Predicting Outcomes of Continuous Renal Replacement Therapy Using Body Composition Monitoring: a Deep-learning Approach

Overview

Journal Sci Rep

Specialty Science

Date 2023 Mar 22

PMID 36944678

Authors

Kyung Don Yoo

Junhyug Noh

Wonho Bae

Jung Nam An

Hyung Jung Oh

Harin Rhee

Eun Young Seong

Seon Ha Baek

Shin Young Ahn

Jang-Hee Cho

Dong Ki Kim

Dong-Ryeol Ryu

Sejoong Kim

Chun Soo Lim

Jung Pyo Lee

Affiliations

Soon will be listed here.

Abstract

Fluid balance is a critical prognostic factor for patients with severe acute kidney injury (AKI) requiring continuous renal replacement therapy (CRRT). This study evaluated whether repeated fluid balance monitoring could improve prognosis in this clinical population. This was a multicenter retrospective study that included 784 patients (mean age, 67.8 years; males, 66.4%) with severe AKI requiring CRRT during 2017-2019 who were treated in eight tertiary hospitals in Korea. Sequential changes in total body water were compared between patients who died (event group) and those who survived (control group) using mixed-effects linear regression analyses. The performance of various machine learning methods, including recurrent neural networks, was compared to that of existing prognostic clinical scores. After adjusting for confounding factors, a marginal benefit of fluid balance was identified for the control group compared to that for the event group (p = 0.074). The deep-learning model using a recurrent neural network with an autoencoder and including fluid balance monitoring provided the best differentiation between the groups (area under the curve, 0.793) compared to 0.604 and 0.606 for SOFA and APACHE II scores, respectively. Our prognostic, deep-learning model underlines the importance of fluid balance monitoring for prognosis assessment among patients receiving CRRT.

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