Frontiers in Cardiovascular Medicine (Nov 2020)

Neural-Network-Based Diagnosis Using 3-Dimensional Myocardial Architecture and Deformation: Demonstration for the Differentiation of Hypertrophic Cardiomyopathy

  • Alessandro Satriano,
  • Yarmaghan Afzal,
  • Muhammad Sarim Afzal,
  • Ali Fatehi Hassanabad,
  • Cody Wu,
  • Steven Dykstra,
  • Jacqueline Flewitt,
  • Jacqueline Flewitt,
  • Jacqueline Flewitt,
  • Patricia Feuchter,
  • Rosa Sandonato,
  • Bobak Heydari,
  • Naeem Merchant,
  • Naeem Merchant,
  • Naeem Merchant,
  • Andrew G. Howarth,
  • Andrew G. Howarth,
  • Andrew G. Howarth,
  • Carmen P. Lydell,
  • Carmen P. Lydell,
  • Carmen P. Lydell,
  • Aneal Khan,
  • Nowell M. Fine,
  • Russell Greiner,
  • Russell Greiner,
  • James A. White,
  • James A. White,
  • James A. White

DOI
https://doi.org/10.3389/fcvm.2020.584727
Journal volume & issue
Vol. 7

Abstract

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The diagnosis of cardiomyopathy states may benefit from machine-learning (ML) based approaches, particularly to distinguish those states with similar phenotypic characteristics. Three-dimensional myocardial deformation analysis (3D-MDA) has been validated to provide standardized descriptors of myocardial architecture and deformation, and may therefore offer appropriate features for the training of ML-based diagnostic tools. We aimed to assess the feasibility of automated disease diagnosis using a neural network trained using 3D-MDA to discriminate hypertrophic cardiomyopathy (HCM) from its mimic states: cardiac amyloidosis (CA), Anderson–Fabry disease (AFD), and hypertensive cardiomyopathy (HTNcm). 3D-MDA data from 163 patients (mean age 53.1 ± 14.8 years; 68 females) with left ventricular hypertrophy (LVH) of known etiology was provided. Source imaging data was from cardiac magnetic resonance (CMR). Clinical diagnoses were as follows: 85 HCM, 30 HTNcm, 30 AFD, and 18 CA. A fully-connected-layer feed-forward neural was trained to distinguish HCM vs. other mimic states. Diagnostic performance was compared to threshold-based assessments of volumetric and strain-based CMR markers, in addition to baseline clinical patient characteristics. Threshold-based measures provided modest performance, the greatest area under the curve (AUC) being 0.70. Global strain parameters exhibited reduced performance, with AUC under 0.64. A neural network trained exclusively from 3D-MDA data achieved an AUC of 0.94 (sensitivity 0.92, specificity 0.90) when performing the same task. This study demonstrates that ML-based diagnosis of cardiomyopathy states performed exclusively from 3D-MDA is feasible and can distinguish HCM from mimic disease states. These findings suggest strong potential for computer-assisted diagnosis in clinical practice.

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