Silicon Optrode with a Micromirror-Tip Providing Tunable Beam Profile During Infrared Neuromodulation of the Rat Neocortex

IF 6.4 3区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY Advanced Materials Technologies Pub Date : 2024-07-07 DOI:10.1002/admt.202400044
Ágoston Csaba Horváth, Ákos Mórocz, Borbála Csomai, Ágnes Szabó, Zsófia Balogh-Lantos, Péter Fürjes, Estilla Zsófia Tóth, Richárd Fiáth, Zoltán Fekete
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Abstract

Infrared (IR) neuromodulation holds an increasing potential in brain research, which is fueled by novel neuroengineering approaches facilitating the exploration of the biophysical mechanism in the microscale. The group lays down the fundamentals of spatially controlled optical manipulation of inherently temperature-sensitive neuronal populations. The concept and in vivo validation of a multifunctional, optical stimulation microdevice is presented, which expands the capabilities of conventional optrodes by coupling IR light through a monolithically integrated parabolic micromirror. Heat distribution in the irradiated volume is experimentally analyzed, and the performance of the integrated electrophysiological recording components of the device is tested in the neocortex of anesthetized rodents. Evoked single-cell responses upon IR irradiation through the novel microtool are evaluated in multiple trials. The safe operation of the implanted device is also presented using immunohistological methods. The results confirm that shift in temperature distribution in the vicinity of the optrode tip can be controlled by the integrated photonic components, and in parallel with the optical stimulation, the device is suitable to interrogate the evoked electrophysiological activity at the single neuron level. The customizable and scalable optrode system provides a new pathway to tailor the location of the heat maximum during infrared neural stimulation.

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在对大鼠神经皮层进行红外神经调制时,带有微镜尖端的硅光学电极可提供可调光束轮廓
红外线(IR)神经调控在脑科学研究中的潜力与日俱增,而新颖的神经工程方法有助于在微观尺度上探索生物物理机制。该研究小组奠定了对固有温度敏感神经元群进行空间控制光学操纵的基础。他们介绍了多功能光学刺激微型装置的概念和体内验证,该装置通过单片集成抛物面微镜耦合红外光,扩展了传统光棒的功能。实验分析了照射体积内的热分布,并在麻醉啮齿动物的新皮质中测试了该装置的集成电生理记录组件的性能。在多个试验中评估了通过新型微型工具进行红外照射时诱发的单细胞反应。此外,还利用免疫组织学方法介绍了植入装置的安全运行情况。结果证实,光电极尖端附近温度分布的变化可由集成光子元件控制,在进行光刺激的同时,该装置还适用于检测单个神经元水平的诱发电生理活动。这种可定制、可扩展的光电极系统为在红外神经刺激过程中定制热量最大值的位置提供了一条新途径。
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来源期刊
Advanced Materials Technologies
Advanced Materials Technologies Materials Science-General Materials Science
CiteScore
10.20
自引率
4.40%
发文量
566
期刊介绍: Advanced Materials Technologies Advanced Materials Technologies is the new home for all technology-related materials applications research, with particular focus on advanced device design, fabrication and integration, as well as new technologies based on novel materials. It bridges the gap between fundamental laboratory research and industry.
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