Development of a Machine Learning Model for Predicting Treatment-Related Amenorrhea in Young Women with Breast Cancer

Long Song; Zobaida Edib; Uwe Aickelin; Hadi Akbarzadeh Khorshidi; Anne Sophie Hamy; Yasmin Jayasinghe; Martha Hickey; Richard A. Anderson; Matteo Lambertini; Margherita Condorelli; Isabelle Demeestere; Michail Ignatiadis; Barbara Pistilli; H. Irene Su; Shanton Chang; Patrick Cheong Iao Pang; Fabien Reyal; Scott M. Nelson; Paniti Sukumvanich; Alessandro Minisini; Fabio Puglisi; Kathryn J. Ruddy; Fergus J. Couch; Janet E. Olson; Kate Stern; Franca Agresta; Lesley Stafford; Laura Chin-Lenn; Wanda Cui; Antoinette Anazodo; Alexandra Gorelik; Tuong L. Nguyen; Ann Partridge; Christobel Saunders; Elizabeth Sullivan; Mary Macheras-Magias; Michelle Peate

doi:10.3390/bioengineering12111171

Development of a Machine Learning Model for Predicting Treatment-Related Amenorrhea in Young Women with Breast Cancer

Long Song
, Zobaida Edib
, Uwe Aickelin
, Hadi Akbarzadeh Khorshidi
, Anne Sophie Hamy
, Yasmin Jayasinghe
, Martha Hickey
, Richard A. Anderson
, Matteo Lambertini
, Margherita Condorelli
, Isabelle Demeestere
, Michail Ignatiadis
, Barbara Pistilli
, H. Irene Su
, Shanton Chang
, Patrick Cheong Iao Pang
, Fabien Reyal
, Scott M. Nelson
, Paniti Sukumvanich
, Alessandro Minisini

Fabio Puglisi, Kathryn J. Ruddy, Fergus J. Couch, Janet E. Olson, Kate Stern, Franca Agresta, Lesley Stafford, Laura Chin-Lenn, Wanda Cui, Antoinette Anazodo, Alexandra Gorelik, Tuong L. Nguyen, Ann Partridge, Christobel Saunders, Elizabeth Sullivan, Mary Macheras-Magias, Michelle Peate

Faculty of Applied Sciences

School of Computing and Information Systems
University of Melbourne
Royal Women's Hospital
Institut Curie
Royal Children's Hospital Melbourne
Murdoch Children's Research Institute
University of Edinburgh
IRCCS Ospedale Policlinico San Martino
University of Genoa
Université libre de Bruxelles
UNICANCER Federation
University of California at San Diego
University of Glasgow
University of Pittsburgh
Azienda Sanitaria Universitaria Friuli Centrale
Mayo Clinic Scottsdale, AZ
Melbourne IVF
Royal Melbourne Hospital
Peter Maccallum Cancer Centre
Sydney Children's Hospital
University of New South Wales
Monash University
Dana-Farber Cancer Institute
University of Newcastle
Breast Cancer Network Australia

研究成果: Article › 同行評審

摘要

Treatment-induced ovarian function loss is a significant concern for many young patients with breast cancer. Accurately predicting this risk is crucial for counselling young patients and informing their fertility-related decision-making. However, current risk prediction models for treatment-related ovarian function loss have limitations. To provide a broader representation of patient cohorts and improve feature selection, we combined retrospective data from six datasets within the FoRECAsT (Infertility after Cancer Predictor) databank, including 2679 pre-menopausal women diagnosed with breast cancer. This combined dataset presented notable missingness, prompting us to employ cross imputation using the k-nearest neighbours (KNN) machine learning (ML) algorithm. Employing Lasso regression, we developed an ML model to forecast the risk of treatment-related amenorrhea as a surrogate marker of ovarian function loss at 12 months after starting chemotherapy. Our model identified 20 variables significantly associated with risk of developing amenorrhea. Internal validation resulted in an area under the receiver operating characteristic curve (AUC) of 0.820 (95% CI: 0.817–0.823), while external validation with another dataset demonstrated an AUC of 0.743 (95% CI: 0.666–0.818). A cutoff of 0.20 was chosen to achieve higher sensitivity in validation, as false negatives—patients incorrectly classified as likely to regain menses—could miss timely opportunities for fertility preservation if desired. At this threshold, internal validation yielded sensitivity and precision rates of 91.3% and 61.7%, respectively, while external validation showed 92.9% and 60.0%. Leveraging ML methodologies, we not only devised a model for personalised risk prediction of amenorrhea, demonstrating substantial enhancements over existing models but also showcased a robust framework for maximally harnessing available data sources.

原文	English
文章編號	1171
期刊	Bioengineering
卷	12
發行號	11
DOIs	https://doi.org/10.3390/bioengineering12111171
出版狀態	Published - 11月 2025

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10.3390/bioengineering12111171

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Song, L., Edib, Z., Aickelin, U., Akbarzadeh Khorshidi, H., Hamy, A. S., Jayasinghe, Y., Hickey, M., Anderson, R. A., Lambertini, M., Condorelli, M., Demeestere, I., Ignatiadis, M., Pistilli, B., Su, H. I., Chang, S., Pang, P. C. I., Reyal, F., Nelson, S. M., Sukumvanich, P., ... Peate, M. (2025). Development of a Machine Learning Model for Predicting Treatment-Related Amenorrhea in Young Women with Breast Cancer. Bioengineering, 12(11), 文章 1171. https://doi.org/10.3390/bioengineering12111171

@article{8f436bc662ad4330b0a9587c21f1e13e,

title = "Development of a Machine Learning Model for Predicting Treatment-Related Amenorrhea in Young Women with Breast Cancer",

abstract = "Treatment-induced ovarian function loss is a significant concern for many young patients with breast cancer. Accurately predicting this risk is crucial for counselling young patients and informing their fertility-related decision-making. However, current risk prediction models for treatment-related ovarian function loss have limitations. To provide a broader representation of patient cohorts and improve feature selection, we combined retrospective data from six datasets within the FoRECAsT (Infertility after Cancer Predictor) databank, including 2679 pre-menopausal women diagnosed with breast cancer. This combined dataset presented notable missingness, prompting us to employ cross imputation using the k-nearest neighbours (KNN) machine learning (ML) algorithm. Employing Lasso regression, we developed an ML model to forecast the risk of treatment-related amenorrhea as a surrogate marker of ovarian function loss at 12 months after starting chemotherapy. Our model identified 20 variables significantly associated with risk of developing amenorrhea. Internal validation resulted in an area under the receiver operating characteristic curve (AUC) of 0.820 (95\% CI: 0.817–0.823), while external validation with another dataset demonstrated an AUC of 0.743 (95\% CI: 0.666–0.818). A cutoff of 0.20 was chosen to achieve higher sensitivity in validation, as false negatives—patients incorrectly classified as likely to regain menses—could miss timely opportunities for fertility preservation if desired. At this threshold, internal validation yielded sensitivity and precision rates of 91.3\% and 61.7\%, respectively, while external validation showed 92.9\% and 60.0\%. Leveraging ML methodologies, we not only devised a model for personalised risk prediction of amenorrhea, demonstrating substantial enhancements over existing models but also showcased a robust framework for maximally harnessing available data sources.",

keywords = "breast cancer, cross imputation, machine learning, risk prediction model, treatment-related amenorrhea",

author = "Long Song and Zobaida Edib and Uwe Aickelin and \{Akbarzadeh Khorshidi\}, Hadi and Hamy, \{Anne Sophie\} and Yasmin Jayasinghe and Martha Hickey and Anderson, \{Richard A.\} and Matteo Lambertini and Margherita Condorelli and Isabelle Demeestere and Michail Ignatiadis and Barbara Pistilli and Su, \{H. Irene\} and Shanton Chang and Pang, \{Patrick Cheong Iao\} and Fabien Reyal and Nelson, \{Scott M.\} and Paniti Sukumvanich and Alessandro Minisini and Fabio Puglisi and Ruddy, \{Kathryn J.\} and Couch, \{Fergus J.\} and Olson, \{Janet E.\} and Kate Stern and Franca Agresta and Lesley Stafford and Laura Chin-Lenn and Wanda Cui and Antoinette Anazodo and Alexandra Gorelik and Nguyen, \{Tuong L.\} and Ann Partridge and Christobel Saunders and Elizabeth Sullivan and Mary Macheras-Magias and Michelle Peate",

note = "Publisher Copyright: {\textcopyright} 2025 by the authors.",

year = "2025",

month = nov,

doi = "10.3390/bioengineering12111171",

language = "English",

volume = "12",

journal = "Bioengineering",

issn = "2306-5354",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "11",

}

Song, L, Edib, Z, Aickelin, U, Akbarzadeh Khorshidi, H, Hamy, AS, Jayasinghe, Y, Hickey, M, Anderson, RA, Lambertini, M, Condorelli, M, Demeestere, I, Ignatiadis, M, Pistilli, B, Su, HI, Chang, S, Pang, PCI, Reyal, F, Nelson, SM, Sukumvanich, P, Minisini, A, Puglisi, F, Ruddy, KJ, Couch, FJ, Olson, JE, Stern, K, Agresta, F, Stafford, L, Chin-Lenn, L, Cui, W, Anazodo, A, Gorelik, A, Nguyen, TL, Partridge, A, Saunders, C, Sullivan, E, Macheras-Magias, M & Peate, M 2025, 'Development of a Machine Learning Model for Predicting Treatment-Related Amenorrhea in Young Women with Breast Cancer', Bioengineering, 卷 12, 編號 11, 1171. https://doi.org/10.3390/bioengineering12111171

TY - JOUR

T1 - Development of a Machine Learning Model for Predicting Treatment-Related Amenorrhea in Young Women with Breast Cancer

AU - Song, Long

AU - Edib, Zobaida

AU - Aickelin, Uwe

AU - Akbarzadeh Khorshidi, Hadi

AU - Hamy, Anne Sophie

AU - Jayasinghe, Yasmin

AU - Hickey, Martha

AU - Anderson, Richard A.

AU - Lambertini, Matteo

AU - Condorelli, Margherita

AU - Demeestere, Isabelle

AU - Ignatiadis, Michail

AU - Pistilli, Barbara

AU - Su, H. Irene

AU - Chang, Shanton

AU - Pang, Patrick Cheong Iao

AU - Reyal, Fabien

AU - Nelson, Scott M.

AU - Sukumvanich, Paniti

AU - Minisini, Alessandro

AU - Puglisi, Fabio

AU - Ruddy, Kathryn J.

AU - Couch, Fergus J.

AU - Olson, Janet E.

AU - Stern, Kate

AU - Agresta, Franca

AU - Stafford, Lesley

AU - Chin-Lenn, Laura

AU - Cui, Wanda

AU - Anazodo, Antoinette

AU - Gorelik, Alexandra

AU - Nguyen, Tuong L.

AU - Partridge, Ann

AU - Saunders, Christobel

AU - Sullivan, Elizabeth

AU - Macheras-Magias, Mary

AU - Peate, Michelle

PY - 2025/11

Y1 - 2025/11

N2 - Treatment-induced ovarian function loss is a significant concern for many young patients with breast cancer. Accurately predicting this risk is crucial for counselling young patients and informing their fertility-related decision-making. However, current risk prediction models for treatment-related ovarian function loss have limitations. To provide a broader representation of patient cohorts and improve feature selection, we combined retrospective data from six datasets within the FoRECAsT (Infertility after Cancer Predictor) databank, including 2679 pre-menopausal women diagnosed with breast cancer. This combined dataset presented notable missingness, prompting us to employ cross imputation using the k-nearest neighbours (KNN) machine learning (ML) algorithm. Employing Lasso regression, we developed an ML model to forecast the risk of treatment-related amenorrhea as a surrogate marker of ovarian function loss at 12 months after starting chemotherapy. Our model identified 20 variables significantly associated with risk of developing amenorrhea. Internal validation resulted in an area under the receiver operating characteristic curve (AUC) of 0.820 (95% CI: 0.817–0.823), while external validation with another dataset demonstrated an AUC of 0.743 (95% CI: 0.666–0.818). A cutoff of 0.20 was chosen to achieve higher sensitivity in validation, as false negatives—patients incorrectly classified as likely to regain menses—could miss timely opportunities for fertility preservation if desired. At this threshold, internal validation yielded sensitivity and precision rates of 91.3% and 61.7%, respectively, while external validation showed 92.9% and 60.0%. Leveraging ML methodologies, we not only devised a model for personalised risk prediction of amenorrhea, demonstrating substantial enhancements over existing models but also showcased a robust framework for maximally harnessing available data sources.

AB - Treatment-induced ovarian function loss is a significant concern for many young patients with breast cancer. Accurately predicting this risk is crucial for counselling young patients and informing their fertility-related decision-making. However, current risk prediction models for treatment-related ovarian function loss have limitations. To provide a broader representation of patient cohorts and improve feature selection, we combined retrospective data from six datasets within the FoRECAsT (Infertility after Cancer Predictor) databank, including 2679 pre-menopausal women diagnosed with breast cancer. This combined dataset presented notable missingness, prompting us to employ cross imputation using the k-nearest neighbours (KNN) machine learning (ML) algorithm. Employing Lasso regression, we developed an ML model to forecast the risk of treatment-related amenorrhea as a surrogate marker of ovarian function loss at 12 months after starting chemotherapy. Our model identified 20 variables significantly associated with risk of developing amenorrhea. Internal validation resulted in an area under the receiver operating characteristic curve (AUC) of 0.820 (95% CI: 0.817–0.823), while external validation with another dataset demonstrated an AUC of 0.743 (95% CI: 0.666–0.818). A cutoff of 0.20 was chosen to achieve higher sensitivity in validation, as false negatives—patients incorrectly classified as likely to regain menses—could miss timely opportunities for fertility preservation if desired. At this threshold, internal validation yielded sensitivity and precision rates of 91.3% and 61.7%, respectively, while external validation showed 92.9% and 60.0%. Leveraging ML methodologies, we not only devised a model for personalised risk prediction of amenorrhea, demonstrating substantial enhancements over existing models but also showcased a robust framework for maximally harnessing available data sources.

KW - breast cancer

KW - cross imputation

KW - machine learning

KW - risk prediction model

KW - treatment-related amenorrhea

UR - https://www.scopus.com/pages/publications/105023448012

U2 - 10.3390/bioengineering12111171

DO - 10.3390/bioengineering12111171

M3 - Article

AN - SCOPUS:105023448012

SN - 2306-5354

VL - 12

JO - Bioengineering

JF - Bioengineering

IS - 11

M1 - 1171

ER -

Development of a Machine Learning Model for Predicting Treatment-Related Amenorrhea in Young Women with Breast Cancer

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