A deep learning algorithm to translate and classify cardiac electrophysiology

Aghasafari, Parya; Yang, Pei; Kernik, Divya C.; Sakamoto, Kazuho; Kanda, Yasunari; Kurokawa, Junko; Clancy, Colleen E.

doi:10.7554/elife.68335

Cited by 22 publications

(14 citation statements)

References 80 publications

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“…Discrepancy between highly nonlinear biophysical model responses and linear approximations increases with the severity of the perturbation and increases prediction uncertainty. Recently, a deep learning network approach was demonstrated for translation of immature hiPSC-CM to adult electrophysiology ( 68 ). Comparison of these methodologies may help to determine what portion of all the possible nonlinear electrophysiological mechanisms underlying these biophysical models (and actual myocyte responses in vitro) can be encoded via linear regression and when nonlinear approaches should be used.…”

Section: Discussionmentioning

confidence: 99%

Quantitative cross-species translators of cardiac myocyte electrophysiology: Model training, experimental validation, and applications

et al. 2021

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Section: Discussionmentioning

confidence: 99%

Quantitative cross-species translators of cardiac myocyte electrophysiology: Model training, experimental validation, and applications

et al. 2021

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“…Interestingly, it has been reported that an ECGage that is >8 years greater than the chronological age is associated with a higher rate of mortality [ 82 ]. In 2000, an artificial neural network was used to detect activations during ventricular fibrillation, which resulted in a classification correctness of 92% in the test examples [ 83 ], with improvements having been made since [ 84 , 85 , 86 ].…”

Section: Computer Modelsmentioning

confidence: 99%

Animal Disease Models and Patient-iPS-Cell-Derived In Vitro Disease Models for Cardiovascular Biology—How Close to Disease?

Kawaguchi

Nakanishi

2023

Biology

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Currently, zebrafish, rodents, canines, and pigs are the primary disease models used in cardiovascular research. In general, larger animals have more physiological similarities to humans, making better disease models. However, they can have restricted or limited use because they are difficult to handle and maintain. Moreover, animal welfare laws regulate the use of experimental animals. Different species have different mechanisms of disease onset. Organs in each animal species have different characteristics depending on their evolutionary history and living environment. For example, mice have higher heart rates than humans. Nonetheless, preclinical studies have used animals to evaluate the safety and efficacy of human drugs because no other complementary method exists. Hence, we need to evaluate the similarities and differences in disease mechanisms between humans and experimental animals. The translation of animal data to humans contributes to eliminating the gap between these two. In vitro disease models have been used as another alternative for human disease models since the discovery of induced pluripotent stem cells (iPSCs). Human cardiomyocytes have been generated from patient-derived iPSCs, which are genetically identical to the derived patients. Researchers have attempted to develop in vivo mimicking 3D culture systems. In this review, we explore the possible uses of animal disease models, iPSC-derived in vitro disease models, humanized animals, and the recent challenges of machine learning. The combination of these methods will make disease models more similar to human disease.

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“…The spectral power in Gaussian white noise is uniformly distributed across all frequencies and is normally distributed in the time domain. Gaussian noise is one of the most common descriptors of fluctuations in biological systems and is therefore implemented in simulations of ionic currents and EC coupling (e.g., Aghasafari et al, 2021 ; Sato et al, 2009 ; Krogh-Madsen et al, 2017 ; Guevara and Lewis, 1995 ). However, as discussed in further detail below, there is a paucity of analyses of [Ca 2+ ] i and electrical noise during EC coupling and therefore of computational models that incorporate experimentally determined noise; without inclusion of these data, the predictions of these models are altered.…”

Section: Implications Of Noise In Biological Systemsmentioning

confidence: 99%

Biological noise is a key determinant of the reproducibility and adaptability of cardiac pacemaking and EC coupling

Guarina

Moghbel

Pourhosseinzadeh

et al. 2022

Journal of General Physiology

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Each heartbeat begins with the generation of an action potential in pacemaking cells in the sinoatrial node. This signal triggers contraction of cardiac muscle through a process termed excitation–contraction (EC) coupling. EC coupling is initiated in dyadic structures of cardiac myocytes, where ryanodine receptors in the junctional sarcoplasmic reticulum come into close apposition with clusters of CaV1.2 channels in invaginations of the sarcolemma. Cooperative activation of CaV1.2 channels within these clusters causes a local increase in intracellular Ca2+ that activates the juxtaposed ryanodine receptors. A salient feature of healthy cardiac function is the reliable and precise beat-to-beat pacemaking and amplitude of Ca2+ transients during EC coupling. In this review, we discuss recent discoveries suggesting that the exquisite reproducibility of this system emerges, paradoxically, from high variability at subcellular, cellular, and network levels. This variability is attributable to stochastic fluctuations in ion channel trafficking, clustering, and gating, as well as dyadic structure, which increase intracellular Ca2+ variance during EC coupling. Although the effects of these large, local fluctuations in function and organization are sometimes negligible at the macroscopic level owing to spatial–temporal summation within and across cells in the tissue, recent work suggests that the “noisiness” of these intracellular Ca2+ events may either enhance or counterintuitively reduce variability in a context-dependent manner. Indeed, these noisy events may represent distinct regulatory features in the tuning of cardiac contractility. Collectively, these observations support the importance of incorporating experimentally determined values of Ca2+ variance in all EC coupling models. The high reproducibility of cardiac contraction is a paradoxical outcome of high Ca2+ signaling variability at subcellular, cellular, and network levels caused by stochastic fluctuations in multiple processes in time and space. This underlying stochasticity, which counterintuitively manifests as reliable, consistent Ca2+ transients during EC coupling, also allows for rapid changes in cardiac rhythmicity and contractility in health and disease.

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A deep learning algorithm to translate and classify cardiac electrophysiology

Cited by 22 publications

References 80 publications

Quantitative cross-species translators of cardiac myocyte electrophysiology: Model training, experimental validation, and applications

Quantitative cross-species translators of cardiac myocyte electrophysiology: Model training, experimental validation, and applications

Animal Disease Models and Patient-iPS-Cell-Derived In Vitro Disease Models for Cardiovascular Biology—How Close to Disease?

Biological noise is a key determinant of the reproducibility and adaptability of cardiac pacemaking and EC coupling

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