Acousto-optic deflectors in experimental neuroscience: overview of theory and applications

IF 4.6 Q1 OPTICS Journal of Physics-Photonics Pub Date : 2024-03-11 DOI:10.1088/2515-7647/ad2e0d
Pietro Ricci, Giuseppe Sancataldo, Vladislav Gavryusev, Francesco Saverio Pavone, Peter Saggau, Martí Duocastella
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Abstract

Cutting-edge methodologies and techniques are required to understand complex neuronal dynamics and pathological mechanisms. Among them, optical tools stand out due to their combination of non-invasiveness, speed, and precision. Examples include optical microscopy, capable of characterizing extended neuronal populations in small vertebrates at high spatiotemporal resolution, or all-optical electrophysiology and optogenetics, suitable for direct control of neuronal activity. However, these approaches necessitate progressively higher levels of accuracy, efficiency, and flexibility of illumination for observing fast entangled neuronal events at a millisecond time-scale over large brain regions. A promising solution is the use of acousto-optic deflectors (AODs). Based on exploiting the acousto-optic effects, AODs are high-performance devices that enable rapid and precise light deflection, up to MHz rates. Such high-speed control of light enables unique features, including random-access scanning or parallelized multi-beam illumination. Here, we survey the main applications of AODs in neuroscience, from fluorescence imaging to optogenetics. We also review the theory and physical mechanisms of these devices and describe the main configurations developed to accomplish flexible illumination strategies for a better understanding of brain function.
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实验神经科学中的声光偏转器:理论与应用概述
要了解复杂的神经元动态和病理机制,需要采用最先进的方法和技术。其中,光学工具因其兼具非侵入性、快速性和精确性而脱颖而出。例如,光学显微镜能以高时空分辨率描述小型脊椎动物的扩展神经元群;全光电生理学和光遗传学适合直接控制神经元活动。然而,这些方法需要逐步提高照明的精确度、效率和灵活性,以观测大脑区毫秒级的快速纠缠神经元事件。使用声光偏转器(AOD)是一种很有前途的解决方案。基于声光效应,声光偏转器是一种高性能设备,可实现快速、精确的光偏转,速度可达兆赫。这种光的高速控制实现了独特的功能,包括随机访问扫描或并行多光束照明。在此,我们将介绍 AOD 在神经科学中的主要应用,从荧光成像到光遗传学。我们还回顾了这些设备的理论和物理机制,并介绍了为实现灵活的照明策略以更好地了解大脑功能而开发的主要配置。
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来源期刊
CiteScore
10.70
自引率
0.00%
发文量
27
审稿时长
12 weeks
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