Electrical Stimulation Induced Current Distribution in Peripheral Nerves Varies Significantly with the Extent of Nerve Damage: A Computational Study Utilizing Convolutional Neural Network and Realistic Nerve Models.

IF 6.6 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
International Journal of Neural Systems Pub Date : 2023-04-01 Epub Date: 2023-03-15 DOI:10.1142/S0129065723500223
Jinze Du, Andres Morales, Pragya Kosta, Jean-Marie C Bouteiller, Gema Martinez-Navarrete, David J Warren, Eduardo Fernandez, Gianluca Lazzi
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引用次数: 1

Abstract

Electrical stimulation of the peripheral nervous system is a promising therapeutic option for several conditions; however, its effects on tissue and the safety of the stimulation remain poorly understood. In order to devise stimulation protocols that enhance therapeutic efficacy without the risk of causing tissue damage, we constructed computational models of peripheral nerve and stimulation cuffs based on extremely high-resolution cross-sectional images of the nerves using the most recent advances in computing power and machine learning techniques. We developed nerve models using nonstimulated (healthy) and over-stimulated (damaged) rat sciatic nerves to explore how nerve damage affects the induced current density distribution. Using our in-house computational, quasi-static, platform, and the Admittance Method (AM), we estimated the induced current distribution within the nerves and compared it for healthy and damaged nerves. We also estimated the extent of localized cell damage in both healthy and damaged nerve samples. When the nerve is damaged, as demonstrated principally by the decreased nerve fiber packing, the current penetrates deeper into the over-stimulated nerve than in the healthy sample. As safety limits for electrical stimulation of peripheral nerves still refer to the Shannon criterion to distinguish between safe and unsafe stimulation, the capability this work demonstrated is an important step toward the development of safety criteria that are specific to peripheral nerve and make use of the latest advances in computational bioelectromagnetics and machine learning, such as Python-based AM and CNN-based nerve image segmentation.

外周神经中电刺激诱导的电流分布随神经损伤程度的不同而显著变化:一项利用卷积神经网络和真实神经模型的计算研究。
电刺激外周神经系统是治疗多种疾病的一种有前景的选择;然而,它对组织的影响和刺激的安全性仍知之甚少。为了设计出在不造成组织损伤的情况下提高治疗效果的刺激方案,我们利用计算能力和机器学习技术的最新进展,基于神经的高分辨率横截面图像构建了外周神经和刺激套的计算模型。我们使用未刺激(健康)和过度刺激(受损)的大鼠坐骨神经建立了神经模型,以探索神经损伤如何影响诱导电流密度分布。使用我们的内部计算、准静态平台和导纳法(AM),我们估计了神经内的感应电流分布,并对健康和受损神经进行了比较。我们还估计了健康和受损神经样本中局部细胞损伤的程度。当神经受损时,主要表现为神经纤维堆积减少,电流比健康样本更深地渗透到过度刺激的神经中。由于外周神经电刺激的安全极限仍然参考Shannon标准来区分安全和不安全刺激,这项工作证明的能力是开发针对外周神经的安全标准的重要一步,并利用计算生物电磁学和机器学习的最新进展,诸如基于Python的AM和基于CNN的神经图像分割。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
International Journal of Neural Systems
International Journal of Neural Systems 工程技术-计算机:人工智能
CiteScore
11.30
自引率
28.80%
发文量
116
审稿时长
24 months
期刊介绍: The International Journal of Neural Systems is a monthly, rigorously peer-reviewed transdisciplinary journal focusing on information processing in both natural and artificial neural systems. Special interests include machine learning, computational neuroscience and neurology. The journal prioritizes innovative, high-impact articles spanning multiple fields, including neurosciences and computer science and engineering. It adopts an open-minded approach to this multidisciplinary field, serving as a platform for novel ideas and enhanced understanding of collective and cooperative phenomena in computationally capable systems.
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