V Shane Pankratz1, Amy C Degnim1, Ryan D Frank1, Marlene H Frost1, Daniel W Visscher1, Robert A Vierkant1, Tina J Hieken1, Karthik Ghosh1, Yaman Tarabishy1, Celine M Vachon1, Derek C Radisky1, Lynn C Hartmann2. 1. V. Shane Pankratz, University of New Mexico Health Sciences Center, Albuquerque, NM; Amy C. Degnim, Ryan D. Frank, Marlene H. Frost, Daniel W. Visscher, Robert A. Vierkant, Tina J. Hieken, Karthik Ghosh, Celine M. Vachon, and Lynn C. Hartmann, Mayo Clinic, Rochester, MN; Yaman Tarabishy, Washington University, St Louis, St Louis, MO; and Derek C. Radisky, Mayo Clinic, Jacksonville, FL. 2. V. Shane Pankratz, University of New Mexico Health Sciences Center, Albuquerque, NM; Amy C. Degnim, Ryan D. Frank, Marlene H. Frost, Daniel W. Visscher, Robert A. Vierkant, Tina J. Hieken, Karthik Ghosh, Celine M. Vachon, and Lynn C. Hartmann, Mayo Clinic, Rochester, MN; Yaman Tarabishy, Washington University, St Louis, St Louis, MO; and Derek C. Radisky, Mayo Clinic, Jacksonville, FL. hartmann.lynn@mayo.edu.
Abstract
PURPOSE: Optimal early detection and prevention for breast cancer depend on accurate identification of women at increased risk. We present a risk prediction model that incorporates histologic features of biopsy tissues from women with benign breast disease (BBD) and compare its performance to the Breast Cancer Risk Assessment Tool (BCRAT). METHODS: We estimated the age-specific incidence of breast cancer and death from the Mayo BBD cohort and then combined these estimates with a relative risk model derived from 377 patient cases with breast cancer and 734 matched controls sampled from the Mayo BBD cohort to develop the BBD-to-breast cancer (BBD-BC) risk assessment tool. We validated the model using an independent set of 378 patient cases with breast cancer and 728 matched controls from the Mayo BBD cohort and compared the risk predictions from our model with those from the BCRAT. RESULTS: The BBD-BC model predicts the probability of breast cancer in women with BBD using tissue-based and other risk factors. The concordance statistic from the BBD-BC model was 0.665 in the model development series and 0.629 in the validation series; these values were higher than those from the BCRAT (0.567 and 0.472, respectively). The BCRAT significantly underpredicted breast cancer risk after benign biopsy (P = .004), whereas the BBD-BC predictions were appropriately calibrated to observed cancers (P = .247). CONCLUSION: We developed a model using both demographic and histologic features to predict breast cancer risk in women with BBD. Our model more accurately classifies a woman's breast cancer risk after a benign biopsy than the BCRAT.
PURPOSE: Optimal early detection and prevention for breast cancer depend on accurate identification of women at increased risk. We present a risk prediction model that incorporates histologic features of biopsy tissues from women with benign breast disease (BBD) and compare its performance to the Breast Cancer Risk Assessment Tool (BCRAT). METHODS: We estimated the age-specific incidence of breast cancer and death from the Mayo BBD cohort and then combined these estimates with a relative risk model derived from 377 patient cases with breast cancer and 734 matched controls sampled from the Mayo BBD cohort to develop the BBD-to-breast cancer (BBD-BC) risk assessment tool. We validated the model using an independent set of 378 patient cases with breast cancer and 728 matched controls from the Mayo BBD cohort and compared the risk predictions from our model with those from the BCRAT. RESULTS: The BBD-BC model predicts the probability of breast cancer in women with BBD using tissue-based and other risk factors. The concordance statistic from the BBD-BC model was 0.665 in the model development series and 0.629 in the validation series; these values were higher than those from the BCRAT (0.567 and 0.472, respectively). The BCRAT significantly underpredicted breast cancer risk after benign biopsy (P = .004), whereas the BBD-BC predictions were appropriately calibrated to observed cancers (P = .247). CONCLUSION: We developed a model using both demographic and histologic features to predict breast cancer risk in women with BBD. Our model more accurately classifies a woman's breast cancer risk after a benign biopsy than the BCRAT.
Authors: Tia R Milanese; Lynn C Hartmann; Thomas A Sellers; Marlene H Frost; Robert A Vierkant; Shaun D Maloney; V Shane Pankratz; Amy C Degnim; Celine M Vachon; Carol A Reynolds; Romayne A Thompson; L Joseph Melton; Ellen L Goode; Daniel W Visscher Journal: J Natl Cancer Inst Date: 2006-11-15 Impact factor: 13.506
Authors: Luke G Gutwein; Darwin N Ang; Huazhi Liu; Julia K Marshall; Steven N Hochwald; Edward M Copeland; Stephen R Grobmyer Journal: Am J Surg Date: 2011-02-03 Impact factor: 2.565
Authors: Judy C Boughey; Lynn C Hartmann; Stephanie S Anderson; Amy C Degnim; Robert A Vierkant; Carol A Reynolds; Marlene H Frost; V Shane Pankratz Journal: J Clin Oncol Date: 2010-07-06 Impact factor: 44.544
Authors: V Shane Pankratz; Lynn C Hartmann; Amy C Degnim; Robert A Vierkant; Karthik Ghosh; Celine M Vachon; Marlene H Frost; Shaun D Maloney; Carol Reynolds; Judy C Boughey Journal: J Clin Oncol Date: 2008-10-14 Impact factor: 44.544
Authors: Jeffrey A Tice; Steven R Cummings; Rebecca Smith-Bindman; Laura Ichikawa; William E Barlow; Karla Kerlikowske Journal: Ann Intern Med Date: 2008-03-04 Impact factor: 25.391
Authors: Kevin P McKian; Carol A Reynolds; Daniel W Visscher; Aziza Nassar; Derek C Radisky; Robert A Vierkant; Amy C Degnim; Judy C Boughey; Karthik Ghosh; Stephanie S Anderson; Douglas Minot; Jill L Caudill; Celine M Vachon; Marlene H Frost; V Shane Pankratz; Lynn C Hartmann Journal: J Clin Oncol Date: 2009-10-05 Impact factor: 44.544
Authors: Kathleen F Kerr; Zheyu Wang; Holly Janes; Robyn L McClelland; Bruce M Psaty; Margaret S Pepe Journal: Epidemiology Date: 2014-01 Impact factor: 4.822
Authors: Matthew E Mealiffe; Renee P Stokowski; Brian K Rhees; Ross L Prentice; Mary Pettinger; David A Hinds Journal: J Natl Cancer Inst Date: 2010-10-18 Impact factor: 13.506
Authors: Tina J Hieken; Jodi M Carter; John R Hawse; Tanya L Hoskin; Melanie Bois; Marlene Frost; Lynn C Hartmann; Derek C Radisky; Daniel W Visscher; Amy C Degnim Journal: Cancer Prev Res (Phila) Date: 2015-08-14
Authors: Zexian Zeng; Andy Vo; Xiaoyu Li; Ali Shidfar; Paulette Saldana; Luis Blanco; Xiaoling Xuei; Yuan Luo; Seema A Khan; Susan E Clare Journal: NPJ Breast Cancer Date: 2020-06-12
Authors: Daniel W Visscher; Marlene H Frost; Lynn C Hartmann; Ryan D Frank; Robert A Vierkant; Ann E McCullough; Stacey J Winham; Celine M Vachon; Karthik Ghosh; Kathleen R Brandt; Ann M Farrell; Yaman Tarabishy; Tina J Hieken; Tufia C Haddad; Ruth A Kraft; Derek C Radisky; Amy C Degnim Journal: Cancer Date: 2015-10-29 Impact factor: 6.860
Authors: Jonine D Figueroa; Ruth M Pfeiffer; Louise A Brinton; Maya M Palakal; Amy C Degnim; Derek Radisky; Lynn C Hartmann; Marlene H Frost; Melody L Stallings Mann; Daphne Papathomas; Gretchen L Gierach; Stephen M Hewitt; Maire A Duggan; Daniel Visscher; Mark E Sherman Journal: Breast Cancer Res Treat Date: 2016-08-03 Impact factor: 4.872
Authors: Amy C Degnim; Stacey J Winham; Ryan D Frank; V Shane Pankratz; William D Dupont; Robert A Vierkant; Marlene H Frost; Tanya L Hoskin; Celine M Vachon; Karthik Ghosh; Tina J Hieken; Jodi M Carter; Lori A Denison; Brendan Broderick; Lynn C Hartmann; Daniel W Visscher; Derek C Radisky Journal: J Clin Oncol Date: 2018-04-20 Impact factor: 44.544
Authors: Jeffrey A Tice; Diana L Miglioretti; Chin-Shang Li; Celine M Vachon; Charlotte C Gard; Karla Kerlikowske Journal: J Clin Oncol Date: 2015-08-17 Impact factor: 44.544