eLife (Jul 2021)

A deep learning algorithm to translate and classify cardiac electrophysiology

  • Parya Aghasafari,
  • Pei-Chi Yang,
  • Divya C Kernik,
  • Kazuho Sakamoto,
  • Yasunari Kanda,
  • Junko Kurokawa,
  • Igor Vorobyov,
  • Colleen E Clancy

DOI
https://doi.org/10.7554/eLife.68335
Journal volume & issue
Vol. 10

Abstract

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The development of induced pluripotent stem cell-derived cardiomyocytes (iPSC-CMs) has been a critical in vitro advance in the study of patient-specific physiology, pathophysiology, and pharmacology. We designed a new deep learning multitask network approach intended to address the low throughput, high variability, and immature phenotype of the iPSC-CM platform. The rationale for combining translation and classification tasks is because the most likely application of the deep learning technology we describe here is to translate iPSC-CMs following application of a perturbation. The deep learning network was trained using simulated action potential (AP) data and applied to classify cells into the drug-free and drugged categories and to predict the impact of electrophysiological perturbation across the continuum of aging from the immature iPSC-CMs to the adult ventricular myocytes. The phase of the AP extremely sensitive to perturbation due to a steep rise of the membrane resistance was found to contain the key information required for successful network multitasking. We also demonstrated successful translation of both experimental and simulated iPSC-CM AP data validating our network by prediction of experimental drug-induced effects on adult cardiomyocyte APs by the latter.

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