Cooling stimulation on cerebral cortex for epilepsy suppression with integration of micro-invasive electrodes and TE coolers

The 8th Annual IEEE International Conference on Nano/Micro Engineered and Molecular Systems Pub Date : 2013-04-07 DOI:10.1109/NEMS.2013.6559945

J. Chiou, Lei-Chun Chou, S. Tsai, K. Hou, Chih-Wei Chang

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Abstract

Epilepsy suppression with cooling stimulation is the primary purpose for this study. In this dissertation, cooling stimulation was implemented and demonstrated on cerebral cortex of rats. Electrodes with needle structure was designed and fabricated by using MEMS technology to minimize the size of device. A TE cooler was used to create cooling source and it can be control via electrical current. A cooler component was integrated with an electrode and a TE cooler, in addition, a thermal sensor was also combined with it to detect temperature variation, which was affected by cooling cerebral cortex. The cooler components were implanted on surface of cerebral with deep brain stimulation and the thermal sensors were penetrated into cortex to measure temperature variation which can verify the functions of cooler components. In our experimental results, electrodes with needle structure can improve efficiency of epilepsy suppression due to the particular structure. Duration, frequency and average single time of epileptic waveforms were used to identify to performance of suppression.

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微创电极联合TE冷却器对大脑皮层的冷却刺激抑制癫痫

降温刺激抑制癫痫是本研究的主要目的。本论文对大鼠大脑皮层进行了冷却刺激实验。为实现器件尺寸的最小化，采用MEMS技术设计并制作了针状结构电极。采用TE冷却器作为冷却源，并通过电流进行控制。将一个冷却器组件与一个电极和一个TE冷却器集成在一起，并结合一个热传感器来检测大脑皮层冷却对温度变化的影响。通过深部脑刺激将冷却元件植入大脑表面，并将热传感器插入大脑皮层，测量温度变化，验证冷却元件的功能。在我们的实验结果中，针状结构电极由于其特殊的结构，可以提高癫痫抑制的效率。用癫痫波形的持续时间、频率和平均单次时间来识别抑制效果。

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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The 8th Annual IEEE International Conference on Nano/Micro Engineered and Molecular Systems

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