Learning competing risks across multiple hospitals: one-shot distributed algorithms

Dazheng Zhang; Jiayi Tong; Naimin Jing; Yuchen Yang; Chongliang Luo; Yiwen Lu; Dimitri A. Christakis; Diana Güthe; Mady Hornig; Kelly J. Kelleher; Keith E. Morse; Colin M. Rogerson; Jasmin Divers; Raymond J. Carroll; Christopher B. Forrest; Yong Chen

doi:10.1093/jamia/ocae027

Learning competing risks across multiple hospitals: one-shot distributed algorithms

Dazheng Zhang, Jiayi Tong, Naimin Jing, Yuchen Yang, Chongliang Luo, Yiwen Lu, Dimitri A. Christakis, Diana Güthe, Mady Hornig, Kelly J. Kelleher, Keith E. Morse, Colin M. Rogerson, Jasmin Divers, Raymond J. Carroll, Christopher B. Forrest, Yong Chen

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

5 Scopus citations

Abstract

Objectives: To characterize the complex interplay between multiple clinical conditions in a time-to-event analysis framework using data from multiple hospitals, we developed two novel one-shot distributed algorithms for competing risk models (ODACoR). By applying our algorithms to the EHR data from eight national children’s hospitals, we quantified the impacts of a wide range of risk factors on the risk of post-acute sequelae of SARS-COV-2 (PASC) among children and adolescents.

Materials and Methods: Our ODACoR algorithms are effectively executed due to their devised simplicity and communication efficiency. We evaluated our algorithms via extensive simulation studies as applications to quantification of the impacts of risk factors for PASC among children and adolescents using data from eight children’s hospitals including the Children’s Hospital of Philadelphia, Cincinnati Children’s Hospital Medical Center, Children’s Hospital of Colorado covering over 6.5 million pediatric patients. The accuracy of the estimation was assessed by comparing the results from our ODACoR algorithms with the estimators derived from the meta-analysis and the pooled data.

Results: The meta-analysis estimator showed a high relative bias (∼40%) when the clinical condition is relatively rare (∼0.5%), whereas ODACoR algorithms exhibited a substantially lower relative bias (∼0.2%). The estimated effects from our ODACoR algorithms were identical on par with the estimates from the pooled data, suggesting the high reliability of our federated learning algorithms. In contrast, the meta-analysis estimate failed to identify risk factors such as age, gender, chronic conditions history, and obesity, compared to the pooled data.

Discussion: Our proposed ODACoR algorithms are communication-efficient, highly accurate, and suitable to characterize the complex interplay between multiple clinical conditions.

Conclusion: Our study demonstrates that our ODACoR algorithms are communication-efficient and can be widely applicable for analyzing multiple clinical conditions in a time-to-event analysis framework.

Original language	English
Pages (from-to)	1102-1112
Number of pages	11
Journal	Journal of the American Medical Informatics Association
Volume	31
Issue number	5
DOIs	https://doi.org/10.1093/jamia/ocae027
State	Published - May 1 2024

Keywords

communication-efficient
competing risk model
distributed research network
federated learning
one-shot distributed algorithm

Access to Document

10.1093/jamia/ocae027

Cite this

Zhang, D., Tong, J., Jing, N., Yang, Y., Luo, C., Lu, Y., Christakis, D. A., Güthe, D., Hornig, M., Kelleher, K. J., Morse, K. E., Rogerson, C. M., Divers, J., Carroll, R. J., Forrest, C. B., & Chen, Y. (2024). Learning competing risks across multiple hospitals: one-shot distributed algorithms. Journal of the American Medical Informatics Association, 31(5), 1102-1112. https://doi.org/10.1093/jamia/ocae027

@article{4edabb7bea914d7fb1ed97f929752a23,

title = "Learning competing risks across multiple hospitals: one-shot distributed algorithms",

abstract = "Objectives: To characterize the complex interplay between multiple clinical conditions in a time-to-event analysis framework using data from multiple hospitals, we developed two novel one-shot distributed algorithms for competing risk models (ODACoR). By applying our algorithms to the EHR data from eight national children{\textquoteright}s hospitals, we quantified the impacts of a wide range of risk factors on the risk of post-acute sequelae of SARS-COV-2 (PASC) among children and adolescents.Materials and Methods: Our ODACoR algorithms are effectively executed due to their devised simplicity and communication efficiency. We evaluated our algorithms via extensive simulation studies as applications to quantification of the impacts of risk factors for PASC among children and adolescents using data from eight children{\textquoteright}s hospitals including the Children{\textquoteright}s Hospital of Philadelphia, Cincinnati Children{\textquoteright}s Hospital Medical Center, Children{\textquoteright}s Hospital of Colorado covering over 6.5 million pediatric patients. The accuracy of the estimation was assessed by comparing the results from our ODACoR algorithms with the estimators derived from the meta-analysis and the pooled data.Results: The meta-analysis estimator showed a high relative bias (∼40%) when the clinical condition is relatively rare (∼0.5%), whereas ODACoR algorithms exhibited a substantially lower relative bias (∼0.2%). The estimated effects from our ODACoR algorithms were identical on par with the estimates from the pooled data, suggesting the high reliability of our federated learning algorithms. In contrast, the meta-analysis estimate failed to identify risk factors such as age, gender, chronic conditions history, and obesity, compared to the pooled data.Discussion: Our proposed ODACoR algorithms are communication-efficient, highly accurate, and suitable to characterize the complex interplay between multiple clinical conditions.Conclusion: Our study demonstrates that our ODACoR algorithms are communication-efficient and can be widely applicable for analyzing multiple clinical conditions in a time-to-event analysis framework.",

keywords = "communication-efficient, competing risk model, distributed research network, federated learning, one-shot distributed algorithm",

author = "Dazheng Zhang and Jiayi Tong and Naimin Jing and Yuchen Yang and Chongliang Luo and Yiwen Lu and Christakis, {Dimitri A.} and Diana G{\"u}the and Mady Hornig and Kelleher, {Kelly J.} and Morse, {Keith E.} and Rogerson, {Colin M.} and Jasmin Divers and Carroll, {Raymond J.} and Forrest, {Christopher B.} and Yong Chen",

note = "Publisher Copyright: # The Author(s) 2024. Published by Oxford University Press on behalf of the American Medical Informatics Association.",

year = "2024",

month = may,

day = "1",

doi = "10.1093/jamia/ocae027",

language = "English",

volume = "31",

pages = "1102--1112",

journal = "Journal of the American Medical Informatics Association",

issn = "1067-5027",

number = "5",

}

Zhang, D, Tong, J, Jing, N, Yang, Y, Luo, C, Lu, Y, Christakis, DA, Güthe, D, Hornig, M, Kelleher, KJ, Morse, KE, Rogerson, CM, Divers, J, Carroll, RJ, Forrest, CB & Chen, Y 2024, 'Learning competing risks across multiple hospitals: one-shot distributed algorithms', Journal of the American Medical Informatics Association, vol. 31, no. 5, pp. 1102-1112. https://doi.org/10.1093/jamia/ocae027

TY - JOUR

T1 - Learning competing risks across multiple hospitals

T2 - one-shot distributed algorithms

AU - Zhang, Dazheng

AU - Tong, Jiayi

AU - Jing, Naimin

AU - Yang, Yuchen

AU - Luo, Chongliang

AU - Lu, Yiwen

AU - Christakis, Dimitri A.

AU - Güthe, Diana

AU - Hornig, Mady

AU - Kelleher, Kelly J.

AU - Morse, Keith E.

AU - Rogerson, Colin M.

AU - Divers, Jasmin

AU - Carroll, Raymond J.

AU - Forrest, Christopher B.

AU - Chen, Yong

N1 - Publisher Copyright: # The Author(s) 2024. Published by Oxford University Press on behalf of the American Medical Informatics Association.

PY - 2024/5/1

Y1 - 2024/5/1

N2 - Objectives: To characterize the complex interplay between multiple clinical conditions in a time-to-event analysis framework using data from multiple hospitals, we developed two novel one-shot distributed algorithms for competing risk models (ODACoR). By applying our algorithms to the EHR data from eight national children’s hospitals, we quantified the impacts of a wide range of risk factors on the risk of post-acute sequelae of SARS-COV-2 (PASC) among children and adolescents.Materials and Methods: Our ODACoR algorithms are effectively executed due to their devised simplicity and communication efficiency. We evaluated our algorithms via extensive simulation studies as applications to quantification of the impacts of risk factors for PASC among children and adolescents using data from eight children’s hospitals including the Children’s Hospital of Philadelphia, Cincinnati Children’s Hospital Medical Center, Children’s Hospital of Colorado covering over 6.5 million pediatric patients. The accuracy of the estimation was assessed by comparing the results from our ODACoR algorithms with the estimators derived from the meta-analysis and the pooled data.Results: The meta-analysis estimator showed a high relative bias (∼40%) when the clinical condition is relatively rare (∼0.5%), whereas ODACoR algorithms exhibited a substantially lower relative bias (∼0.2%). The estimated effects from our ODACoR algorithms were identical on par with the estimates from the pooled data, suggesting the high reliability of our federated learning algorithms. In contrast, the meta-analysis estimate failed to identify risk factors such as age, gender, chronic conditions history, and obesity, compared to the pooled data.Discussion: Our proposed ODACoR algorithms are communication-efficient, highly accurate, and suitable to characterize the complex interplay between multiple clinical conditions.Conclusion: Our study demonstrates that our ODACoR algorithms are communication-efficient and can be widely applicable for analyzing multiple clinical conditions in a time-to-event analysis framework.

AB - Objectives: To characterize the complex interplay between multiple clinical conditions in a time-to-event analysis framework using data from multiple hospitals, we developed two novel one-shot distributed algorithms for competing risk models (ODACoR). By applying our algorithms to the EHR data from eight national children’s hospitals, we quantified the impacts of a wide range of risk factors on the risk of post-acute sequelae of SARS-COV-2 (PASC) among children and adolescents.Materials and Methods: Our ODACoR algorithms are effectively executed due to their devised simplicity and communication efficiency. We evaluated our algorithms via extensive simulation studies as applications to quantification of the impacts of risk factors for PASC among children and adolescents using data from eight children’s hospitals including the Children’s Hospital of Philadelphia, Cincinnati Children’s Hospital Medical Center, Children’s Hospital of Colorado covering over 6.5 million pediatric patients. The accuracy of the estimation was assessed by comparing the results from our ODACoR algorithms with the estimators derived from the meta-analysis and the pooled data.Results: The meta-analysis estimator showed a high relative bias (∼40%) when the clinical condition is relatively rare (∼0.5%), whereas ODACoR algorithms exhibited a substantially lower relative bias (∼0.2%). The estimated effects from our ODACoR algorithms were identical on par with the estimates from the pooled data, suggesting the high reliability of our federated learning algorithms. In contrast, the meta-analysis estimate failed to identify risk factors such as age, gender, chronic conditions history, and obesity, compared to the pooled data.Discussion: Our proposed ODACoR algorithms are communication-efficient, highly accurate, and suitable to characterize the complex interplay between multiple clinical conditions.Conclusion: Our study demonstrates that our ODACoR algorithms are communication-efficient and can be widely applicable for analyzing multiple clinical conditions in a time-to-event analysis framework.

KW - communication-efficient

KW - competing risk model

KW - distributed research network

KW - federated learning

KW - one-shot distributed algorithm

UR - http://www.scopus.com/inward/record.url?scp=85191027470&partnerID=8YFLogxK

U2 - 10.1093/jamia/ocae027

DO - 10.1093/jamia/ocae027

M3 - Article

C2 - 38456459

AN - SCOPUS:85191027470

SN - 1067-5027

VL - 31

SP - 1102

EP - 1112

JO - Journal of the American Medical Informatics Association

JF - Journal of the American Medical Informatics Association

IS - 5

ER -

Learning competing risks across multiple hospitals: one-shot distributed algorithms

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this