A 3D-printed modular implant for extracellular recordings

IF 2.7 4区医学 Q2 BIOCHEMICAL RESEARCH METHODS

Journal of Neuroscience Methods Pub Date : 2025-02-27 DOI:10.1016/j.jneumeth.2025.110407

Dorian Röders , Jesus J. Ballesteros , Celil Semih Sevincik , Sara Santos Silva , Luca Bürgel , Bilal Abbas , Yannik Neukirch , Roland Pusch , Jonas Rose

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引用次数: 0

Abstract

Background

Chronic implants for neural data acquisition must meet several criteria that can be difficult to integrate. Surgical procedures should be as short as possible to reduce unnecessary stress and risks, yet implants must precisely fit to the location of interest and last long periods of time. Implants also must be lightweight but stable enough to withstand the subject’s daily life and experimental needs.

New method

Here we introduce a novel, 3D-printed and open-source modular implant. Our modular design philosophy allows altering parts of the implant either before implantation or later, during the course of experiments. The implant consists of a base individually designed, for instance using an MRI of the subject for an exact skull fit. This base remains permanently on the subject and can contain multiple sites for craniotomies, microdrives and head stage connectors. All movable components (drives with probes, connectors, reference/ground points) are securely screwed onto this base, allowing for replacement and recovery.

Results

After implantation of the bases, self-made microdrives carrying commercial silicon probes were implanted. Once the experimental goals were achieved, they were recovered for further use. Should the quality of the data decrease during the experimental period, the components were replaced, allowing for the experimentation to continue. On an exemplary free-moving subject, under wireless electrophysiological data collection, we reliably obtained single and multi unit data up to 86 days after a silicon probe implantation. In this specific case, after this time we successfully substituted the components and collected similar quality data for additional 11 days.

Comparison with existing methods

Our approach allows to remove, reposition and exchange components during minimally invasive procedures, not requiring new incisions, bone drilling (unless new craniotomies are planned sequentially) or removal of dental cement or glue structures. Splitting complex implantations into multiple shorter procedures reduce the risks inherent to long surgical procedures. A careful plan of action allows to re-use and reduce subject's usage.

Conclusion

This novel approach reduces the duration of surgical procedures. It allows for minimally invasive follow-up procedures, including component replacements between experiments. The design is stable, proven to yield good results, in a very long-term period. This approach increases the chance of successful long experimental paradigms, and help reducing the use of subjects.

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用于细胞外记录的3d打印模块化植入物。

背景：用于神经数据采集的慢性植入物必须满足几个难以整合的标准。手术过程应尽可能短，以减少不必要的压力和风险，但植入物必须精确地适合感兴趣的位置，并持续很长时间。植入物还必须重量轻但足够稳定，以承受受试者的日常生活和实验需要。新方法：在这里我们介绍一种新颖的，3d打印和开源的模块化植入物。我们的模块化设计理念允许在植入之前或之后的实验过程中改变植入物的部分。植入物由一个单独设计的底座组成，例如使用受试者的核磁共振成像来精确匹配头骨。该基地将永久保留在主体上，并可包含多个用于颅骨切开术、微驱动器和头级连接器的位置。所有可移动组件（带探头、连接器、参考/接地点的驱动器）都牢固地拧在这个底座上，允许更换和恢复。结果：植入基底后，植入自制微型驱动器，携带商业硅探针。一旦达到实验目标，它们就会被回收以供进一步使用。如果在实验期间数据质量下降，则更换组件，允许实验继续进行。在一个示例性的自由移动受试者上，在无线电生理数据收集下，我们可靠地获得了硅探针植入后长达86天的单单元和多单元数据。在这个特定的案例中，在此之后，我们成功地替换了组件，并在另外11天内收集了类似的质量数据。与现有方法的比较：我们的方法允许在微创手术过程中移除，重新定位和交换组件，不需要新的切口，骨钻孔（除非计划依次进行新的开颅手术）或去除牙水泥或胶结构。将复杂的植入手术分割成多个较短的手术过程，可以降低长期手术过程所固有的风险。一个仔细的行动计划允许重复使用并减少受试者的使用。结论：这种新入路缩短了手术时间。它允许微创随访程序，包括实验之间的部件更换。该设计是稳定的，在很长一段时间内被证明可以产生良好的结果。这种方法增加了长期实验范例成功的机会，并有助于减少受试者的使用。

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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来源期刊

Journal of Neuroscience Methods 医学-神经科学

CiteScore

7.10

自引率

3.30%

发文量

226

审稿时长

52 days

期刊介绍： The Journal of Neuroscience Methods publishes papers that describe new methods that are specifically for neuroscience research conducted in invertebrates, vertebrates or in man. Major methodological improvements or important refinements of established neuroscience methods are also considered for publication. The Journal''s Scope includes all aspects of contemporary neuroscience research, including anatomical, behavioural, biochemical, cellular, computational, molecular, invasive and non-invasive imaging, optogenetic, and physiological research investigations.