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Autores principales: Alamu, Opeyemi Sheu, Choque, Bismar Jorge Gutierrez, Rizvi, Syed Wajeeh Abbs, Hammed, Samah Badr, Medani, Isameldin Elamin, Siam, Md Kamrul, Tahir, Waqar Ahmad
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2410.13404
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author Alamu, Opeyemi Sheu
Choque, Bismar Jorge Gutierrez
Rizvi, Syed Wajeeh Abbs
Hammed, Samah Badr
Medani, Isameldin Elamin
Siam, Md Kamrul
Tahir, Waqar Ahmad
author_facet Alamu, Opeyemi Sheu
Choque, Bismar Jorge Gutierrez
Rizvi, Syed Wajeeh Abbs
Hammed, Samah Badr
Medani, Isameldin Elamin
Siam, Md Kamrul
Tahir, Waqar Ahmad
contents Breast cancer remains a significant global health challenge, with prognosis and treatment decisions largely dependent on clinical characteristics. Accurate prediction of patient outcomes is crucial for personalized treatment strategies. This study employs survival analysis techniques, including Cox proportional hazards and parametric survival models, to enhance the prediction of the log odds of survival in breast cancer patients. Clinical variables such as tumor size, hormone receptor status, HER2 status, age, and treatment history were analyzed to assess their impact on survival outcomes. Data from 1557 breast cancer patients were obtained from a publicly available dataset provided by the University College Hospital, Ibadan, Nigeria. This dataset was preprocessed and analyzed using both univariate and multivariate approaches to evaluate survival outcomes. Kaplan-Meier survival curves were generated to visualize survival probabilities, while the Cox proportional hazards model identified key risk factors influencing mortality. The results showed that older age, larger tumor size, and HER2-positive status were significantly associated with an increased risk of mortality. In contrast, estrogen receptor positivity and breast-conserving surgery were linked to better survival outcomes. The findings suggest that integrating these clinical variables into predictive models improvesthe accuracy of survival predictions, helping to identify high-risk patients who may benefit from more aggressive interventions. This study demonstrates the potential of survival analysis in optimizing breast cancer care, particularly in resource-limited settings. Future research should focus on integrating genomic data and real-world clinical outcomes to further refine these models.
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publishDate 2024
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spellingShingle Predicting Breast Cancer Survival: A Survival Analysis Approach Using Log Odds and Clinical Variables
Alamu, Opeyemi Sheu
Choque, Bismar Jorge Gutierrez
Rizvi, Syed Wajeeh Abbs
Hammed, Samah Badr
Medani, Isameldin Elamin
Siam, Md Kamrul
Tahir, Waqar Ahmad
Machine Learning
Breast cancer remains a significant global health challenge, with prognosis and treatment decisions largely dependent on clinical characteristics. Accurate prediction of patient outcomes is crucial for personalized treatment strategies. This study employs survival analysis techniques, including Cox proportional hazards and parametric survival models, to enhance the prediction of the log odds of survival in breast cancer patients. Clinical variables such as tumor size, hormone receptor status, HER2 status, age, and treatment history were analyzed to assess their impact on survival outcomes. Data from 1557 breast cancer patients were obtained from a publicly available dataset provided by the University College Hospital, Ibadan, Nigeria. This dataset was preprocessed and analyzed using both univariate and multivariate approaches to evaluate survival outcomes. Kaplan-Meier survival curves were generated to visualize survival probabilities, while the Cox proportional hazards model identified key risk factors influencing mortality. The results showed that older age, larger tumor size, and HER2-positive status were significantly associated with an increased risk of mortality. In contrast, estrogen receptor positivity and breast-conserving surgery were linked to better survival outcomes. The findings suggest that integrating these clinical variables into predictive models improvesthe accuracy of survival predictions, helping to identify high-risk patients who may benefit from more aggressive interventions. This study demonstrates the potential of survival analysis in optimizing breast cancer care, particularly in resource-limited settings. Future research should focus on integrating genomic data and real-world clinical outcomes to further refine these models.
title Predicting Breast Cancer Survival: A Survival Analysis Approach Using Log Odds and Clinical Variables
topic Machine Learning
url https://arxiv.org/abs/2410.13404