电生理CMOS电路的设计

IF 0.6 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

IEICE Transactions on Electronics Pub Date : 2023-01-01 DOI:10.1587/transele.2022cti0003

N. V. Helleputte, Carolina Mora Lopez, C. Hoof

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引用次数: 0

摘要

电生理学是研究生物组织和细胞电学特性的学科，在现代临床研究、诊断、疾病监测和治疗中已成为不可或缺的学科。在本文中，我们简要介绍了这一学科的历史，以及集成电路设计在过去几十年中如何影响电生理学。我们将讨论生物电位放大器设计如何从经典的三运培架构发展到更先进的高性能电路，从而实现自主和中枢神经系统的长期可穿戴监测。我们还将讨论这些集成电路是如何进化到测量体内神经回路的。本文的目标读者是谁是新的生物电势记录领域，并希望得到一个简短的历史概述，并加快对可穿戴和体内生物电势记录的主要电路设计概念。

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Design of CMOS Circuits for Electrophysiology

SUMMARY Electrophysiology, which is the study of the electrical properties of biological tissues and cells, has become indispensable in modern clinical research, diagnostics, disease monitoring and therapeutics. In this paper we present a brief history of this discipline and how integrated circuit design shaped electrophysiology in the last few decades. We will discuss how biopotential ampliﬁer design has evolved from the classical three-opamp architecture to more advanced high-performance circuits enabling long-term wearable monitoring of the autonomous and central nervous system. We will also discuss how these integrated circuits evolved to measure in-vivo neural circuits. This paper targets readers who are new to the domain of biopotential recording and want to get a brief historical overview and get up to speed on the main circuit design concepts for both wearable and in-vivo biopotential recording.

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来源期刊

IEICE Transactions on Electronics 工程技术-工程：电子与电气

CiteScore

1.00

自引率

20.00%

发文量

审稿时长

3-6 weeks

期刊介绍： Currently, the IEICE has ten sections nationwide. Each section operates under the leadership of a section chief, four section secretaries and about 20 section councilors. Sections host lecture meetings, seminars and industrial tours, and carry out other activities. Topics: Integrated Circuits, Semiconductor Materials and Devices, Quantum Electronics, Opto-Electronics, Superconductive Electronics, Electronic Displays, Microwave and Millimeter Wave Technologies, Vacuum and Beam Technologies, Recording and Memory Technologies, Electromagnetic Theory.