Compact voltage and current stimulation buffer for high-density microelectrode arrays

P. Livi, F. Heer, U. Frey, D. Bakkum, A. Hierlemann
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引用次数: 9

Abstract

The most sophisticated information processing system, the human brain, consists of a huge number of neurons that form part of an intricate network and communicate through electrical and chemical signals via synapses. To elucidate interneuronal communication and network characteristics, it is important to gain bidirectional access (recording and stimulation) to individual neurons and to be able to do closed-loop experiments in cultures. The targeted stimulation of individual neurons, and the subsequent tracking of a signal's propagation is a valuable tool to decipher network structures as well as strength and plasticity of involved connections. CMOS-based microelectrode arrays (MEAs) featuring high spatial resolution (subcellular) and low noise provide a wealth of information. Extracellular electrodes ensure cell integrity and long-term recordings; neuronal stimulation is performed by either current or voltage pulses, with typical amplitudes of 0.1 to 1V or 5 to 10µA, and durations of 50 to 900µs [1].
用于高密度微电极阵列的紧凑型电压和电流刺激缓冲器
人类大脑是最复杂的信息处理系统,它由大量神经元组成,这些神经元构成了一个复杂网络的一部分,并通过突触通过电信号和化学信号进行交流。为了阐明神经元间的通信和网络特性,重要的是获得对单个神经元的双向访问(记录和刺激),并能够在培养中进行闭环实验。对单个神经元的定向刺激以及随后的信号传播跟踪是破译网络结构以及相关连接的强度和可塑性的重要工具。基于cmos的微电极阵列(MEAs)具有高空间分辨率(亚细胞)和低噪声的特点,提供了丰富的信息。细胞外电极确保细胞完整性和长期记录;神经元刺激可通过电流或电压脉冲进行,典型振幅为0.1至1V或5至10 μ A,持续时间为50至900 μ s[1]。
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