Advanced neuroprosthetic electrode design optimized by electromagnetic finite element simulation: innovations and applications.

IF 4.3 3区 工程技术 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Frontiers in Bioengineering and Biotechnology Pub Date : 2024-11-06 eCollection Date: 2024-01-01 DOI:10.3389/fbioe.2024.1476447
Shu Yang, Siyi Yang, Peixuan Li, Shuchun Gou, Yuhang Cheng, Qinggang Jia, Zhanhong Du
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Abstract

Based on electrophysiological activity, neuroprostheses can effectively monitor and control neural activity. Currently, electrophysiological neuroprostheses are widely utilized in treating neurological disorders, particularly in restoring motor, visual, auditory, and somatosensory functions after nervous system injuries. They also help alleviate inflammation, regulate blood pressure, provide analgesia, and treat conditions such as epilepsy and Alzheimer's disease, offering significant research, economic, and social value. Enhancing the targeting capabilities of neuroprostheses remains a key objective for researchers. Modeling and simulation techniques facilitate the theoretical analysis of interactions between neuroprostheses and the nervous system, allowing for quantitative assessments of targeting efficiency. Throughout the development of neuroprostheses, these modeling and simulation methods can save time, materials, and labor costs, thereby accelerating the rapid development of highly targeted neuroprostheses. This article introduces the fundamental principles of neuroprosthesis simulation technology and reviews how various simulation techniques assist in the design and performance enhancement of neuroprostheses. Finally, it discusses the limitations of modeling and simulation and outlines future directions for utilizing these approaches to guide neuroprosthesis design.

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通过电磁有限元模拟优化先进的神经假体电极设计:创新与应用。
基于电生理活动,神经义肢可以有效监测和控制神经活动。目前,电生理神经义肢被广泛用于治疗神经系统疾病,特别是在神经系统损伤后恢复运动、视觉、听觉和体感功能方面。它们还有助于缓解炎症、调节血压、提供镇痛以及治疗癫痫和阿尔茨海默病等疾病,具有重要的研究、经济和社会价值。提高神经义肢的靶向能力仍然是研究人员的主要目标。建模和模拟技术有助于对神经假体与神经系统之间的相互作用进行理论分析,从而对靶向效率进行定量评估。在神经假体的整个开发过程中,这些建模和模拟方法可以节省时间、材料和人力成本,从而加快高靶向性神经假体的快速开发。本文介绍了神经假体仿真技术的基本原理,并回顾了各种仿真技术如何帮助设计和提高神经假体的性能。最后,文章讨论了建模和仿真的局限性,并概述了利用这些方法指导神经假体设计的未来方向。
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来源期刊
Frontiers in Bioengineering and Biotechnology
Frontiers in Bioengineering and Biotechnology Chemical Engineering-Bioengineering
CiteScore
8.30
自引率
5.30%
发文量
2270
审稿时长
12 weeks
期刊介绍: The translation of new discoveries in medicine to clinical routine has never been easy. During the second half of the last century, thanks to the progress in chemistry, biochemistry and pharmacology, we have seen the development and the application of a large number of drugs and devices aimed at the treatment of symptoms, blocking unwanted pathways and, in the case of infectious diseases, fighting the micro-organisms responsible. However, we are facing, today, a dramatic change in the therapeutic approach to pathologies and diseases. Indeed, the challenge of the present and the next decade is to fully restore the physiological status of the diseased organism and to completely regenerate tissue and organs when they are so seriously affected that treatments cannot be limited to the repression of symptoms or to the repair of damage. This is being made possible thanks to the major developments made in basic cell and molecular biology, including stem cell science, growth factor delivery, gene isolation and transfection, the advances in bioengineering and nanotechnology, including development of new biomaterials, biofabrication technologies and use of bioreactors, and the big improvements in diagnostic tools and imaging of cells, tissues and organs. In today`s world, an enhancement of communication between multidisciplinary experts, together with the promotion of joint projects and close collaborations among scientists, engineers, industry people, regulatory agencies and physicians are absolute requirements for the success of any attempt to develop and clinically apply a new biological therapy or an innovative device involving the collective use of biomaterials, cells and/or bioactive molecules. “Frontiers in Bioengineering and Biotechnology” aspires to be a forum for all people involved in the process by bridging the gap too often existing between a discovery in the basic sciences and its clinical application.
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