Multicenter validation of a machine learning phase space electro-mechanical pulse wave analysis to predict elevated left ventricular end diastolic pressure at the point-of-care

Bhavnani, Sanjeev P; Khedraki, Rola; Cohoon, Travis J; Meine, Frederick J; Stuckey, Thomas D; McMinn, Thomas; Depta, Jeremiah P; Bennett, Brett; McGarry, Thomas; Carroll, William; Suh, David; Steuter, John A; Roberts, Michael; Gillins, Horace R; Shadforth, Ian; Lange, Emmanuel; Doomra, Abhinav; Firouzi, Mohammad; Fathieh, Farhad; Burton, Timothy; Khosousi, Ali; Ramchandani, Shyam; Sanders, William E; Smart, Frank

Multicenter validation of a machine learning phase space electro-mechanical pulse wave analysis to predict elevated left ventricular end diastolic pressure at the point-of-care

Sanjeev P Bhavnani, Rola Khedraki, Travis J Cohoon, Frederick J Meine, Thomas D Stuckey, Thomas McMinn, Jeremiah P Depta, Brett Bennett, Thomas McGarry, William Carroll, David Suh, John A Steuter, Michael Roberts, Horace R Gillins, Ian Shadforth, Emmanuel Lange, Abhinav Doomra, Mohammad Firouzi, Farhad Fathieh, Timothy Burton, Ali Khosousi, Shyam Ramchandani, William E Sanders and Frank Smart

PLOS ONE, 2022, vol. 17, issue 11, 1-22

Abstract: Background: Phase space is a mechanical systems approach and large-scale data representation of an object in 3-dimensional space. Whether such techniques can be applied to predict left ventricular pressures non-invasively and at the point-of-care is unknown. Objective: This study prospectively validated a phase space machine-learned approach based on a novel electro-mechanical pulse wave method of data collection through orthogonal voltage gradient (OVG) and photoplethysmography (PPG) for the prediction of elevated left ventricular end diastolic pressure (LVEDP). Methods: Consecutive outpatients across 15 US-based healthcare centers with symptoms suggestive of coronary artery disease were enrolled at the time of elective cardiac catheterization and underwent OVG and PPG data acquisition immediately prior to angiography with signals paired with LVEDP (IDENTIFY; NCT #03864081). The primary objective was to validate a ML algorithm for prediction of elevated LVEDP using a definition of ≥25 mmHg (study cohort) and normal LVEDP ≤ 12 mmHg (control cohort), using AUC as the measure of diagnostic accuracy. Secondary objectives included performance of the ML predictor in a propensity matched cohort (age and gender) and performance for an elevated LVEDP across a spectrum of comparative LVEDP (

Date: 2022
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Persistent link: https://EconPapers.repec.org/RePEc:plo:pone00:0277300

DOI: 10.1371/journal.pone.0277300

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