Interpretable subgroup learning-based modeling framework:: Study of diabetic kidney disease prediction

Bo  Liu; Xiangzhou  Zhang; Kang  Liu; Xinhou  Hu; Wai Ting Ngai; Weiqi  Chen; Ho Yin  Chan; Yong  Hu; Mei  Liu

doi:10.1177/14604582241291379

Interpretable subgroup learning-based modeling framework: Study of diabetic kidney disease prediction

Bo Liu
, Xiangzhou Zhang
, Kang Liu
, Xinhou Hu
, Wai Ting Ngai
, Weiqi Chen
, Ho Yin Chan
, Yong Hu
, Mei Liu

Department of Management and Marketing

Research output: Journal article publication › Journal article › Academic research › peer-review

1 Citation (Scopus)

Abstract

Objectives: Complex diseases, like diabetic kidney disease (DKD), often exhibit heterogeneity, challenging accurate risk prediction with machine learning. Traditional global models ignore patient differences, and subgroup learning lacks interpretability and predictive efficiency. This study introduces the Interpretable Subgroup Learning-based Modeling (iSLIM) framework to address these issues.
Methods: iSLIM integrates expert knowledge with a tree-based recursive partitioning approach to identify DKD subgroups within an EHR dataset of 11,559 patients. It then constructs separate models for each subgroup, enhancing predictive accuracy while preserving interpretability.
Results: Five clinically relevant subgroups are identified, achieving an average sensitivity of 0.8074, outperforming a single global model by 0.1104. Post hoc analyses provide pathological and biological evidence supporting subgroup validity and potential DKD risk factors.
Conclusion: The iSLIM surpasses traditional global model in predictive performance and subgroup-specific risk factor interpretation, enhancing the understanding of DKD’s heterogeneous mechanisms and potentially increasing the adoption of machine learning models in clinical decision-making.

Original language	English
Article number	14604582241291379
Journal	Health Informatics Journal
Volume	30
Issue number	4
DOIs	https://doi.org/10.1177/14604582241291379
Publication status	Published - Oct 2024

Keywords

clinical decision support system
diabetic kidney disease
electronic health record
predictive modeling
subgroup learning

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

More information

10.1177/14604582241291379

Cite this

@article{227e529e0ffe4bdb9d264655be305159,

title = "Interpretable subgroup learning-based modeling framework:: Study of diabetic kidney disease prediction",

abstract = "Objectives: Complex diseases, like diabetic kidney disease (DKD), often exhibit heterogeneity, challenging accurate risk prediction with machine learning. Traditional global models ignore patient differences, and subgroup learning lacks interpretability and predictive efficiency. This study introduces the Interpretable Subgroup Learning-based Modeling (iSLIM) framework to address these issues. Methods: iSLIM integrates expert knowledge with a tree-based recursive partitioning approach to identify DKD subgroups within an EHR dataset of 11,559 patients. It then constructs separate models for each subgroup, enhancing predictive accuracy while preserving interpretability. Results: Five clinically relevant subgroups are identified, achieving an average sensitivity of 0.8074, outperforming a single global model by 0.1104. Post hoc analyses provide pathological and biological evidence supporting subgroup validity and potential DKD risk factors. Conclusion: The iSLIM surpasses traditional global model in predictive performance and subgroup-specific risk factor interpretation, enhancing the understanding of DKD{\textquoteright}s heterogeneous mechanisms and potentially increasing the adoption of machine learning models in clinical decision-making.",

keywords = "clinical decision support system, diabetic kidney disease, electronic health record, predictive modeling, subgroup learning",

author = "Bo Liu and Xiangzhou Zhang and Kang Liu and Xinhou Hu and Ngai, \{Wai Ting\} and Weiqi Chen and Chan, \{Ho Yin\} and Yong Hu and Mei Liu",

year = "2024",

month = oct,

doi = "10.1177/14604582241291379",

language = "English",

volume = "30",

journal = "Health Informatics Journal",

issn = "1460-4582",

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number = "4",

}

TY - JOUR

T1 - Interpretable subgroup learning-based modeling framework:

T2 - Study of diabetic kidney disease prediction

AU - Liu, Bo

AU - Zhang, Xiangzhou

AU - Liu, Kang

AU - Hu, Xinhou

AU - Ngai, Wai Ting

AU - Chen, Weiqi

AU - Chan, Ho Yin

AU - Hu, Yong

AU - Liu, Mei

PY - 2024/10

Y1 - 2024/10

N2 - Objectives: Complex diseases, like diabetic kidney disease (DKD), often exhibit heterogeneity, challenging accurate risk prediction with machine learning. Traditional global models ignore patient differences, and subgroup learning lacks interpretability and predictive efficiency. This study introduces the Interpretable Subgroup Learning-based Modeling (iSLIM) framework to address these issues. Methods: iSLIM integrates expert knowledge with a tree-based recursive partitioning approach to identify DKD subgroups within an EHR dataset of 11,559 patients. It then constructs separate models for each subgroup, enhancing predictive accuracy while preserving interpretability. Results: Five clinically relevant subgroups are identified, achieving an average sensitivity of 0.8074, outperforming a single global model by 0.1104. Post hoc analyses provide pathological and biological evidence supporting subgroup validity and potential DKD risk factors. Conclusion: The iSLIM surpasses traditional global model in predictive performance and subgroup-specific risk factor interpretation, enhancing the understanding of DKD’s heterogeneous mechanisms and potentially increasing the adoption of machine learning models in clinical decision-making.

AB - Objectives: Complex diseases, like diabetic kidney disease (DKD), often exhibit heterogeneity, challenging accurate risk prediction with machine learning. Traditional global models ignore patient differences, and subgroup learning lacks interpretability and predictive efficiency. This study introduces the Interpretable Subgroup Learning-based Modeling (iSLIM) framework to address these issues. Methods: iSLIM integrates expert knowledge with a tree-based recursive partitioning approach to identify DKD subgroups within an EHR dataset of 11,559 patients. It then constructs separate models for each subgroup, enhancing predictive accuracy while preserving interpretability. Results: Five clinically relevant subgroups are identified, achieving an average sensitivity of 0.8074, outperforming a single global model by 0.1104. Post hoc analyses provide pathological and biological evidence supporting subgroup validity and potential DKD risk factors. Conclusion: The iSLIM surpasses traditional global model in predictive performance and subgroup-specific risk factor interpretation, enhancing the understanding of DKD’s heterogeneous mechanisms and potentially increasing the adoption of machine learning models in clinical decision-making.

KW - clinical decision support system

KW - diabetic kidney disease

KW - electronic health record

KW - predictive modeling

KW - subgroup learning

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