材料科学
微电极
生物医学工程
琼脂糖
微电子
聚乙二醇
胶粘剂
灵活性(工程)
多电极阵列
流离失所(心理学)
聚合物
纳米技术
计算机科学
复合材料
图层(电子)
化学
心理治疗师
物理化学
有机化学
心理学
统计
医学
色谱法
数学
电极
作者
Sarah Felix,Kedar G. Shah,Vanessa Tolosa,Heeral Sheth,Angela Tooker,Terri L. Delima,Shantanu P. Jadhav,Loren M. Frank,Satinderpall S. Pannu
摘要
Microelectrode arrays for neural interface devices that are made of biocompatible thin-film polymer are expected to have extended functional lifetime because the flexible material may minimize adverse tissue response caused by micromotion. However, their flexibility prevents them from being accurately inserted into neural tissue. This article demonstrates a method to temporarily attach a flexible microelectrode probe to a rigid stiffener using biodissolvable polyethylene glycol (PEG) to facilitate precise, surgical insertion of the probe. A unique stiffener design allows for uniform distribution of the PEG adhesive along the length of the probe. Flip-chip bonding, a common tool used in microelectronics packaging, enables accurate and repeatable alignment and attachment of the probe to the stiffener. The probe and stiffener are surgically implanted together, then the PEG is allowed to dissolve so that the stiffener can be extracted leaving the probe in place. Finally, an in vitro test method is used to evaluate stiffener extraction in an agarose gel model of brain tissue. This approach to implantation has proven particularly advantageous for longer flexible probes (>3 mm). It also provides a feasible method to implant dual-sided flexible probes. To date, the technique has been used to obtain various in vivo recording data from the rat cortex.
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