Christopher A. Werley, Ted Brookings, Hansini Upadhyay, Luis A. Williams, Owen B. McManus, Graham T. Dempsey
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引用次数: 26
Abstract
A key challenge for establishing a phenotypic screen for neuronal excitability is measurement of membrane potential changes with high throughput and accuracy. Most approaches for probing excitability rely on low-throughput, invasive methods or lack cell-specific information. These limitations stimulated the development of novel strategies for characterizing the electrical properties of cultured neurons. Among these was the development of optogenetic technologies (Optopatch) that allow for stimulation and recording of membrane voltage signals from cultured neurons with single-cell sensitivity and millisecond temporal resolution. Neuronal activity is elicited using blue light activation of the channelrhodopsin variant ‘CheRiff’. Action potentials and synaptic signals are measured with ‘QuasAr’, a rapid and sensitive voltage-indicating protein with near-infrared fluorescence that scales proportionately with transmembrane potential. This integrated technology of optical stimulation and recording of electrical signals enables investigation of neuronal electrical function with unprecedented scale and precision. © 2017 by John Wiley & Sons, Inc.
神经元疾病建模和药理表征的全光电生理学
建立神经元兴奋性表型筛选的关键挑战是高通量和准确性地测量膜电位变化。大多数探测兴奋性的方法依赖于低通量、侵入性方法或缺乏细胞特异性信息。这些限制刺激了表征培养神经元电特性的新策略的发展。其中包括光遗传技术(Optopatch)的发展,该技术允许刺激和记录来自培养神经元的膜电压信号,具有单细胞灵敏度和毫秒级的时间分辨率。使用蓝光激活通道视紫红质变体“CheRiff”来激发神经元活动。动作电位和突触信号用“类星体”来测量,类星体是一种快速而敏感的电压指示蛋白,具有近红外荧光,与跨膜电位成比例。这种光刺激和电信号记录的集成技术使研究神经元电功能具有前所未有的规模和精度。©2017 by John Wiley &儿子,Inc。
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