Neuromorphic computing for modeling neurological and psychiatric disorders: implications for drug development

IF 10.7 2区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
Amisha S. Raikar, J Andrew, Pranjali Prabhu Dessai, Sweta M. Prabhu, Shounak Jathar, Aishwarya Prabhu, Mayuri B. Naik, Gokuldas Vedant S. Raikar
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Abstract

The emergence of neuromorphic computing, inspired by the structure and function of the human brain, presents a transformative framework for modelling neurological disorders in drug development. This article investigates the implications of applying neuromorphic computing to simulate and comprehend complex neural systems affected by conditions like Alzheimer’s, Parkinson’s, and epilepsy, drawing from extensive literature. It explores the intersection of neuromorphic computing with neurology and pharmaceutical development, emphasizing the significance of understanding neural processes and integrating deep learning techniques. Technical considerations, such as integrating neural circuits into CMOS technology and employing memristive devices for synaptic emulation, are discussed. The review evaluates how neuromorphic computing optimizes drug discovery and improves clinical trials by precisely simulating biological systems. It also examines the role of neuromorphic models in comprehending and simulating neurological disorders, facilitating targeted treatment development. Recent progress in neuromorphic drug discovery is highlighted, indicating the potential for transformative therapeutic interventions. As technology advances, the synergy between neuromorphic computing and neuroscience holds promise for revolutionizing the study of the human brain’s complexities and addressing neurological challenges.

用于神经和精神疾病建模的神经形态计算:对药物开发的影响
受人脑结构和功能的启发,神经形态计算的出现为药物开发中的神经系统疾病建模提供了一个变革性框架。本文通过大量文献,探讨了应用神经形态计算模拟和理解受阿尔茨海默氏症、帕金森氏症和癫痫等疾病影响的复杂神经系统的意义。文章探讨了神经形态计算与神经学和药物开发的交叉点,强调了理解神经过程和整合深度学习技术的重要性。文中还讨论了一些技术考虑因素,如将神经电路集成到 CMOS 技术中,以及采用记忆器件进行突触仿真。综述评估了神经形态计算如何通过精确模拟生物系统来优化药物发现和改进临床试验。它还探讨了神经形态模型在理解和模拟神经系统疾病方面的作用,从而促进有针对性的治疗开发。报告重点介绍了神经形态药物发现的最新进展,指出了变革性治疗干预的潜力。随着技术的进步,神经形态计算与神经科学之间的协同作用有望彻底改变对人类大脑复杂性的研究,并解决神经学方面的难题。
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
Artificial Intelligence Review
Artificial Intelligence Review 工程技术-计算机:人工智能
CiteScore
22.00
自引率
3.30%
发文量
194
审稿时长
5.3 months
期刊介绍: Artificial Intelligence Review, a fully open access journal, publishes cutting-edge research in artificial intelligence and cognitive science. It features critical evaluations of applications, techniques, and algorithms, providing a platform for both researchers and application developers. The journal includes refereed survey and tutorial articles, along with reviews and commentary on significant developments in the field.
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