A decision support system in precision medicine: contrastive multimodal learning for patient stratification-Reference-Cited by-同舟云学术

A decision support system in precision medicine: contrastive multimodal learning for patient stratification

Published:2023-08-29 Issue: Volume: Page:
ISSN:0254-5330
Container-title:Annals of Operations Research
language:en
Short-container-title:Ann Oper Res

Author:

Yin Qing,Zhong Linda,Song Yunya,Bai Liang,Wang Zhihua,Li Chen,Xu Yida,Yang Xian^ORCID

Abstract

AbstractPrecision medicine aims to provide personalized healthcare for patients by stratifying them into subgroups based on their health conditions, enabling the development of tailored medical management. Various decision support systems (DSSs) are increasingly developed in this field, where the performance is limited to their capability of handling big amounts of heterogeneous and high-dimensional electronic health records (EHRs). In this paper, we focus on developing a deep learning model for patient stratification that can identify and explain patient subgroups from multimodal EHRs. The primary challenge is to effectively align and unify heterogeneous information from various modalities, which includes both unstructured and structured data. Here, we develop a Contrastive Multimodal learning model for EHR (ConMEHR) based on topic modelling. In ConMEHR, modality-level and topic-level contrastive learning (CL) mechanisms are adopted to obtain a unified representation space and diversify patient subgroups, respectively. The performance of ConMEHR will be evaluated on two real-world EHR datasets and the results show that our model outperforms other baseline methods.

Publisher

Springer Science and Business Media LLC

Subject

Management Science and Operations Research,General Decision Sciences

Link

https://link.springer.com/content/pdf/10.1007/s10479-023-05545-6.pdf

Reference78 articles.

1. Affes, Z., & Hentati-Kaffel, R. (2019). Forecast bankruptcy using a blend of clustering and mars model: Case of us banks. Annals of Operations Research, 281(1–2), 27–64.

2. Arora, S., Ge, R., Halpern, Y., Mimno, D., Moitra, A., Sontag, D., Wu, Y., & Zhu, M. (2013). A practical algorithm for topic modeling with provable guarantees. In International conference on machine learning (pp. 280–288). PMLR

3. Arora, S., Khandeparkar, H., Khodak, M., Plevrakis, O., & Saunshi, N. (2019). A theoretical analysis of contrastive unsupervised representation learning. In 36th International conference on machine learning, ICML 2019 (pp. 9904–9923). International Machine Learning Society (IMLS).

4. Bachman, P., Hjelm, R. D., & Buchwalter, W. (2019). Learning representations by maximizing mutual information across views. In Advances in neural information processing systems, vol. 32.

5. Benson, A. R., Lee, J. D., Rajwa, B., & Gleich, D. F. (2014). Scalable methods for nonnegative matrix factorizations of near-separable tall-and-skinny matrices. In Advances in neural information processing systems, vol. 27.