Design of a current-steering implantable stimulator with electric field shifting for deep brain stimulation

2010 Biomedical Circuits and Systems Conference (BioCAS) Pub Date : 1900-01-01 DOI:10.1109/BIOCAS.2010.5709596

V. Valente, A. Demosthenous, R. Bayford

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引用次数: 5

Abstract

Active control over the electric field distribution during deep brain stimulation (DBS) can provide better focus of the stimulation field on target regions, beneficial to improve neural selectivity and reduce side effects arising from simulation of non-target regions. A current-steering tripolar electrode configuration can be adopted to achieve better selectivity in DBS. The tripole consists of a central cathode and two lateral anodes. The currents through the anodes are set by two complementary current sources. By varying the ratio between the amplitude of the anodic currents, the current can be steered toward one anode, while keeping the cathodic current constant. In this paper we present the design of a current-steering tripolar current source in 0.35μm CMOS technology. The current source is capable of delivering cathodic currents up to 1.5mA and generate exponential and quasi-trapezoidal pulses needed for anodal blocking. The average mismatch between sourcing and sinking currents is in the order of 0.4% and the output compliance ranges between 6.1V and 11.15V for a 12V supply, when the maximum and minimum anodic currents are supplied, respectively.

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一种用于深部脑刺激的电流转向植入式电场转移刺激器的设计

在脑深部电刺激(DBS)过程中对电场分布进行主动控制，可以使刺激场更好地聚焦于目标区域，有利于提高神经的选择性，减少模拟非目标区域产生的副作用。采用电流导向的三极电极结构可以在DBS中获得更好的选择性。三极由一个中心阴极和两个侧阳极组成。通过阳极的电流由两个互补的电流源设定。通过改变阳极电流振幅之间的比率，电流可以被引导到一个阳极，同时保持阴极电流恒定。本文提出了一种基于0.35μm CMOS工艺的电流导向三极电流源的设计。电流源能够提供高达1.5mA的阴极电流，并产生阳极阻断所需的指数和准梯形脉冲。当提供最大和最小阳极电流时，源电流和下沉电流之间的平均失配约为0.4%，对于12V电源，输出符合性范围在6.1V和11.15V之间。

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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2010 Biomedical Circuits and Systems Conference (BioCAS)

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