Ultrasound Images (CEUS) for the Assessment of Histological Characteristics of Breast Cancer: A Pilot Study
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Cancers
Volume 14
Issue 19
10.3390/cancers14194619
cancers-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Systematic Review

Breast-Specific Gamma Imaging: An Added Value in the Diagnosis of Breast Cancer, a Systematic Review

by
Maria Silvia De Feo
1,
Marko Magdi Abdou Sidrak
1,
Miriam Conte
1,
Viviana Frantellizzi
1,*,
Andrea Marongiu
2,
Flaminia De Cristofaro
1,
Susanna Nuvoli
2,
Angela Spanu
2 and
Giuseppe De Vincentis
1
1
Department of Radiological Sciences, Oncology and Anatomo-Pathology, Sapienza University of Rome, 00161 Rome, Italy
2
Unit of Nuclear Medicine, Department of Medical, Surgical and Experimental Sciences, University of Sassari, 07100 Sassari, Italy
*
Author to whom correspondence should be addressed.
Cancers 2022, 14(19), 4619; https://doi.org/10.3390/cancers14194619
Submission received: 4 August 2022 / Revised: 19 September 2022 / Accepted: 20 September 2022 / Published: 23 September 2022
(This article belongs to the Special Issue Breast Cancer Imaging: Current Trends and Future Direction)
Browse Figure
Review Reports Versions Notes

Abstract

:

Simple Summary

Breast-specific gamma imaging represents an emergent instrument for breast cancer detection. We selected on Medline articles published from 1995 to 2022 that compare various imaging modalities with breast-specific gamma imaging. The aim of this paper was to assess if this imaging method is a more valuable choice in detecting breast malignant lesions compared to morphological counterparts such mammography, ultrasound, and magnetic resonance imaging in terms of specificity, sensibility and positive and negative predictive value. At the cost of a major radiology burden, breast-specific gamma imaging is more specific, with a sensibility comparable to magnetic resonance imaging and higher than ultrasonography and mammography.

Abstract

Purpose: Breast cancer is the most common solid tumor and the second highest cause of death in the United States. Detection and diagnosis of breast tumors includes various imaging modalities, such as mammography (MMG), ultrasound (US), and contrast-enhancement MRI. Breast-specific gamma imaging (BSGI) is an emerging tool, whereas morphological imaging has the disadvantage of a higher absorbed dose. Our aim was to assess if this imaging method is a more valuable choice in detecting breast malignant lesions compared to morphological counterparts. Methods: research on Medline from 1995 to June 2022 was conducted. Studies that compared at least one anatomical imaging modality with BSGI were screened and assessed through QUADAS2 for risk of bias and applicability concerns assessment. Sensitivity, specificity, positive and negative predictive value (PPV and NPV) were reported. Results: A total of 15 studies compared BSGI with MMG, US, and MRI. BSGI sensitivity was similar to MRI, but specificity was higher. Specificity was always higher than MMG and US. BSGI had higher PPV and NPV. When used for the evaluation of a suspected breast lesion, the overall sensitivity was better than the examined overall sensitivity when BSGI was excluded. Risk of bias and applicability concerns domain showed mainly low risk of bias. Conclusion: BSGI is a valuable imaging modality with similar sensitivity to MRI but higher specificity, although at the cost of higher radiation burden.

1. Introduction

Breast cancer is the leading cause of malignancy in women, followed by lung cancer, and the second most common cause of cancer death in the US. In recent years, a slow and steady rise in the detection of breast cancer has been seen, although mortality has been reduced thanks to an earlier diagnosis and treatment, but also sensibilization campaigns and better patient management [1,2]. Mammography (MMG) is the most used screening method used to explore anatomic changes. Its sensitivity is influenced by breast density and ranges from 75 to 85% in women with low-fat tissue to 42 to 68% in women with high-fat tissue [3,4,5]. Other limitations are represented by previous surgery or radiation therapy as well as architectural distortion, which might lead to unnecessary biopsies [6,7]. In order to overcome these pitfalls, other imaging techniques are used, such as ultrasound (US) and magnetic resonance imaging (MRI). Hand-held ultrasound (HHUS) has its flaws such as operator-dependency, small field of view (FOV), and the lack of standardization. Nevertheless, it has a small increase in sensitivity when coupled to mammography at the cost of a reduction in specificity. Automated Breast Ultrasound (ABUS) was developed to reduce operator dependency, although no specificity was observed [8]. MRI, although radiation-free, is still burdened with renal toxicity due to contrast enhancement [8]. More recently, Magnetic Resonance Spectroscopy Imaging (MRSI) has been shown to be very sensitive, although it does not have brilliant specificity [9]. The improvement of imaging devices results in a better sensitivity, specificity, and positive predictive value (PPV) [10,11]. These results have been recently reached in nuclear medicine imaging thanks to Breast-specific Gamma Imaging (BSGI). This is a radio-imaging technique used to precisely detect breast cancer lesions, by applying dedicated detectors, in tissues of variable density [12]. The main radiopharmaceutical (RP) used for BSGI is Technetium 99metastable (99mTc) methoxyisobutyl isonitrile (Sestamibi-MIBI) [13]. It is a cationic and lipophilic molecule with a great affinity for high metabolism and therefore for mitochondria-rich cells. Its distribution is dependent on blood flow, and it is influenced by mitochondrial membrane potential. These characteristics make MIBI a good tracer for tumor lesions imaging and tissues with high blood flow and high metabolism. A lack of uptake may be seen in high concentrations on efflux proteins such as P-glycoprotein and multidrug resistance-related protein 1 [14]. The recommended activity of 99mTc-sestamibi is 370–740 MBq. More recent studies showed how a 2.5-fold dose reduction in activity was possible without a significant impact on sensitivity and specificity, using both NaI and CZT detectors. For 296 MBq i of administered activity, the effective whole-body dose is 2.5 mSv and 0.019 mGy/MBq for the breast, while for two-projection mammography the effective dose delivered to the breast is 0.5 mSv. It is worth noting how the estimations of radiation-related cancer with a dose below 100 mSv are almost zero [15,16]. With an injected activity of 740–1100 MBq, critical organs are represented by the large intestine and by secretory organs such kidneys, bladder and gallbladder wall. The breast has the lowest dose equal to 2 mGy. The effective dose is estimated to be 5.9–9.4 mSv. Considering the properties of Sestamibi that adheres to the plastic syringe, a 20% to 30% of activity is maintained in the syringe after injection, thus an administered activity is inferior. For example, the effective administered activity of a 296 MBq contained in the syringe is about 240 MBq [17]. A BSGI conducted with activities below 300 MBq demonstrated a superior cancer detection rate than mammography alone, but it does not match the benefit-to-radiation risk ratio of screening mammography [18]. 99mTc-tetrofosmin is another radiotracer that is used for BSGI and, like MIBI, finds its main application in myocardial imaging. Its uptake mechanism is very similar to that of MIBI. It is a metabolism-dependent process that does not imply cation channel transport but most likely diffusion of the cation through mitochondrial membranes. Sensitivity and specificity for BSGI with tetrofosmin overlap the sensibility and specificity of BSGI conducted with MIBI. The only advantage of tetrofosmin could be found in its preparation since it does not require boiling before usage (as MIBI) [19,20]. Newer RPs are still under development and are pending for FDA approval. Maraciclatide (99mTc-NC100692) is a synthetic cyclic peptide with strong affinity for tissue characterized by high angiogenesis and pregulated integrins such as αvβ3. Thus, its target is the integrin’s receptors expressed on endothelial cells. In 2017, O’Connor et al. published data regarding BSGI using MIBI and BSGI with Maraciclatide on 39 women with known or suspected breast lesions, although no significant difference was found between the two RPs in detecting malignant breast lesions (AUC 0.83 and 0.87 for MIBI and Maraciclatide, respectively). They showed comparable uptake in breast tumors [21]. In another paper, recently published specific peptides with high cell binding properties were reported. Ahmadpour et al. studied MCF-7 cell line, which is an epithelial luminal cell line expressing progesterone and estrogen receptors. This cell line is isolated from bone-metastatic women with pleural effusion. They demonstrated that 99mTc-HYNIC-(tricine/EDDA)-FROP showed relevant uptake in the MCF-7 cell lines, compared to other normal and cancerous cell lines, figuring as a promising probe for these malignancies [22,23]. The aim of this systematic review was to assess if BSGI is a more valuable choice in detecting breast malignant lesions compared to morphological counterparts.

2. Materials and Methods

The research was conducted on Pubmed starting from January 1995 to June 2022 and drawn up according to PRISMA guidelines. The protocol has not been registered. The following keywords were applied: “BSGI” or “breast specific gamma imaging” and “ultrasound” or “MRI” or “magnetic resonance imaging” or “MMG” or “mammography”. Studies that made a comparison between at least two imaging modalities were tabled and sensibility, specificity, PPV and negative predictive value (NPV) were reported. Papers on BSGI only or with comparison between groups of imaging modalities were also considered for this paper. English language was mandatory. Quality Assessment of Diagnostic accuracy Studies-2 (QUADAS-2) was the mean for assessing the diagnostic validity of eligible studies.

3. Results

Through these keywords, 1196 articles were screened. After excluding duplicates, case reports, reviews, trials, non-English articles, and non-related papers, a total of 15 comparison studies between BSGI were collected (see Figure 1). Among all imaging modalities, MRI displayed the highest sensitivity, ranging from 83.3% to 100%. Specificity was low from 25% to 69.7%. Mammography’s sensitivity ranged from 53.6% to 93.64%, while specificity was from 28% to 90.66%. Ultrasound had high sensitivity, from 82.1% to 99%, but lower specificity, from 19.8% to 87.09%. BSGI had high sensitivity, along with MRI, from 68.6% up to 95.45%. BSGI has a specificity between 56% and 90.93%. PPV and NPV, when reported, were almost always higher for BSGI than for the compared exam. The inclusion of BSGI as a breast lesion diagnostic tool increased overall sensitivity. The differences in sensitivity, specificity, PPV, NPV between BSGI and MRI in the included studies is summarized in Table 1, while the differences between BSGI and mammography in Table 2. In Table 3, BSGI and ultrasound are compared. Methodological quality assessment was satisfactory. Out of 105 domains, only 4 were high risk, and 2 other domains were unclear. Most of the evaluated domains were at a low risk of bias. High risk domains were a concern in one study, as the authors selected a group of patients whose anatomical abnormalities were most likely not due to cancer. Overall, low risk assessment is probably due to a conventionally standardized procedure in breast cancer management, going through imaging, biopsy and surgery and with no concerns for applicability whatsoever (See Table 4).

4. Discussion

Liu et al. evaluated 390 women with suspected breast lesions with BSGI, 235 of whom underwent MRI as well. MRI had the highest sensitivity but lowest specificity among all examinations and higher costs and longer imaging time compared to mammography and ultrasound. BSGI had higher positive and negative predictive value (PPV and NPV), as well as the highest specificity and the second-highest sensitivity. BSGI was found to be highly sensitive in detecting and diagnosing ductal carcinomas in situ (DCIS) [12]. In 2021 the same group studied Sestamibi BSGI in women undergoing neoadjuvant chemotherapy (NAC) to evaluate tumor staging and NAC response, since MRI yields high false-positive rates and it may well overestimate tumor size, leading to unwanted surgery. A slightly lower sensitivity for BSGI was confirmed with respect to a greater specificity compared to MRI [24]. In 2012, Lee et al. compared BSGI to mammography and ultrasound, subdividing the study group of 471 women into under and over 50 years of age (249 and 222, respectively). Sensitivity and specificity were overall higher in the over 50 group for all the imaging modalities, probably due to the higher breast density in the under 50 group, leading to more false negative results in the latter group [33]. In 2020, Liu et al. compared BSGI with MMG and US in women with Breast Imaging Reporting and Data System 4 (BI-RADS 4) lesions in 177 women retrospectively. Lesion sizes ranged from 3 to 74 mm. BSGI sensitivity for lesion <1 cm was comparable to US, with higher specificity compared to MMG and US (88% vs. 40% and 64%, respectively). In lesions with dimensions greater than 1 cm, specificity dropped to 71.4%, still higher than US 45.7%. Among luminal lesions, HER2+ and triple negative, sensitivity overlapped between the three modalities [34]. Keto et al. compared BSGI and MRI in patients with ductal carcinoma-in situ (DCIS), as it is usually detected through breast calcification seen on MMG, although reported sensitivity in the literature fluctuates. A total of 18 women with recently discovered DCIS who underwent MRI and BSGI were grouped, and MRI identified 17 lesions while BSGI identified 16 women positive for malignant lesions (94% vs. 89%). No significant difference was found. The non-identified lesion on both imaging modalities had dimensions of 0.2 cm [25]. DCIS turned out to be the most detected malignancy through BSGI. In 2007, Brem et al. reported data on the sensitivity for BSGI in comparison to MMG and MRI for DCIS. It was equal to 92%, 82% and 88%, respectively. Another paper on multiple malignancies reported lower specificity compared to other imaging modalities (59.5%). The highest sensitivity was reported for lesions greater than 11 mm (100%) [26,32]. In 2016, Brem et al. showed an increase in diagnostic accuracy when BSGI was added to the annual screening MMG in inconclusive exams conducted in women with dense breasts. This proved to be a limitation of MMG, demonstrating how improved overall sensitivity by 1.7% was reached when BSGI was included in the screening program [37]. Other authors’ results followed the overall pattern comparing BSGI to MMG and US, with higher overall sensitivity and specificity found for BSGI in BI-RADS 4. These results were repeatable when women with dense breasts were considered, especially specificity-wise (81.3% vs. 19% and 50% for BSGI, US and MMG, respectively). BSGI showed excellent results in dense breasts and lesions with dimensions less than 1 cm with only suspicious microcalcifications [35]. Semi-quantitative BSGI analysis was also applied to compare BSGI to MMG, MRI and US in BI-RADS 4 and 5 lesions, by dividing the number of counts in the BSGI lesion by the ipsilateral background parenchyma. Mean value (counts in BSGI lesion) was 4.27 and 2.37 for benign ones, with a cut-off of 3.04. Relative lesion size was not significantly different (18.42 cm vs. 17.88 cm for malignant and benign lesions, respectively) [27]. Yu et al. in 2016 examined 166 women who had undergone four imaging modalities. MRI had the highest sensitivity and BSGI the highest specificity, in line with other researchers. BSGI had the highest sensitivity, followed by MRI. Tumor to normal tissue ratio cut-off value was found at 1.82 [28]. Previously, Kim et al. also demonstrated the same sensitivity and specificity-wise for MRI and BSGI in women with dense breasts (>50%) [30]. Later, they evaluated MRI and BSGI performance in women after NAC. NAC response was determined by final surgical pathology, with a slight edge for BSGI (kappa values 0.47 vs. 0.41) [31]. Another study evaluated calcified and non-calcified DCIS with MRI and BSGI. Far greater sensitivity for MRI than BSGI in both sub-groups with an overall MRI sensitivity of 91.4% vs. 68.6 for BSGI was highlighted [29]. In 2012, Park et al. studied the clinical utility of BSGI in single and dual-phase imaging, acquired immediately after injection of MIBI and one hour later. Imaging was carried out on patients with BI-RADS from 1 to 5 categorized in US. Sensitivity decreased after dual imaging (77% to 69%), although not significantly, while specificity and PPV increased. As MIBI uptake in benign conditions decreases over time, resulting in asymmetrical mild and nodular uptake on early imaging, late imaging is supposed to confirm or exclude malignancy [38]. The same group in 2014 published a paper dividing breast cancer into BSGI+ and BSGI− lesions. Overall sensitivity was 85.7%, 90.7% for lesions greater than 1 cm, and 55.6% for sub-centimetric lesions, with the smallest lesion of 0.4 cm identified on BSGI only. No correlation was found between BSGI positivity and extensive intraductal component, Estrogen Receptor (ER), Progesterone Receptor (PR), ERBB2, Ki67, p53 and nuclear grade [39]. Again, in 2018, the aforementioned trend was confirmed on 89 invasive breast cancers imaged by BSGI in a study conducted by the same group. Reported sensitivity aligned with the one stated in the 2014 study, as well as for lesions over and below 1 cm. However, the sensitivity was lower than in other studies, probably due to the inclusion of only invasive breast cancers [40]. BSGI in Mucinous Breast Carcinoma (MCB) and Pure Mucinous Breast Carcinoma (PMBC) has been less studied compared to DCIS. It is harder to detect as the mucinous component takes over and less blood volume/mitochondrial density is to be found since a lesser uptake was seen. It might be responsible for misinterpretation since it could be mistaken for a benign lesion [41]. In the 2020, another Chinese group evaluated sensitivity and specificity for women tested with BSGI and MMG group and for MMG and US group. The population was characterized by 364 women with suspicious lesions and was heterogeneous. Only young women who are more likely to have denser breasts were selected. The MMG and US group had sensitivity equal to 90.4%. The BSGI and MMG group’s sensitivity was 93.6%. The highest difference between the two groups was the different representation of HER-2+ type (86.21 for MMG + US group, 96.55 for BSGI + MMG group) and the number of tumor lesions was smaller than 1 cm (73.33 for MMG + US group, 80 for BSGI + MMG group). AUC was 0.9 in the MMG + BSGI group and 0.93 in the MMG + US group [42]. In another study, Chung et al. evaluated the combination of BSGI and MMG compared with the group who had undergone MMG and US. The latter combination had higher sensitivity, although not significant, while the first had higher specificity, which was significant. PPV, NPV, and AUC were higher when BSGI was included. AUC did not change when patients were injected with 370 or 740 MBq of 99mTc-MIBI [43]. Sensitivity according to breast density is still controversial, as some data showed that sensitivity decreases when breast density increases, while others found no significant difference [44]. No consensus was reached in stating if BSGI is able to identify or predict ER, PR, HER-2, and Ki-67 expression. The value of lesion/normal tissue uptake has been demonstrated not to be related to receptor expression or histologic grade. It seemed influenced by infiltration degree and tumor size [36]. Another limitation for BSGI could be an increased background activity in women with dense breasts displayed in MMG and increased background enhancement on MRI, as it may interfere with lesion detection. BSGI could also be affected by the menstrual cycle, as women should be imaged between the 7th and the 14th day of the cycle [45]. However, the use of MRI does not seem to decline even though it underperformed compared to BSGI. Estimated in the United States, if every newly breast cancer diagnosed woman had to undergo MRI instead of BSGI, the costs would be more than 500M USD greater [46]. Nevertheless, the benefit-to-radiation risk ratio in annual screening for the combination of BSGI and MMG is similar than BSGI alone. BSGI risk from ionizing radiation is eight times that of MMG in women between 40 and 49, and about thirty times that of MMG in women between 70 and 79 [18].
Moreover, mean costs for mammography has been estimated around USD349 ($493), US around USD132 ($134) and biopsies USD1938 ($2343) in the USA between 1 January 2012 and 30 June 2014. The annual diagnostic breast cost of each procedure was USD3.05 billion, USD0.92 billion, and USD3.07 billion, respectively. Breast biopsy is burdened by a false positive rate in the USA, estimated at 71.0% with an annual false positive cost of USD 2.18 billion. In addition, 49.4% of patients underwent a second diagnostic procedure, 20.1% a third diagnostic procedure, and 10.0% fourth diagnostic procedure, with an increase in annual costs [47]. An analysis of the utilization patterns and associated costs of breast imaging and diagnostic procedures after screening mammography found that the total cost for BSGI amounts to USD 63,750, while the charge for false positive for BSGI is USD 8500 without biopsy. The cost of MRI is USD 253,575, while the cost of false positive excluding biopsy procedures amounts to USD 30,429 [46]. As can be seen, the gap between the two procedures is $189,825 in favor of BSGI, while the gap between the false positive cost is $29,929 in favor of BSGI. A more specific and sensible procedure could lower health care expenditures. In fact, it is evident that the higher sensibility and specificity of BSGI lowers the total costs for the national care system.
As BSGI finds its place in traditional nuclear medicine, PEM (Positron emission mammography) or MAMMI-PET (MAMmography and Molecular Imaging—Positron Emission Tomography) is its counterpart in PET imaging. While PET focuses on whole body imaging, PEM centers on breast imaging, coming at a lower cost and a higher spatial resolution. PEM uses two positron detectors mounted on a mammography gantry that are placed on both sides of the breast. [48]. FDG-PET is reported to have low sensitivity in screening breast cancer, lower than mammography and physical examinations together, [49]. A study that compared PET, PEM and MRI showed higher sensitivity (92.8%) for PEM for index lesions and slightly lower (85%) for additional lesions. MRI showed no significant difference in sensitivity for index lesions (95%) and higher (98%) for additional lesions. Specificity was higher for PEM (74% vs. 48%). Whole-body PET had the worst sensitivity (67.9%). [50]. Other studies continue to show high PEM sensitivity 90–96% and specificity 84–91%, still higher than MRI [51,52,53]. When tumor size comes ino play, evaluation between PEM and PET/TC found no difference in assessing lesions greater than 2 cm in diameter, while PEM had better resolution for <2 cm lesions, [54]. Although, to the best of our knowledge, no study has compared BSGI directly to PEM, the overall sensitivity and specificity of the two methods are comparable, although confirmation is needed.

5. Conclusions

BSGI is a useful imaging modality that, as a functional imaging modality, reaches where anatomical imaging does not. With sensitivity comparable to MRI but higher than MMG and US, it can aid physicians and surgeons in obtaining the best therapeutic approach for the patient as it may distinguish benign and malignant lesions with higher specificity. Although it involves a higher radiation burden for patients, many studies have been conducted with BSGI approaches in which the injected dose was lowered. Incorporating BSGI for breast lesion diagnosis increases overall sensitivity in the detection of cancer lesions.

Author Contributions

Author Contributions: Conceptualization, V.F., A.S. and G.D.V.; methodology, M.S.D.F. and A.M.; investigation, M.M.A.S.; data curation, M.C. and S.N.; writing—original draft preparation, M.M.A.S.; writing—review and editing, V.F., M.C., A.M.; visualization, S.N., F.D.C. and G.D.V.; supervision, V.F., G.D.V. and A.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Schillaci, O.; Danieli, R.; Romano, P.; Santoni, R.; Simonetti, G. Scintimammography for the detection of breast cancer. Expert Rev. Med. Devices 2005, 2, 191–196. [Google Scholar] [CrossRef] [PubMed]
  2. Follacchio, G.A.; Monteleone, F.; Anibaldi, P.; De Vincentis, G.; Iacobelli, S.; Merola, R.; D’Orazi, V.; Monti, M.; Pasta, V. A modified sentinel node and occult lesion localization (SNOLL) technique in non-palpable breast cancer: A pilot study. J. Exp. Clin. Cancer Res. 2015, 34, 113. [Google Scholar] [CrossRef] [PubMed]
  3. Kolb, T.M.; Lichy, J.; Newhouse, J.H. Comparison of the performance of screening mammography, physical examination, and breast US and evaluation of factors that influence them: An analysis of 27,825 patient evaluations. Radiology 2002, 225, 165–175. [Google Scholar] [CrossRef]
  4. Sardanelli, F.; Podo, F.; D’Agnolo, G.; Verdecchia, A.; Santaquilani, M.; Musumeci, R.; Trecate, G.; Manoukian, S.; Morassut, S.; de Giacomi, C.; et al. Multicenter comparative multimodality surveillance of women at genetic-familial high risk for breast cancer (HIBCRIT study): Interim results. Radiology 2007, 242, 698–715. [Google Scholar] [CrossRef]
  5. Lehman, C.D. Role of MRI in screening women at high risk for breast cancer. J. Magn. Reson. Imaging 2006, 24, 964–970. [Google Scholar] [CrossRef] [PubMed]
  6. Kopans, D.B. The positive predictive value of mammography. AJR Am. J. Roentgenol. 1992, 158, 521–526. [Google Scholar] [CrossRef] [PubMed]
  7. Birdwell, R.L.; Ikeda, D.M.; O’Shaughnessy, K.F.; Sickles, E.A. Mammographic characteristics of 115 missed cancers later detected with screening mammography and the potential utility of computer-aided detection. Radiology 2001, 219, 192–202. [Google Scholar] [CrossRef] [PubMed]
  8. Łuczyńska, E.; Pawlak, M.; Popiela, T.; Rudnicki, W. The Role of ABUS in The Diagnosis of Breast Cancer. J. Ultrason. 2022, 22, 76–85. [Google Scholar] [CrossRef] [PubMed]
  9. Leithner, D.; Wengert, G.J.; Helbich, T.H.; Thakur, S.; Ochoa-Albiztegui, R.E.; Morris, E.A.; Pinker, K. Clinical role of breast MRI now and going forward. Clin. Radiol. 2018, 73, 700–714. [Google Scholar] [CrossRef]
  10. Polito, C.; Pellegrini, R.; Cinti, M.N.; De Vincentis, G.; Lo Meo, S.; Fabbri, A.; Bennati, P.; Cencelli, V.O.; Pani, R. Dual-modality imaging with a ultrasound-gamma device for oncology. Radiat. Phys. Chem. 2018, 147, 77–84. [Google Scholar] [CrossRef]
  11. Follacchio, G.A.; Monteleone, F.; Meggiorini, M.L.; Nusiner, M.P.; De Felice, C.; De Vincentis, G.; Liberatore, M. Radio-localization of Non-Palpable Breast Lesions Under Ultrasonographic Guidance: Current Status and Future Perspectives. Curr. Radiopharm. 2017, 10, 178–183. [Google Scholar] [CrossRef] [PubMed]
  12. Liu, H.; Zhan, H.; Sun, D.; Zhang, Y. Comparison of BSGI, MRI, mammography, and ultrasound for the diagnosis of breast lesions and their correlations with specific molecular subtypes in Chinese women. BMC Med. Imaging 2020, 20, 98. [Google Scholar] [CrossRef] [PubMed]
  13. DeCesare, A.; De Vincentis, G.; Gervasi, S.; Crescentini, G.; Fiori, E.; Bonomi, M.; Crocetti, A.; Sterpetti, A.V. Single-photon-emission computed tomography (SPECT) with technetium-99m sestamibi in the diagnosis of small breast cancer and axillary lymph node involvement. World J. Surg. 2011, 35, 2668–2672. [Google Scholar] [CrossRef] [PubMed]
  14. Rizk, T.H.; Nagalli, S. Technetium (99mTc) Sestamibi. In StatPearls [Internet]; StatPearls Publishing LLC.: Treasure Island, FL, USA, 2022. [Google Scholar]
  15. Huppe, A.I.; Mehta, A.K.; Brem, R.F. Molecular Breast Imaging: A Comprehensive Review. Semin. Ultrasound CT MR 2018, 39, 60–69. [Google Scholar] [CrossRef] [PubMed]
  16. Dibble, E.H.; Hunt, K.N.; Ehman, E.C.; O’Connor, M.K. Molecular Breast Imaging in Clinical Practice. AJR Am. J. Roentgenol. 2020, 215, 277–284. [Google Scholar] [CrossRef]
  17. Gunasekera, R.D.; Notghi, A.; Mostafa, A.B.; Harding, L.K. Adsorption of radiopharmaceuticals to syringes leads to lower administered activity than intended. Nucl. Med. Commun. 2001, 22, 493–497. [Google Scholar] [CrossRef]
  18. Hendrick, R.E.; Tredennick, T. Benefit to Radiation Risk of Breast-specific Gamma Imaging Compared with Mammography in Screening Asymptomatic Women with Dense Breasts. Radiology 2016, 281, 583–588. [Google Scholar] [CrossRef]
  19. Horne, T.; Pappo, I.; Cohen-Pour, M.; Baumer, M.; Orda, R. 99Tc(m)-tetrofosmin scintimammography for detecting breast cancer: A comparative study with 99Tc(m)-MIBI. Nucl. Med. Commun. 2001, 22, 807–811. [Google Scholar] [CrossRef]
  20. Chen, Q.; An, X.Y.; Liang, H. Clinical value of (99m)Tc-tetrofosmin imaging and ultrasonography in diagnosis of breast cancer: A comparative study. J. South. Med. Univ. 2008, 28, 140–141. [Google Scholar] [CrossRef]
  21. O’Connor, M.K.; Morrow, M.M.B.; Hunt, K.N.; Boughey, J.C.; Wahner-Roedler, D.L.; Conners, A.L.; Rhodes, D.J.; Hruska, C.B. Comparison of Tc-99m maraciclatide and Tc-99m sestamibi molecular breast imaging in patients with suspected breast cancer. EJNMMI Res. 2017, 7, 5. [Google Scholar] [CrossRef] [Green Version]
  22. Goffin, V.; Bogorad, R.L.; Touraine, P. Identification of gain-of-function variants of the human prolactin receptor. Methods Enzym. 2010, 484, 329–355. [Google Scholar] [CrossRef]
  23. Ahmadpour, S.; Noaparast, Z.; Abedi, S.M.; Hosseinimehr, S.J. (99m)Tc-HYNIC-(tricine/EDDA)-FROP peptide for MCF-7 breast tumor targeting and imaging. J. Biomed. Sci. 2018, 25, 17. [Google Scholar] [CrossRef] [PubMed]
  24. Liu, H.; Zhan, H.; Zhang, Y.; He, G.; Wang, H.; Zhang, Q.; Zheng, L. Comparison of BSGI and MRI as Approaches to Evaluating Residual Tumor Status after Neoadjuvant Chemotherapy in Chinese Women with Breast Cancer. Diagnostics 2021, 11, 1846. [Google Scholar] [CrossRef] [PubMed]
  25. Keto, J.L.; Kirstein, L.; Sanchez, D.P.; Fulop, T.; McPartland, L.; Cohen, I.; Boolbol, S.K. MRI versus breast-specific gamma imaging (BSGI) in newly diagnosed ductal cell carcinoma-in-situ: A prospective head-to-head trial. Ann. Surg. Oncol. 2012, 19, 249–252. [Google Scholar] [CrossRef] [PubMed]
  26. Brem, R.F.; Fishman, M.; Rapelyea, J.A. Detection of ductal carcinoma in situ with mammography, breast specific gamma imaging, and magnetic resonance imaging: A comparative study. Acad. Radiol. 2007, 14, 945–950. [Google Scholar] [CrossRef]
  27. Meissnitzer, T.; Seymer, A.; Keinrath, P.; Holzmannhofer, J.; Pirich, C.; Hergan, K.; Meissnitzer, M.W. Added value of semi-quantitative breast-specific gamma imaging in the work-up of suspicious breast lesions compared to mammography, ultrasound and 3-T MRI. Br. J. Radiol. 2015, 88, 20150147. [Google Scholar] [CrossRef]
  28. Yu, X.; Hu, G.; Zhang, Z.; Qiu, F.; Shao, X.; Wang, X.; Zhan, H.; Chen, Y.; Deng, Y.; Huang, J. Retrospective and comparative analysis of (99m)Tc-Sestamibi breast specific gamma imaging versus mammography, ultrasound, and magnetic resonance imaging for the detection of breast cancer in Chinese women. BMC Cancer 2016, 16, 450. [Google Scholar] [CrossRef]
  29. Kim, J.S.; Lee, S.M.; Cha, E.S. The diagnostic sensitivity of dynamic contrast-enhanced magnetic resonance imaging and breast-specific gamma imaging in women with calcified and non-calcified DCIS. Acta Radiol. 2014, 55, 668–675. [Google Scholar] [CrossRef]
  30. Kim, B.S. Usefulness of breast-specific gamma imaging as an adjunct modality in breast cancer patients with dense breast: A comparative study with MRI. Ann. Nucl. Med. 2012, 26, 131–137. [Google Scholar] [CrossRef]
  31. Kim, S.; Plemmons, J.; Hoang, K.; Chaudhuri, D.; Kelley, A.; Cunningham, T.; Hoefer, R. Breast-Specific Gamma Imaging Versus MRI: Comparing the Diagnostic Performance in Assessing Treatment Response After Neoadjuvant Chemotherapy in Patients with Breast Cancer. AJR Am. J. Roentgenol. 2019, 212, 696–705. [Google Scholar] [CrossRef]
  32. Brem, R.F.; Floerke, A.C.; Rapelyea, J.A.; Teal, C.; Kelly, T.; Mathur, V. Breast-specific gamma imaging as an adjunct imaging modality for the diagnosis of breast cancer. Radiology 2008, 247, 651–657. [Google Scholar] [CrossRef] [PubMed]
  33. Lee, A.; Chang, J.; Lim, W.; Kim, B.S.; Lee, J.E.; Cha, E.S.; Moon, B.I. Effectiveness of breast-specific gamma imaging (BSGI) for breast cancer in Korea: A comparative study. Breast J. 2012, 18, 453–458. [Google Scholar] [CrossRef] [PubMed]
  34. Liu, H.; Zhan, H.; Sun, D. Comparison of (99m)Tc-MIBI scintigraphy, ultrasound, and mammography for the diagnosis of BI-RADS 4 category lesions. BMC Cancer 2020, 20, 463. [Google Scholar] [CrossRef]
  35. Cho, M.J.; Yang, J.H.; Yu, Y.B.; Park, K.S.; Chung, H.W.; So, Y.; Choi, N.; Kim, M.Y. Validity of breast-specific gamma imaging for Breast Imaging Reporting and Data System 4 lesions on mammography and/or ultrasound. Ann. Surg. Treat. Res. 2016, 90, 194–200. [Google Scholar] [CrossRef] [PubMed]
  36. Tan, H.; Zhang, H.; Yang, W.; Fu, Y.; Gu, Y.; Du, M.; Cheng, D.; Shi, H. Breast-specific gamma imaging with Tc-99m-sestamibi in the diagnosis of breast cancer and its semiquantitative index correlation with tumor biologic markers, subtypes, and clinicopathologic characteristics. Nucl. Med. Commun. 2016, 37, 792–799. [Google Scholar] [CrossRef] [PubMed]
  37. Brem, R.F.; Ruda, R.C.; Yang, J.L.; Coffey, C.M.; Rapelyea, J.A. Breast-Specific γ-Imaging for the Detection of Mammographically Occult Breast Cancer in Women at Increased Risk. J. Nucl. Med. 2016, 57, 678–684. [Google Scholar] [CrossRef] [PubMed]
  38. Park, J.S.; Lee, A.Y.; Jung, K.P.; Choi, S.J.; Lee, S.M.; Kyun Bae, S. Diagnostic Performance of Breast-Specific Gamma Imaging (BSGI) for Breast Cancer: Usefulness of Dual-Phase Imaging with (99m)Tc-sestamibi. Nucl. Med. Mol. Imaging 2013, 47, 18–26. [Google Scholar] [CrossRef]
  39. Park, J.Y.; Yi, S.Y.; Park, H.J.; Kim, M.S.; Kwon, H.J.; Park, N.H.; Moon, S.Y. Breast-specific gamma imaging: Correlations with mammographic and clinicopathologic characteristics of breast cancer. AJR Am. J. Roentgenol. 2014, 203, 223–228. [Google Scholar] [CrossRef]
  40. Park, J.Y.; Chun, K.A.; Shin, H.J.; Yi, S.Y.; Kwon, H.J.; Park, H.J. Breast-specific gamma imaging of invasive breast cancer: Clinicopathologic factors affecting detectability and correlation with mammographic findings. Clin. Imaging 2018, 51, 168–173. [Google Scholar] [CrossRef]
  41. Wang, P.L.; Zheng, F.Y.; Lu, Q.; Xia, H.S.; Huang, B.J.; Liu, L.M.; Wang, W.P. Imaging features of pure mucinous breast carcinoma: Correlation with extracellular mucus content. Clin. Radiol. 2019, 74, 569.e569–569.e517. [Google Scholar] [CrossRef]
  42. Zhang, Z.; Wang, W.; Wang, X.; Yu, X.; Zhu, Y.; Zhan, H.; Chen, Z.; Li, B.; Huang, J. Breast-specific gamma imaging or ultrasonography as adjunct imaging diagnostics in women with mammographically dense breasts. Eur. Radiol. 2020, 30, 6062–6071. [Google Scholar] [CrossRef] [PubMed]
  43. Chung, H.W.; So, Y.; Yang, J.H.; Park, K.S.; Yoo, Y.B.; Choi, N.; Kim, M.Y.; Kim, J.; Lee, E.J. Adjunctive Breast-Specific Gamma Imaging for Detecting Cancer in Women with Calcifications at Mammography. Ann. Surg. Oncol. 2017, 24, 3541–3548. [Google Scholar] [CrossRef] [PubMed]
  44. Rechtman, L.R.; Lenihan, M.J.; Lieberman, J.H.; Teal, C.B.; Torrente, J.; Rapelyea, J.A.; Brem, R.F. Breast-specific gamma imaging for the detection of breast cancer in dense versus nondense breasts. AJR Am. J. Roentgenol. 2014, 202, 293–298. [Google Scholar] [CrossRef]
  45. Kim, M.Y.; Choi, N.; Ko, S.M.; Chung, H.W. Background uptake of breast-specific gamma imaging: Correlation with mammographic breast density and background enhancement of breast MRI. Clin. Imaging 2014, 38, 255–258. [Google Scholar] [CrossRef]
  46. Johnson, N.; Sorenson, L.; Bennetts, L.; Winter, K.; Bryn, S.; Johnson, W.; Glissmeyer, M.; Garreau, J.; Blanchard, D. Breast-specific gamma imaging is a cost effective and efficacious imaging modality when compared with MRI. Am. J. Surg. 2014, 207, 698–701; discussion 701. [Google Scholar] [CrossRef] [PubMed]
  47. Valhiots, A.; Griffin, B.; Stavros, A.T.; Magrolis, J. Analysis of utilization patterns and associated costs of the breast imaging and diagnostic procedures after screening mammography. Clin. Outcomes Res. 2018, 26, 157–167. [Google Scholar] [CrossRef]
  48. Keshavarz, K.; Jafari, M.; Lotfi, F.; Bastani, P.; Salesi, M.; Gheisari, F.; Hemami, M.R. Positron Emission Mammography (PEM) in the diagnosis of breast cancer: A systematic review and economic evaluation. Med. J. Islam Repub. Iran 2020, 34, 100. [Google Scholar] [CrossRef]
  49. Yamamoto, Y.; Tasaki, Y.; Kuwada, Y.; Ozawa, Y.; Inoue, T. A preliminary report of breast cancer screening by positron emission mammography. Ann. Nucl. Med. 2016, 30, 130–137. [Google Scholar] [CrossRef]
  50. Schilling, K.; Narayanan, D.; Kalinyak, J.E.; The, J.; Velasquez, M.V.; Kahn, S.; Saady, M.; Mahal, R.; Chrystal, L. Positron emission mammography in breast cancer presurgical planning: Comparisons with magnetic resonance imaging. Eur. J. Nucl. Med. Mol. Imaging 2011, 38, 23–36. [Google Scholar] [CrossRef]
  51. Berg, W.A.; Madsen, K.S.; Schilling, K.; Tartar, M.; Pisano, E.D.; Larsen, L.H.; Narayanan, D.; Ozonoff, A.; Miller, J.P.; Kalinyak, J.E. Breast cancer: Comparative effectiveness of positron emission mammography and MR imaging in presurgical planning for the ipsilateral breast. Radiology 2011, 258, 59–72. [Google Scholar] [CrossRef] [Green Version]
  52. Narayanan, D.; Madsen, K.S.; Kalinyak, J.E.; Berg, W.A. Interpretation of positron emission mammography and MRI by experienced breast imaging radiologists: Performance and observer reproducibility. AJR. Am. J. Roentgenol. 2011, 196, 971–981. [Google Scholar] [CrossRef] [PubMed]
  53. Berg, W.A.; Weinberg, I.N.; Narayanan, D.; Lobrano, M.E.; Ross, E.; Amodei, L.; Tafra, L.; Adler, L.P.; Uddo, J.; Stein 3rd, W.; Levine, E.A. High-resolution fluorodeoxyglucose positron emission tomography with compression (“positron emission mammography”) is highly accurate in depicting primary breast cancer. Breast J. 2006, 12, 309–323. [Google Scholar] [CrossRef] [PubMed]
  54. Eo, J.S.; Chun, I.K.; Paeng, J.C.; Kang, K.W.; Lee, S.M.; Han, W.; Noh, D.Y.; Chung, J.K.; Lee, D.S. Imaging sensitivity of dedicated positron emission mammography in relation to tumor size. Breast 2012, 21, 66–71. [Google Scholar] [CrossRef] [PubMed]
Cancers 14 04619 g001 550
Figure 1. PRISMA flow-chart.
Figure 1. PRISMA flow-chart.
Cancers 14 04619 g001
Table
Table 1. A summary of studies that compared BSGI and MRI.
Table 1. A summary of studies that compared BSGI and MRI.
BSGI vs. MRI SensitivitySpecificityPPVNPV
Liu et al., 2020 [1]91.7 vs. 92.580.7 vs. 69.7 87.1 vs. 86.587.2 vs. 81.5
Liu et al., 2021 [2]76.9 vs. 83.970.6 vs. 58.8Not esplicitedNot esplicited
Keto et al., 2011 [3]89 vs. 94Not esplicitedNot esplicitedNot esplicited
Brem et al., 2007 [4]91 vs. 88Not esplicitedNot esplicitedNot esplicited
Meissnitzer et al., 2015 [5]90 vs. 8856 vs. 4085 vs. 8067 vs. 56
Yu et al., 2016 [6]80.35 vs. 94.0683.19 vs. 67.6987.1 vs. 81.975 vs. 88
Kim et al., 2014 [7]68.6 vs. 91.4Not esplicitedNot esplicitedNot esplicited
Kim et al., 2012 [8]88.8 vs. 90.190.1 vs. 39.476.6 vs. 35.895.5 vs. 93.3
Kim et al., 2019 [9]70.2 vs. 83.390 vs. 6094.6 vs. 84.251.9 vs. 56.3
Brem et al., 2008 [10]89 vs. 10071 vs. 2553 vs. 3394 vs. 100
Table
Table 2. A collection of papers in which BSGI was compared to mammography.
Table 2. A collection of papers in which BSGI was compared to mammography.
BSGI vs. MammographySensitivitySpecificityPPVNPV
Liu et al., 2020 [1]91.7 vs. 77.3 80.7 vs. 74.587.1 vs. 81.287.2 vs. 69.8
Lee et al., 2012 [11]95.45 vs. 93.6490.93 vs. 90.6676.09 vs. 75.1898.51 vs. 97.92
Liu et al., 2020 [12]94.9 vs. 91.578.3 vs. 48.389.5 vs. 77.588.7 vs. 74.4
Cho et al., 2016 [13]90.9 vs. 74.278.1 vs. 56.374.1 vs. 53.992.6 vs. 76.1
Brem et al., 2007 [4]91 vs. 82Not esplicitedNot esplicitedNot esplicited
Meissnitzer 2015 [5]90 vs. 8556 vs. 2885 vs. 7667 vs. 41
Yu et al., 2016 [6]80.35 vs. 75.683.19 vs. 66.3987.10 vs. 76.0575 vs. 65.83
Kim et al., 2012 [8]92.2 vs. 53.689.3 vs. 94.794.6 vs. 95.384.8 vs. 50
Tan et al., 2016 [14]94.1 vs. 84.5Not esplicitedNot esplicitedNot esplicited
Table
Table 3. Sensitivity, specificity, PVV and NPV for BSGI and ultrasound in the included studies.
Table 3. Sensitivity, specificity, PVV and NPV for BSGI and ultrasound in the included studies.
BSGI vs. UltrasoundSensitivitySpecificityPPVNPV
Liu et al., 2020 [1]91.7 vs. 82.180.7 vs. 70.887.1 vs. 8087.2 vs. 73.5
Lee et al., 2012 [11]95.45 vs. 98.1890.93 vs. 87.0976.09 vs. 69.6898.51 vs. 99.37
Liu et al., 2020 [12]94.9 vs. 93.2 78.3 vs. 53.389.5 vs. 79.688.7 vs. 80
Cho et al., 2016 [13]90.9 vs. 87.978.1 vs. 19.874.1 vs. 4392.6 vs. 70.4
Meissnitzer 2015 [5]90 vs. 9956 vs. 2085 vs. 7767 vs. 83
Yu et al., 2016 [6]80.35 vs. 82.1483.19 vs. 77.31 87.10 vs. 83.6475 vs. 75.41
Kim et al., 2012 [8]92.2 vs. 91.589.3 vs. 53.394.6 vs. 8084.8 vs. 75.5
Tan et al., 2016 [14]94.1 vs. 84.5Not esplicitedNot esplicitedNot esplicited
Table
Table 4. QUADAS 2 score of all included studies.
Table 4. QUADAS 2 score of all included studies.
Risk of Bias AssessmentApplicability Concerns Assessment
Patient SelectionIndex TestReference StandardFlow and TimingPatient SelectionIndex TestReference Standard
Liu et al., 2020 [12]LowLowLowLowLowLowLow
Liu et al., 2021 [24]LowLowLowLowLowLowLow
Keto el al. 2011 [25]LowLowLowLowLowLowLow
Brem et al., 2007 [26]LowUnclearLowLowLowLowLow
Meissnitzer et al., 2015 [27]LowLowLowLowLowLowLow
Yu et al., 2016 [28]LowLowLowLowLowLowLow
Kim et al., 2014 [29]LowLowLowLowLowLowLow
Kim et al., 2012 [30]LowLowLowLowLowLowLow
Kim et al., 2019 [31]LowLowLowLowLowLowLow
Brem et al., 2008 [32]LowLowLowLowLowLowLow
Lee et al., 2012 [33]LowUnclearLowLowLowLowLow
Lee et al., 2020 [34]LowLowLowLowLowLowLow
Cho et al., 2016 [35]LowLowLowLowLowLowLow
Tan et al., 2016 [36]LowLowLowLowLowLowLow
Brem et al., 2016 [37]HighHighLowLowHighHighLow
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

De Feo, M.S.; Sidrak, M.M.A.; Conte, M.; Frantellizzi, V.; Marongiu, A.; De Cristofaro, F.; Nuvoli, S.; Spanu, A.; De Vincentis, G. Breast-Specific Gamma Imaging: An Added Value in the Diagnosis of Breast Cancer, a Systematic Review. Cancers 2022, 14, 4619. https://doi.org/10.3390/cancers14194619

AMA Style

De Feo MS, Sidrak MMA, Conte M, Frantellizzi V, Marongiu A, De Cristofaro F, Nuvoli S, Spanu A, De Vincentis G. Breast-Specific Gamma Imaging: An Added Value in the Diagnosis of Breast Cancer, a Systematic Review. Cancers. 2022; 14(19):4619. https://doi.org/10.3390/cancers14194619

Chicago/Turabian Style

De Feo, Maria Silvia, Marko Magdi Abdou Sidrak, Miriam Conte, Viviana Frantellizzi, Andrea Marongiu, Flaminia De Cristofaro, Susanna Nuvoli, Angela Spanu, and Giuseppe De Vincentis. 2022. "Breast-Specific Gamma Imaging: An Added Value in the Diagnosis of Breast Cancer, a Systematic Review" Cancers 14, no. 19: 4619. https://doi.org/10.3390/cancers14194619

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop