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Predicting stroke volume variation using central venous pressure waveform: a deep learning approach

Authors
 Park, Insun  ;  Park, Jae Hyon  ;  Koo, Bon-Wook  ;  Kim, Jin-Hee  ;  Jeon, Young-Tae  ;  Na, Hyo-Seok  ;  Oh, Ah-Young 
Citation
 PHYSIOLOGICAL MEASUREMENT, Vol.45(9), 2024-09 
Article Number
 095007 
Journal Title
PHYSIOLOGICAL MEASUREMENT
ISSN
 0967-3334 
Issue Date
2024-09
Keywords
anesthesia ; central venous pressure ; deep learning ; fluid therapy ; hemodynamics ; stroke volume
Abstract
Objective. This study evaluated the predictive performance of a deep learning approach to predict stroke volume variation (SVV) from central venous pressure (CVP) waveforms. Approach. Long short-term memory (LSTM) and the feed-forward neural network were sequenced to predict SVV using CVP waveforms obtained from the VitalDB database, an open-source registry. The input for the LSTM consisted of 10 s CVP waveforms sampled at 2 s intervals throughout the anesthesia duration. Inputs of the feed-forward network were the outputs of LSTM and demographic data such as age, sex, weight, and height. The final output of the feed-forward network was the SVV. The performance of SVV predicted by the deep learning model was compared to SVV estimated derived from arterial pulse waveform analysis using a commercialized model, EV1000. Main results. The model hyperparameters consisted of 12 memory cells in the LSTM layer and 32 nodes in the hidden layer of the feed-forward network. A total of 224 cases comprising 1717 978 CVP waveforms and EV1000/SVV data were used to construct and test the deep learning models. The concordance correlation coefficient between estimated SVV from the deep learning model were 0.993 (95% confidence interval, 0.992-0.993) for SVV measured by EV1000. Significance. Using a deep learning approach, CVP waveforms can accurately approximate SVV values close to those estimated using commercial arterial pulse waveform analysis.
DOI
10.1088/1361-6579/ad75e4
Appears in Collections:
7. Others (기타) > Others (기타) > 1. Journal Papers
URI
https://ir.ymlib.yonsei.ac.kr/handle/22282913/206410
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