Predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholds

Predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholds

Abstract Background Case–control studies show that mammographic density is a better risk factor when defined at higher than conventional pixel-brightness thresholds. We asked if this applied to interval and/or screen-detected cancers. Method We conducted a nested case–control study within the prospe...

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Main Authors: Tuong L. Nguyen, Ye K. Aung, Shuai Li, Nhut Ho Trinh, Christopher F. Evans, Laura Baglietto, Kavitha Krishnan, Gillian S. Dite, Jennifer Stone, Dallas R. English, Yun-Mi Song, Joohon Sung, Mark A. Jenkins, Melissa C. Southey, Graham G. Giles, John L. Hopper
Format: Article
Language:English
Published: BMC 2018-12-01
Series:Breast Cancer Research
Subjects:
Breast cancer
Masking effect
Interval cancer
Screen-detected
Nested case–control cohort study
Australian women
Online Access:http://link.springer.com/article/10.1186/s13058-018-1081-0
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spelling doaj-dcc39002bdf94bb79ab7e08a424b952f2021-04-02T10:08:13ZengBMCBreast Cancer Research1465-542X2018-12-0120111110.1186/s13058-018-1081-0Predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholdsTuong L. Nguyen0Ye K. Aung1Shuai Li2Nhut Ho Trinh3Christopher F. Evans4Laura Baglietto5Kavitha Krishnan6Gillian S. Dite7Jennifer Stone8Dallas R. English9Yun-Mi Song10Joohon Sung11Mark A. Jenkins12Melissa C. Southey13Graham G. Giles14John L. Hopper15Centre for Epidemiology and Biostatistics, The University of MelbourneCentre for Epidemiology and Biostatistics, The University of MelbourneCentre for Epidemiology and Biostatistics, The University of MelbourneCentre for Epidemiology and Biostatistics, The University of MelbourneCentre for Epidemiology and Biostatistics, The University of MelbourneCentre for Epidemiology and Biostatistics, The University of MelbourneCentre for Epidemiology and Biostatistics, The University of MelbourneCentre for Epidemiology and Biostatistics, The University of MelbourneCurtin UWA Centre for Genetic Origins of Health and Disease, Curtin University and the University of Western AustraliaCentre for Epidemiology and Biostatistics, The University of MelbourneDepartment of Family Medicine, Samsung Medical Center, Sungkyunkwan University School of MedicineDepartment of Epidemiology School of Public Health, Seoul National UniversityCentre for Epidemiology and Biostatistics, The University of MelbourneDepartment of Pathology, University of MelbourneCentre for Epidemiology and Biostatistics, The University of MelbourneCentre for Epidemiology and Biostatistics, The University of MelbourneAbstract Background Case–control studies show that mammographic density is a better risk factor when defined at higher than conventional pixel-brightness thresholds. We asked if this applied to interval and/or screen-detected cancers. Method We conducted a nested case–control study within the prospective Melbourne Collaborative Cohort Study including 168 women with interval and 422 with screen-detected breast cancers, and 498 and 1197 matched controls, respectively. We measured absolute and percent mammographic density using the Cumulus software at the conventional threshold (Cumulus) and two increasingly higher thresholds (Altocumulus and Cirrocumulus, respectively). Measures were transformed and adjusted for age and body mass index (BMI). Using conditional logistic regression and adjusting for BMI by age at mammogram, we estimated risk discrimination by the odds ratio per adjusted standard deviation (OPERA), calculated the area under the receiver operating characteristic curve (AUC) and compared nested models using the likelihood ratio criterion and models with the same number of parameters using the difference in Bayesian information criterion (ΔBIC). Results For interval cancer, there was very strong evidence that the association was best predicted by Cumulus as a percentage (OPERA = 2.33 (95% confidence interval (CI) 1.85–2.92); all ΔBIC > 14), and the association with BMI was independent of age at mammogram. After adjusting for percent Cumulus, no other measure was associated with risk (all P > 0.1). For screen-detected cancer, however, the associations were strongest for the absolute and percent Cirrocumulus measures (all ΔBIC > 6), and after adjusting for Cirrocumulus, no other measure was associated with risk (all P > 0.07). Conclusion The amount of brighter areas is the best mammogram-based measure of screen-detected breast cancer risk, while the percentage of the breast covered by white or bright areas is the best mammogram-based measure of interval breast cancer risk, irrespective of BMI. Therefore, there are different features of mammographic images that give clinically important information about different outcomes.http://link.springer.com/article/10.1186/s13058-018-1081-0Breast cancerMasking effectInterval cancerScreen-detectedNested case–control cohort studyAustralian women
collection DOAJ
language English
format Article
sources DOAJ
author Tuong L. Nguyen
Ye K. Aung
Shuai Li
Nhut Ho Trinh
Christopher F. Evans
Laura Baglietto
Kavitha Krishnan
Gillian S. Dite
Jennifer Stone
Dallas R. English
Yun-Mi Song
Joohon Sung
Mark A. Jenkins
Melissa C. Southey
Graham G. Giles
John L. Hopper
spellingShingle Tuong L. Nguyen
Ye K. Aung
Shuai Li
Nhut Ho Trinh
Christopher F. Evans
Laura Baglietto
Kavitha Krishnan
Gillian S. Dite
Jennifer Stone
Dallas R. English
Yun-Mi Song
Joohon Sung
Mark A. Jenkins
Melissa C. Southey
Graham G. Giles
John L. Hopper
Predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholds
Breast Cancer Research
Breast cancer
Masking effect
Interval cancer
Screen-detected
Nested case–control cohort study
Australian women
author_facet Tuong L. Nguyen
Ye K. Aung
Shuai Li
Nhut Ho Trinh
Christopher F. Evans
Laura Baglietto
Kavitha Krishnan
Gillian S. Dite
Jennifer Stone
Dallas R. English
Yun-Mi Song
Joohon Sung
Mark A. Jenkins
Melissa C. Southey
Graham G. Giles
John L. Hopper
author_sort Tuong L. Nguyen
title Predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholds
title_short Predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholds
title_full Predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholds
title_fullStr Predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholds
title_full_unstemmed Predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholds
title_sort predicting interval and screen-detected breast cancers from mammographic density defined by different brightness thresholds
publisher BMC
series Breast Cancer Research
issn 1465-542X
publishDate 2018-12-01
description Abstract Background Case–control studies show that mammographic density is a better risk factor when defined at higher than conventional pixel-brightness thresholds. We asked if this applied to interval and/or screen-detected cancers. Method We conducted a nested case–control study within the prospective Melbourne Collaborative Cohort Study including 168 women with interval and 422 with screen-detected breast cancers, and 498 and 1197 matched controls, respectively. We measured absolute and percent mammographic density using the Cumulus software at the conventional threshold (Cumulus) and two increasingly higher thresholds (Altocumulus and Cirrocumulus, respectively). Measures were transformed and adjusted for age and body mass index (BMI). Using conditional logistic regression and adjusting for BMI by age at mammogram, we estimated risk discrimination by the odds ratio per adjusted standard deviation (OPERA), calculated the area under the receiver operating characteristic curve (AUC) and compared nested models using the likelihood ratio criterion and models with the same number of parameters using the difference in Bayesian information criterion (ΔBIC). Results For interval cancer, there was very strong evidence that the association was best predicted by Cumulus as a percentage (OPERA = 2.33 (95% confidence interval (CI) 1.85–2.92); all ΔBIC > 14), and the association with BMI was independent of age at mammogram. After adjusting for percent Cumulus, no other measure was associated with risk (all P > 0.1). For screen-detected cancer, however, the associations were strongest for the absolute and percent Cirrocumulus measures (all ΔBIC > 6), and after adjusting for Cirrocumulus, no other measure was associated with risk (all P > 0.07). Conclusion The amount of brighter areas is the best mammogram-based measure of screen-detected breast cancer risk, while the percentage of the breast covered by white or bright areas is the best mammogram-based measure of interval breast cancer risk, irrespective of BMI. Therefore, there are different features of mammographic images that give clinically important information about different outcomes.
topic Breast cancer
Masking effect
Interval cancer
Screen-detected
Nested case–control cohort study
Australian women
url http://link.springer.com/article/10.1186/s13058-018-1081-0
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