Predicting short- to long-term breast cancer risk from longitudinal mammographic screening history

Xin Wang; Tao Tan; Yuan Gao; Ruisheng Su; Jonas Teuwen; Jaap Kroes; Tianyu Zhang; Anna D’Angelo; Luyi Han; Caroline A. Drukker; Marjanka K. Schmidt; Regina Beets-Tan; Nico Karssemeijer; Ritse Mann

doi:10.1038/s41523-025-00831-x

Predicting short- to long-term breast cancer risk from longitudinal mammographic screening history

Xin Wang, Tao Tan, Yuan Gao, Ruisheng Su, Jonas Teuwen, Jaap Kroes, Tianyu Zhang, Anna D’Angelo, Luyi Han, Caroline A. Drukker, Marjanka K. Schmidt, Regina Beets-Tan, Nico Karssemeijer, Ritse Mann

Faculty of Applied Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

Breast cancer (BC) risk assessment aims to enhance individualized screening and prevention strategies. While recent deep learning (DL) models based on mammography have shown promise in short-term risk prediction, they primarily rely on single-time-point (STP) exams, ignoring temporal changes in breast tissue from sequence exams. We present the Multi-Time Point Breast Cancer Risk Model (MTP-BCR), a novel DL approach that integrates traditional risk factors and longitudinal mammography data to capture subtle tissue changes indicative of future malignancy. Using a large in-house dataset with 171,168 mammograms from 9133 women, MTP-BCR achieved superior performance in 10-year risk prediction, with an AUC of 0.80 (95% CI, 0.78–0.82) at the patient level, outperforming STP-based and traditional risk models. External validation on the CSAW-CC dataset confirmed its robustness. Further analysis demonstrates the advantages of the MTP-BCR method in diverse populations. MTP-BCR also excels in risk stratification and offers heatmaps to enhance clinical interpretability.

Original language	English
Article number	118
Journal	npj Breast Cancer
Volume	11
Issue number	1
DOIs	https://doi.org/10.1038/s41523-025-00831-x
Publication status	Published - Dec 2025

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title = "Predicting short- to long-term breast cancer risk from longitudinal mammographic screening history",

abstract = "Breast cancer (BC) risk assessment aims to enhance individualized screening and prevention strategies. While recent deep learning (DL) models based on mammography have shown promise in short-term risk prediction, they primarily rely on single-time-point (STP) exams, ignoring temporal changes in breast tissue from sequence exams. We present the Multi-Time Point Breast Cancer Risk Model (MTP-BCR), a novel DL approach that integrates traditional risk factors and longitudinal mammography data to capture subtle tissue changes indicative of future malignancy. Using a large in-house dataset with 171,168 mammograms from 9133 women, MTP-BCR achieved superior performance in 10-year risk prediction, with an AUC of 0.80 (95\% CI, 0.78–0.82) at the patient level, outperforming STP-based and traditional risk models. External validation on the CSAW-CC dataset confirmed its robustness. Further analysis demonstrates the advantages of the MTP-BCR method in diverse populations. MTP-BCR also excels in risk stratification and offers heatmaps to enhance clinical interpretability.",

author = "Xin Wang and Tao Tan and Yuan Gao and Ruisheng Su and Jonas Teuwen and Jaap Kroes and Tianyu Zhang and Anna D{\textquoteright}Angelo and Luyi Han and Drukker, \{Caroline A.\} and Schmidt, \{Marjanka K.\} and Regina Beets-Tan and Nico Karssemeijer and Ritse Mann",

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month = dec,

doi = "10.1038/s41523-025-00831-x",

language = "English",

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AU - Wang, Xin

AU - Tan, Tao

AU - Gao, Yuan

AU - Su, Ruisheng

AU - Teuwen, Jonas

AU - Kroes, Jaap

AU - Zhang, Tianyu

AU - D’Angelo, Anna

AU - Han, Luyi

AU - Drukker, Caroline A.

AU - Schmidt, Marjanka K.

AU - Beets-Tan, Regina

AU - Karssemeijer, Nico

AU - Mann, Ritse

PY - 2025/12

Y1 - 2025/12

N2 - Breast cancer (BC) risk assessment aims to enhance individualized screening and prevention strategies. While recent deep learning (DL) models based on mammography have shown promise in short-term risk prediction, they primarily rely on single-time-point (STP) exams, ignoring temporal changes in breast tissue from sequence exams. We present the Multi-Time Point Breast Cancer Risk Model (MTP-BCR), a novel DL approach that integrates traditional risk factors and longitudinal mammography data to capture subtle tissue changes indicative of future malignancy. Using a large in-house dataset with 171,168 mammograms from 9133 women, MTP-BCR achieved superior performance in 10-year risk prediction, with an AUC of 0.80 (95% CI, 0.78–0.82) at the patient level, outperforming STP-based and traditional risk models. External validation on the CSAW-CC dataset confirmed its robustness. Further analysis demonstrates the advantages of the MTP-BCR method in diverse populations. MTP-BCR also excels in risk stratification and offers heatmaps to enhance clinical interpretability.

AB - Breast cancer (BC) risk assessment aims to enhance individualized screening and prevention strategies. While recent deep learning (DL) models based on mammography have shown promise in short-term risk prediction, they primarily rely on single-time-point (STP) exams, ignoring temporal changes in breast tissue from sequence exams. We present the Multi-Time Point Breast Cancer Risk Model (MTP-BCR), a novel DL approach that integrates traditional risk factors and longitudinal mammography data to capture subtle tissue changes indicative of future malignancy. Using a large in-house dataset with 171,168 mammograms from 9133 women, MTP-BCR achieved superior performance in 10-year risk prediction, with an AUC of 0.80 (95% CI, 0.78–0.82) at the patient level, outperforming STP-based and traditional risk models. External validation on the CSAW-CC dataset confirmed its robustness. Further analysis demonstrates the advantages of the MTP-BCR method in diverse populations. MTP-BCR also excels in risk stratification and offers heatmaps to enhance clinical interpretability.

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DO - 10.1038/s41523-025-00831-x

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JO - npj Breast Cancer

JF - npj Breast Cancer

IS - 1

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ER -

Predicting short- to long-term breast cancer risk from longitudinal mammographic screening history

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