High-Density Multilayer Graphene Microelectrode Arrays for Optogenetic Electrophysiology in Human Embryonic Kidney Cells

2020 Device Research Conference (DRC) Pub Date : 2020-06-01 DOI:10.1109/DRC50226.2020.9135174

Jinyoung Park, D. Mao, Yaowei Xie, Z. Xiong, Guangyu Xu

{"title":"High-Density Multilayer Graphene Microelectrode Arrays for Optogenetic Electrophysiology in Human Embryonic Kidney Cells","authors":"Jinyoung Park, D. Mao, Yaowei Xie, Z. Xiong, Guangyu Xu","doi":"10.1109/DRC50226.2020.9135174","DOIUrl":null,"url":null,"abstract":"Optogenetic electrophysiology offers high precision cellular analysis by electrophysiological recording under optogenetic control [1] , [2] . Such studies often use microelectrode arrays (MEA) to obtain massively parallel recording from densely packed cells. Among the MEA materials, graphene has been suggested to be well suited for optogenetic electrophysiology [1] - [3] , enabling transparent, flexible, and low-noise MEAs for in vivo recording of the local field potential (LFP) [1] . To date, most graphene microelectrodes were 25-300 μm in size to achieve high signal-to-noise ratios, and placed in a 150-900 μm pitch for single-unit recording [1] , [3] . Such device dimension however has limited spatial resolution compared to closely-packed silicon MEAs [4] , and cannot offer spatial oversampling of the cell activity. Here we present a 28-μm pitched multilayer graphene MEA with 13-μm sized electrodes, the smallest in literature, for high-density optogenetic electrophysiology in human embryonic kidney (HEK) cells. Our MEA was made of CVD-grown multilayer graphene for its low sheet resistance, which was one-time transferred onto a Si/SiO 2 substrate, instead of layer-by-layer transfer steps (see [2] ) that may increase the electrode impedance by contaminants. Our electrodes had 2 MΩ impedance at 1 kHz (2.38 Ω•cm 2 ) in electrochemical impedance spectroscopy (EIS), 6 times smaller than those made by layer-by-layer transfer steps if they were made in the same size [2] . Our MEA was able to record optogenetically evoked extracellular signals in HEK cells co-expressed with opsins ( ChR2 ) and Ca 2+ reporters ( jRCAMP1a ) [5] . The signal amplitude increased with the intensity (not the duration) of the optogenetic stimulus, and qualitatively matched the position of optogenetically responsive cells (confirmed by jRCAMP1a imaging). Our work suggests the possible use of multiplayer graphene MEA for optogenetic electrophysiology in HEK cells.","PeriodicalId":397182,"journal":{"name":"2020 Device Research Conference (DRC)","volume":"6 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2020-06-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"2020 Device Research Conference (DRC)","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1109/DRC50226.2020.9135174","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 0

Abstract

Optogenetic electrophysiology offers high precision cellular analysis by electrophysiological recording under optogenetic control [1] , [2] . Such studies often use microelectrode arrays (MEA) to obtain massively parallel recording from densely packed cells. Among the MEA materials, graphene has been suggested to be well suited for optogenetic electrophysiology [1] - [3] , enabling transparent, flexible, and low-noise MEAs for in vivo recording of the local field potential (LFP) [1] . To date, most graphene microelectrodes were 25-300 μm in size to achieve high signal-to-noise ratios, and placed in a 150-900 μm pitch for single-unit recording [1] , [3] . Such device dimension however has limited spatial resolution compared to closely-packed silicon MEAs [4] , and cannot offer spatial oversampling of the cell activity. Here we present a 28-μm pitched multilayer graphene MEA with 13-μm sized electrodes, the smallest in literature, for high-density optogenetic electrophysiology in human embryonic kidney (HEK) cells. Our MEA was made of CVD-grown multilayer graphene for its low sheet resistance, which was one-time transferred onto a Si/SiO 2 substrate, instead of layer-by-layer transfer steps (see [2] ) that may increase the electrode impedance by contaminants. Our electrodes had 2 MΩ impedance at 1 kHz (2.38 Ω•cm 2 ) in electrochemical impedance spectroscopy (EIS), 6 times smaller than those made by layer-by-layer transfer steps if they were made in the same size [2] . Our MEA was able to record optogenetically evoked extracellular signals in HEK cells co-expressed with opsins ( ChR2 ) and Ca 2+ reporters ( jRCAMP1a ) [5] . The signal amplitude increased with the intensity (not the duration) of the optogenetic stimulus, and qualitatively matched the position of optogenetically responsive cells (confirmed by jRCAMP1a imaging). Our work suggests the possible use of multiplayer graphene MEA for optogenetic electrophysiology in HEK cells.

查看原文本刊更多论文

高密度多层石墨烯微电极阵列用于人胚胎肾细胞的光遗传电生理

光遗传电生理在光遗传控制下通过电生理记录提供高精度的细胞分析[1]，[2]。此类研究通常使用微电极阵列(MEA)从密集排列的细胞中获得大量并行记录。在MEA材料中，石墨烯被认为非常适合于光遗传电生理学[1]-[3]，使透明、柔性和低噪声的MEA能够用于局部场电位(LFP)的体内记录[1]。迄今为止，大多数石墨烯微电极的尺寸为25-300 μm，以实现高信噪比，并放置在150-900 μm的间距上进行单单元记录[1]，[3]。然而，与紧密堆积的硅mea相比，这种器件尺寸具有有限的空间分辨率[4]，并且无法提供细胞活性的空间过采样。在这里，我们提出了一个28 μm的多层石墨烯MEA和13 μm大小的电极，这是文献中最小的，用于人胚胎肾(HEK)细胞的高密度光遗传电生理。我们的MEA是由cvd生长的多层石墨烯制成的，因为它具有低片电阻，可以一次性转移到Si/ sio2衬底上，而不是逐层转移步骤(见[2])，这可能会增加污染物对电极阻抗的影响。在电化学阻抗谱(EIS)中，我们的电极在1 kHz (2.38 Ω•cm 2)处具有2 MΩ阻抗，如果以相同的尺寸制作，则比采用逐层转移步骤制作的电极小6倍[2]。我们的MEA能够在与视蛋白(ChR2)和ca2 +报告基因(jRCAMP1a)共表达的HEK细胞中记录光遗传诱发的细胞外信号[5]。信号振幅随光遗传刺激的强度而增加(而不是持续时间)，并且和光遗传应答细胞的位置在质量上匹配(通过jRCAMP1a成像证实)。我们的研究表明，多层石墨烯MEA可能用于HEK细胞的光遗传电生理。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

2020 Device Research Conference (DRC)

自引率

0.00%

发文量