Fabrication and Characterization of 3D Microelectrode Arrays (3D MEAS) with Tri-Modal (Electrical, Optical, and Microfluidic) Interrogation of Electrogenic Cell Constructs

Julia Freitas Orico, A. Kundu, Charles M. Didier, Alexander Bosak, M. J. Moore, S. Rajaraman
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Abstract

We present a polymer and metal-based microfabrication technology toward 3D Microelectrode Arrays (3D MEAs) with tri-modal functionality for obtaining simultaneous data sets comprising electrical, optical and microfluidic markers from a variety of electrogenic cellular constructs. 3D MEAs are the next generation interfaces to transduce multi-modal data sets from the burgeoning field of “organ-on-a-chip” in vitro modeling of biological functions. The microfabrication process is fully characterized for low and higher density 3D electrodes/ µF ports along with full spectrum impedance showcasing the ability to control the 3D microelectrode size. Further the material set used in the microfabrication process is characterized for biological metrics through both a novel transparency assay along with a biocompatibility assay with an electrogenic cell culture system. Lastly, rapid neuronal spheroid attachment to the 3D microfluidic ports of the tri-modal 3D MEA is demonstrated successfully.
三维微电极阵列(3D MEAS)的制备和表征与电致细胞结构的三模态(电、光学和微流体)询问
我们提出了一种基于聚合物和金属的3D微电极阵列(3D MEAs)微加工技术,该技术具有三模态功能,可同时获得来自各种电致细胞结构的包括电、光学和微流体标记的数据集。3D mea是下一代接口,用于从新兴的“器官芯片”领域转换多模态数据集,用于体外生物功能建模。微加工工艺具有低密度和高密度3D电极/µF端口以及全谱阻抗的特点,显示了控制3D微电极尺寸的能力。此外,微制造工艺中使用的材料集通过新型透明度测定以及电致细胞培养系统的生物相容性测定具有生物计量的特征。最后,成功地演示了神经元球体在三模态三维MEA的三维微流控端口上的快速附着。
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