Technical Development of Two-Photon Optogenetic Stimulation and Its Potential Application to Brain-Machine Interfaces
Riichiro Hira, Yoshikazu Isomura

TL;DR
This paper reviews the development of two-photon optogenetic stimulation techniques, highlighting their potential for precise neural control and integration into brain-machine interfaces, while discussing technical challenges and future directions.
Contribution
It provides a comprehensive overview of recent advancements in two-photon optogenetics and explores their application potential in brain-machine interfaces.
Findings
Three main strategies: spiral scanning, temporal focusing, 3D holography.
Enhanced ability to target multiple neurons with high precision.
Discussion of technical challenges for clinical and research applications.
Abstract
Over the past decade, techniques enabling bidirectional modulation of neuronal activity with single cell precision have rapidly advanced in the form of two-photon optogenetic stimulation. Unlike conventional electrophysiological approaches or one-photon optogenetics, which inevitably activate many neurons surrounding the target, two-photon optogenetics can drive hundreds of specifically targeted neurons simultaneously, with stimulation patterns that can be flexibly and rapidly reconfigured. In this review, we trace the development of two-photon optogenetic stimulation, focusing on its progression toward implementations in large field of view two-photon microscopes capable of targeted multi neuron control. We highlight three principal strategies: spiral scanning, temporal focusing, and three-dimensional computer-generated holography (3D CGH), along with their combinations, which together…
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Taxonomy
TopicsPhotoreceptor and optogenetics research · Neuroscience and Neural Engineering · Photochromic and Fluorescence Chemistry
