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    柔软电子产品为长期的神经记录提供了前所未有的强度和组织层面的灵活性. 这一突破推动了神经科学研究和临床应用的脑计算机接口.

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    科学领域:

    • 神经科学是一个神经科学.
    • 材料科学 材料科学 材料科学
    • 生物医学工程 生物医学工程

    背景情况:

    • 目前的神经记录电子设备缺乏长期大脑植入所需的强度和灵活性.
    • 这种局限性阻碍了可扩展的神经科学研究和临床应用.

    研究的目的:

    • 推出FlexiSoft,一个新的电子平台,集成机械强度和组织层面的灵活性.
    • 为了证明FlexiSoft在稳定,长期的神经信号记录和可定制植入方面的能力.

    主要方法:

    • 开发一个塑料弹性体异构结构电子平台 (FlexiSoft).
    • 机械特性比较FlexiSoft与传统的柔性电子产品.
    • 在体内测试植入强度,深度透和长期神经记录在运动学习任务期间.

    主要成果:

    • 与现有技术相比,FlexiSoft显著提高了机械强度和灵活性.
    • FlexiSoft 探测器证明了成功的植入,重复插入/移除的耐受性,以及厘米尺度的深度透.
    • 从海马和运动皮层启用了稳定,长期的神经记录,揭示了几个月的动态神经活动变化.

    结论:

    • 弗莱西软是一款强大的,组织级的灵活电子平台,推进大脑-计算机接口.
    • 该技术显示出强大的转化潜力,用于神经科学研究和临床应用.
    • 实现了新的曲线植入途径,以进行定制的神经记录.