- Research article
- Open access
- Published:
Screening mammography for second breast cancers in women with history of early-stage breast cancer: factors and causes associated with non-detection
BMC Medical Imaging volume 19, Article number: 2 (2019)
Abstract
Background
The aim of our study was to identify the factors and causes associated with non-detection for second breast cancers on screening mammography in women with a personal history of early-stage breast cancer.
Methods
Between January 2000 and December 2008, 7976 women with early-stage breast cancer underwent breast surgery in our institution. The inclusion criteria of our study were patients who had: (a) subsequent in-breast recurrence, (b) surveillance mammography within 1 year before recurrence. Retrospective analysis of mammography was performed. Non-detection was defined as second breast cancers that were not visible on screening mammography. Imaging features, demographics, primary breast cancer (PBC) characteristics, and clinical features were evaluated to determine its association with non-detection. Univariate and multivariate logistic regression analyses were also performed to identify the factors related to non-detection.
Results
We identified 188 patients that met the criteria. Among them, 39% of patients showed non-detection (n = 74). Of the 74 patients with non-detection, 53 (72%) were classified as having no detectable mammographic abnormality (i.e., true negative) due to overlapping dense breast tissue (n = 32), obscured by postoperative scar (n = 12) or difficult anatomic location / poor positioning (n = 9). The remaining 21 patients were categorized as having subtle findings (n = 11) or missed cancer (n = 10). Non-detection for second breast cancers were significantly associated with mammographic breast density (p = 0.001, OR = 2.959) and detectability of PBC on mammography (p = 0.011, OR = 3.013).
Conclusion
Non-detection of second breast cancer in women with a personal history of early-stage breast cancer were associated with mammographic dense breast and lower detectability of PBC on mammography.
Background
Breast cancer survival rates following diagnosis have improved through advances in local and systemic treatments and early detection [1], and early-stage breast cancers, including in situ (stage 0) and stage I-II, have a better prognosis than the later stages of invasive breast cancers [2]. At the same time, women with a personal history of early-stage breast cancer (PHBC) have an increased risk of second breast cancers [3], which can be either a local recurrence or a new primary cancer in the conserved and contralateral breast [4]. Studies have shown that early detection of second breast cancers in the asymptomatic phase has a better prognosis than patients with symptomatic disease [5]. A meta-analysis of 2263 breast cancer survivors showed that survival in both loco-regional and contralateral breast cancer recurrence was better in the early detection group (asymptomatic recurrence found by mammography) compared to women with symptomatic disease [6].
Surveillance of breast cancer patients after curative primary therapy focuses on the early detection of recurrent disease while still potentially curable. Current guidelines from the National Comprehensive Cancer Network and the American Society of Clinical Oncology recommend annual mammography for women with breast cancer following primary treatment [7,8,9]. In previous studies, 8 to 50% of ipsilateral recurrences and 18 to 80% of contralateral metachronous cancers were detected by mammography alone [3, 10]. This result highlights the need to identify causes and risk factors for non-detection on screening mammography for women with a PHBC. To our knowledge, only a few studies focused solely on interval cancer or false negative results have been published [11,12,13,14], but no studies have yet determined the reasons for non-detection that included all of them. Therefore, the purpose of this study was to identify the factors and causes associated with non-detection for second breast cancers on screening mammography in women with a PHBC.
Methods
Study population
Between January 2000 and December 2008, 7976 women (mean age, 48.9 years; age range, 18–88 years) with early-stage breast cancer, including ductal carcinoma in situ (DCIS) or stage I-II invasive carcinoma, underwent breast surgery in our institution. Our aim was to identify the factors and causes associated with non-detection for second breast cancers on screening mammography in women with a personal history of early-stage breast cancer. Therefore, the inclusion criteria of our study were women who had: (a) subsequent in-breast (ipsi- or contralateral) recurrence, and (b) surveillance mammography within 1 year before recurrence. We excluded patients whose mammography was not available in our picture archiving and communication system (n = 6). Institutional review board approval (No. 2017–0440) was obtained for this study, and the need for informed patient consent was waived owing to its retrospective nature.
Definitions
In-breast recurrence included ipsilateral and contralateral recurrence. Ipsilateral recurrence was defined as local tumor recurrence in the same side after curative breast surgery. Metachronous breast cancer after primary cancer treatment in the opposite side was considered as contralateral recurrence.
Screening mammography after primary cancer treatment indicated to be a routine screen without any breast symptom. Non-detection was defined as second breast cancers that were not visible on screening mammography, including interval cancers (diagnosed before the next invitation to screening after negative screening mammography).
Clinicopathologic data review
Clinicopathologic data were obtained from the electronic medical records. The clinical features of all patients were collected, including age at diagnosis of primary breast cancer (PBC), family history of breast cancer, menarcheal age, menopausal status, body mass index (BMI), breast feeding history, oral pill or hormonal therapy history, presence or absence of primary breast cancer symptoms, type of primary breast cancer surgery, and adjuvant treatment of primary breast cancer (radiotherapy, chemotherapy, and/or hormonal therapy).
The pathological data were also reviewed. The recorded data included pathologic tumor stage, histologic grade, lymph node (LN) status, lymphovascular invasion (LVI), and molecular subtype based on the expression of estrogen receptor (ER), progesterone receptor (PR), and human epidermal growth factor receptor 2 (HER2) status of both primary and recurrent tumors.
Mammographic evaluation
All mammograms were obtained by using screen-film mammography units with a Senographe DMR scanner (GE Healthcare, Milwaukee, USA) or a Performa scanner (Instrumentarium), or dedicated digital mammography units with a Senographe DS or Senographe Essential unit (GE Healthcare). A combination of craniocaudal and mediolateral oblique views was evaluated.
All images were reviewed by two board-certified breast radiologists with ten and five years of clinical experience, respectively, and the final decision was carried out by consensus when a discrepancy occurred. Mammographic evaluation was done in two steps. The first step was blinded review. At this step, the radiologists were blinded to any clinical or histopathological information and other imaging results. They performed a retrospective review of the screening mammography whether the findings on screening mammography should be recalled or not. Cases that were not recalled by the blinded review were considered as non-detection.
The next step was unblinded review of mammography. In the case of non-detection from the first step of blinded review, the radiologists re-reviewed the mammography to determine the causes of non-detection. At that time, they were unblinded and used the other imaging results, such as ultrasound, magnetic resonance imaging, as available, to determine the reference location of the second breast cancers. The causes for non-detection of surveillance mammography were classified as ‘true negative’ or ‘interpretation error’. If the lesion could not be seen even in the unblinded repeat review, it was defined as ‘true negative’. And, the ‘interpretation error’ was subclassified as ‘missed’ or ‘subtle findings’. A cancer was defined as ‘missed’ if two radiologists agreed that the mammogram showed malignant signs that were overlooked or misdiagnosed in the first blinded review. If the mammogram showed nonspecific findings for malignancy, including asymmetry or a benign-appearing calcification, it was defined as ‘subtle finding’.
The visually estimated mammographic breast density was also determined for each patient based on the four categories of breast composition as described by the American College of Radiology (ACR) Breast Imaging Reporting and Data System (BI-RADS) [15]. Breast compositions c and d were classified as dense and breast compositions a and b were defined as fatty breast. The detectability of primary breast cancer on mammography was recorded from a review of the radiology reports during practice.
Statistical analyses
Associations between the non-detection and categorical variables were assessed using chi-square or Fisher’s exact test, and t-test or Mann-Whitney test for continuous variables. Investigated factors included mammographic features (breast density and detectability of primary breast cancer on mammography), time interval between final diagnosis of secondary breast cancers and mammography, patient demographics, primary breast cancer tumor characteristics, and various clinical features. Univariate and multivariate logistic regression analyses were performed to identify the factors related to non-detection. A multivariable model using backward elimination was used to identify the independent factors associated with non-detection. The outputs were plotted, showing the adjusted odds ratio (OR) and the 95% confidence interval (CI) for each factor. All p-values < 0.05 were considered statistically significant. All statistical analyses were performed using SPSS version 12.0 (SPSS Inc., Chicago, IL, USA).
Results
Non-detection for second breast cancers
Among 7976 women with early-stage breast cancer who underwent breast surgery in our institution (Fig. 1), there were 1064 (13.3%) patients with subsequent recurrence. Of these, 289 patients were identified with in-breast recurrence and 194 patients had screening mammography within 1 year before recurrence. After excluding 6 patients whose mammography was unavailable, a total of 188 patients (mean age, 44 years; age range, 21–79 years) comprised our study population. The final diagnosis of the second breast cancers was based on surgery (n = 172), core needle biopsy (n = 13), or fine needle aspiration (n = 3). The mean time period from initial treatment to recurrence was 56 months (range, 5–152 months). Of those, 143 cases of ipsilateral recurrence and 48 cases of contralateral recurrence were identified. Recurrence in both sides was detected in 3 cases. Of the 188 patients, 86 (46%) second breast cancers showed the same molecular subtype as the primary breast cancer.
In the blinded mammographic review, 114 of 188 cases were detected by screening mammography (Fig. 2). In other words, 74 patients (39%) showed non-detection in the first blinded review.
Causes associated with non-detection
Of 74 patients with non-detection, 53 (72%) showed no detectable mammographic abnormality (i.e., ‘true negative’)(Fig. 3). In the unblinded repeat review using the reference location of the second breast cancers, 32 cases were obscured by overlapping dense breast tissue, 12 cases were obscured by postoperative scar, and 9 cases were not included due to difficult anatomic location or poor positioning. The remaining 21 patients were classified as ‘interpretation error’, including 11 subtle findings and 10 missed cancers. Subtle findings (Fig. 4) included asymmetry (n = 8) or benign-appearing calcification (n = 3), and ‘missed cancer’ showed a mass (n = 6), calcification (n = 3), or focal asymmetry (n = 1).
Factors associated with non-detection
Tables 1 and 2 summarize the association between clinical features, tumor characteristics, and non-detection. The clinical features were not significantly different between those with or without non-detection, except for family history (p = 0.043). Also, no significant difference was observed between these two groups in terms of primary breast cancer tumor characteristics.
Table 3 shows the association between mammographic features and non-detection. Mammographic breast density was significantly associated with non-detection (p < 0.001). Non-detection for second breast cancers was significantly more frequent when primary breast cancer was not detectable on mammography compared to when it was detectable (p = 0.007). There was no statistically significant difference in the time interval between the final diagnosis of second breast cancers and mammography.
In the multivariate analysis, mammographic breast density and detectability of primary breast cancer on mammography, remained independent variables related to non-detection (Table 4). The odds ratios were 2.959 (95% CI: 1.581, 5.540) for breast density and 3.013 (95% CI: 1.290, 7.041) for mammographic detectability of primary breast cancer.
Discussion
As breast cancer survivors are at a higher risk for second breast cancer in the conserved and opposite breasts, women with breast cancer are recommended for regular imaging surveillance after primary treatment. Our study of the screening mammography in women with a personal history of early-stage breast cancer revealed that 39% of patients showed non-detection for second breast cancer. Our study also shows that non-detection for second breast cancer was associated with mammographic breast density and the detectability of primary breast cancer on mammography.
In our study, the most common cause of non-detection by screening mammography was ‘true negative’ cancer. Fifty-three (72%) of 74 patients with non-detection showed no detectable mammographic abnormality in the unblinded repeat review with the reference location of the second breast cancers. 32 (43%) cases were obscured by overlapping normal breast tissue and 12 (16%) cases were obscured by postoperative scar. Breast cancer can be invisible on mammography if the tumor does not show a higher density distinct from surrounding fibroglandular tissue or postoperative scar. The remaining 9 (12%) cases of ‘true negative’ cancer were not included due to difficult anatomic location or poor positioning. These cancers more frequently were located at the immediate prepectoral region. Schrading and Kuhl [16] reported that the posterior location was observed more frequently in women at high risk for breast cancer and women with BRCA mutations. Thus, they suggested breast positioning during mammographic examinations should be optimized to include the posterior tissues, particularly in women at high risk with dense breasts.
The remaining 21 (28%) non-detection patients were classified as ‘interpretation error’, including 11 subtle findings and 10 missed cancers. The percentage of interpretation error in our study was similar to previous results from the ACRIN 6666 study and other reports on mammographically missed cancers [17,18,19]. In the ACRIN study, a retrospective review revealed that 19 of 67 (28%) mammographically undetected cancers were interpretation errors. It meant that although the lesions were visible on mammography, they were considered as probably benign findings, such as asymmetry or benign-appearing calcification. Of the 21 misinterpreted cases at mammography in our study, the lesions were a mass or asymmetry in 15 cases and calcification in 6 cases. These findings are consistent with those of previous studies that reported that noncalcified findings were more common than calcifications among interpretation errors [20, 21].
Our multivariate analysis found that mammographic breast density (OR = 2.959; p = 0.001) and mammographic detectability of primary breast cancer (PBC; OR = 3.013; p = 0.011) are independent variables associated with non-detection for second breast cancers. Mammographic breast density is one of the known risk factors for breast cancer and it also makes the detection of cancer by mammography more difficult [22]. Thus, breast density is a major issue in breast cancer screening because it is one of the variables proposed for tailored screening [23, 24]. In an analysis of missed cancers at screening mammography, Bird et al. reported that missed cancers occurred in women with denser breasts. These findings are similar with those in our study of postoperative patients, which showed that 66% of patients with non-detection had dense breast tissues and 62% of patients without non-detection had fatty breasts by mammography [25].
We also identified that the detectability of primary breast cancer on mammography is associated with non-detection for second breast cancers. Yang et al. [26] reported that clinical and pathologic differences in mammographically occult and mammographically positive primary tumors ultimately result in more false-negative mammograms at recurrence for the mammographically occult cohort. The results of the Yang et al. study showed lower mammographic detectability of the recurrent cancer in the mammographic occult cohort after breast-conserving operation. Breast density is influenced by age, parity, body mass index, and menopause, but these factors account for only 20–30% of the variation in breast density in the population. Twin studies have shown that the percent of mammographic density is highly heritable [22]. Furthermore, a significant portion (46%) of second breast cancers in our study showed the same molecular subtype as the primary breast cancer. This result is similar to those in previous studies, which reported that 48.3–71.9% of recurrent breast cancers had no changes in hormone receptors and HER2 status from the primary breast cancer [27,28,29].
Currently, there is a lack of consistent data on appropriate screening strategies to potentially reduce non-detection of breast cancers in women with a PHBC participating in mammography screening. The addition of ultrasonography or MRI may have its strong points for visualizing areas that cannot be approached by mammography and could provide additional information regarding differentiation between postoperative changes and tumor recurrence, especially in high risk women [30]. Recently, Cho et al. showed that addition of MRI to mammography screening improved the detection of early-stage breast cancers in women treated with breast conserving therapy [4]. It is worthwhile to know which group of patients may benefit more from the adjunct screening in women with a PHBC. Our study revealed that mammographic dense breast and lower detectability of primary breast cancer on mammography are associated with non-detection for second breast cancer in women with a PHBC. These findings can provide indirect evidence that adjunct screening tools may be necessary for these patients.
Our study had limitations. First, this was a retrospective study conducted at a single institution, although we did include quite a large number of consecutive patients. Second, not all of the mammograms were obtained by digital mammography, which may have affected the outcome. Thus, prospective multi-institutional evaluation is needed to eliminate bias based on differences that may exist in patient demographics, diagnostic equipment, or therapeutic interventions.
Conclusion
Our study revealed that the non-detection of second breast cancer in women with a personal history of early-stage breast cancer were associated with mammographic dense breast tissue and lower detectability of primary breast cancer on mammography. Most breast cancers with non-detection were not identified by mammography, even in an unblinded review. Further study is necessary to evaluate the role of adjunct screening tools in patients with a history of early-stage breast cancer.
Abbreviations
- BI-RADS:
-
Breast imaging reporting and data system
- DCIS:
-
Ductal carcinoma in situ
- PBC:
-
Primary breast cancer
- PHBC:
-
Personal history of breast cancer
References
Webb PM, Cummings MC, Bain CJ, Furnival CM. Changes in survival after breast cancer: improvements in diagnosis or treatment? Breast. 2004;13:7–14.
Sant M, Allemani C, Capocaccia R, et al. Stage at diagnosis is a key explanation of differences in breast cancer survival across Europe. Int J Cancer. 2003;106:416–22.
Houssami N, Abraham LA, Miglioretti DL, et al. Accuracy and outcomes of screening mammography in women with a personal history of early-stage breast cancer. JAMA. 2011;305:790–9.
Cho N, Han W, Han BK, et al. Breast cancer screening with mammography plus ultrasonography or magnetic resonance imaging in women 50 years or younger at diagnosis and treated with breast conservation therapy. JAMA Oncol. 2017;3:1495–502.
van der Sangen MJ, Poortmans PM, Scheepers SW, et al. Prognosis following local recurrence after breast conserving treatment in young women with early breast cancer. Eur J Surg Oncol. 2013;39:892–8.
Lu WL, Jansen L, Post WJ, Bonnema J, Van de Velde JC, De Bock GH. Impact on survival of early detection of isolated breast recurrences after the primary treatment for breast cancer: a meta-analysis. Breast Cancer Res Treat. 2009;114:403–12.
Khatcheressian JL, Hurley P, Bantug E, et al. Breast cancer follow-up and management after primary treatment: American Society of Clinical Oncology clinical practice guideline update. J Clin Oncol. 2013;31:961–5.
Schneble EJ, Graham LJ, Shupe MP, et al. Current approaches and challenges in early detection of breast cancer recurrence. J Cancer. 2014;5:281–90.
National Comprehensive Cancer Network. NCCN guidline Breast cancer, version 2. https://www.nccn.org/professionals/physician_gls/default.aspx. Published 2017.
Arasu VA, Joe BN, Lvoff NM, et al. Benefit of semiannual ipsilateral mammographic surveillance following breast conservation therapy. Radiology. 2012;264:371–7.
Domingo L, Salas D, Zubizarreta R, et al. Tumor phenotype and breast density in distinct categories of interval cancer: results of population-based mammography screening in Spain. Breast Cancer Res. 2014;16:R3.
Houssami N, Abraham LA, Kerlikowske K, et al. Risk factors for second screen-detected or interval breast cancers in women with a personal history of breast cancer participating in mammography screening. Cancer Epidemiol Biomark Prev. 2013;22:946–61.
Kerlikowske K, Zhu W, Tosteson AN, et al. Identifying women with dense breasts at high risk for interval cancer: a cohort study. Ann Intern Med. 2015;162:673–81.
Nelson HD, O'Meara ES, Kerlikowske K, Balch S, Miglioretti D. Factors associated with rates of false-positive and false-negative results from digital mammography screening: an analysis of registry data. Ann Intern Med. 2016;164:226–35.
American College of Radiology, BI-RADS Committee. ACR BI-RADS atlas : breast imaging reporting and data system, 5th ed. Reston, Va: American College of Radiology, 2013.
Schrading S, Kuhl CK. Mammographic, US, and MR imaging phenotypes of familial breast cancer. Radiology. 2008;246:58–70.
A. Berg W, Mendelson E, Le-Petross H, Zhang Z, Marques H, Adams A. Reasons for failed cancer detection in the ACRIN 6666 screening protocol: mammography, US, and MRI. http://archive.rsna.org/2011/11006596.html. Published 2011.
Hoff SR, Abrahamsen AL, Samset JH, Vigeland E, Klepp O, Hofvind S. Breast cancer: missed interval and screening-detected cancer at full-field digital mammography and screen-film mammography-- results from a retrospective review. Radiology. 2012;264:378–86.
Bae MS, Moon WK, Chang JM, et al. Breast cancer detected with screening US: reasons for nondetection at mammography. Radiology. 2014;270:369–77.
Ikeda DM, Birdwell RL, O'Shaughnessy KF, Brenner RJ, Sickles EA. Analysis of 172 subtle findings on prior normal mammograms in women with breast cancer detected at follow-up screening. Radiology. 2003;226:494–503.
van Dijck JA, Verbeek AL, Hendriks JH, Holland R. The current detectability of breast cancer in a mammographic screening program. A review of the previous mammograms of interval and screen-detected cancers. Cancer. 1993;72:1933–8.
Boyd NF, Martin LJ, Rommens JM, et al. Mammographic density: a heritable risk factor for breast cancer. Methods Mol Biol. 2009;472:343–60.
Schousboe JT, Kerlikowske K, Loh A, Cummings SR. Personalizing mammography by breast density and other risk factors for breast cancer: analysis of health benefits and cost-effectiveness. Ann Intern Med. 2011;155:10–20.
Kerlikowske K, Grady D, Barclay J, Sickles EA, Ernster V. Effect of age, breast density, and family history on the sensitivity of first screening mammography. JAMA. 1996;276:33–8.
Bird RE, Wallace TW, Yankaskas BC. Analysis of cancers missed at screening mammography. Radiology. 1992;184:613–7.
Yang T-IJ. Prognostic implications of patients with mammographically occult, early stage breast cancer http://elischolar.library.yale.edu/ymtdl/1606. Published 2011.
Macfarlane R, Seal M, Speers C, et al. Molecular alterations between the primary breast cancer and the subsequent locoregional/metastatic tumor. Oncologist. 2012;17:172–8.
El Nemr Esmail RS, El Farouk Abdel-Salam LO, Abd El Ellah MM. Could the breast prognostic biomarker status change during disease progression? An immunohistochemical comparison between primary tumors and synchronous nodal metastasis. Asian Pac J Cancer Prev. 2015;16:4317–21.
Ilgun S, Sarsenov D, Erdogan Z, et al. Receptor discordance rate and its effects on survival in primary and recurrent breast cancer patients. J BUON. 2016;21:1425–32.
Yoon JH, Kim MJ, Kim EK, Moon HJ. Imaging surveillance of patients with breast cancer after primary treatment: current recommendations. Korean J Radiol. 2015;16:219–28.
Acknowledgements
Not applicable.
Funding
No funding was received.
Availability of data and materials
The datasets analysed during the current study are available from the corresponding author on reasonable request.
Consent for publication
Not applicable.
Author information
Authors and Affiliations
Contributions
All authors (YKY, EYC, HHK, JHC, HJS and WJC) have made substantial contributions to acquisition of data, or analysis and interpretation of data. They have been involved in drafting the manuscript or revising it critically for important intellectual content. The authors have given final approval of the version to be published and agreed to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. Each author – namely YKY, EYC, HHK, JHC, HJS and WJC – has participated sufficiently in the work to take public responsibility for appropriate portions of the content.
Corresponding author
Ethics declarations
Ethics approval and consent to participate
This study was approved by the institutional review board of Asan Medical Center (No. 2017–0440), and the need for informed consent was waived due to the retrospective design of the study.
Competing interests
The authors declare that they have no competing interests.
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.
About this article
Cite this article
Yeom, Y.K., Chae, E.Y., Kim, H.H. et al. Screening mammography for second breast cancers in women with history of early-stage breast cancer: factors and causes associated with non-detection. BMC Med Imaging 19, 2 (2019). https://doi.org/10.1186/s12880-018-0303-3
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s12880-018-0303-3