基于柔顺机构的减振神经电极的设计与评估  被引量:2

Physical Design Concepts and Biomechanical Evaluations of a Novel Neural Electrode Abutment with Micromotion-Attenuation Capability Based on Compliant Mechanisms

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作  者:李正伟[1] 马亚坤[1] 张文光[1] 

机构地区:[1]上海交通大学机械系统与振动国家重点实验室,上海200240

出  处:《上海交通大学学报》2015年第12期1888-1892,1906,共6页Journal of Shanghai Jiaotong University

基  金:国家自然科学基金项目(51175334);上海交通大学医工(理)交叉基金项目(YG2013MS06)资助

摘  要:为了提高神经电极长期稳定性,提出基于柔顺结构的新型减振神经电极的设计思路,对其柔性铰链进行建模分析,并采用有限元方法对电极-脑组织界面的微动进行静态分析和模态分析,研究了不同方向微振对电极-脑组织界面力学状态的影响,对新型减振电极与原电极的力学性能进行对比评估.结果显示,新型减振电极可以有效改善微振动环境下的应力状态:在横向微振环境下,有效降低最大应力6.64%;纵向微振环境下,有效降低最大应力4.47%;其二、三阶固有频率为3~8Hz,可避开微振的频率范围.新型减振电极可显著提高电极的减振能力,预期可有效提高电极工作寿命.Micromotion is one of the most important factors that influence the long-term stability of neural electrodes.In order to improve the long-term stability of brain-implanted electrodes,a neural electrode abutment which has the capability of vibration attenuation was developed to control different modes of micromotion in a more effective way.The compliant hinge was studied with the mechanics modeling analysis,and the static and modal mechanical states of neural electrode-brain tissue interface were investigated with finite element methods.The results of the finite element analysis confirmed that the novel neural electrode abutment had the anticipated micromotion-attenuation capability.The proportion of decline of von Mises stress was 4.47% on the longitudinal direction and 6.64% on the lateral direction.The results show that the novel neural electrode abutment is effective in reducing vibration,which has potential capabilities for improving the stability of neural electrodes in a long term.

关 键 词:微电极 柔顺机构 微振 有限元法 

分 类 号:R318.01[医药卫生—生物医学工程]

 

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