Optogenetic stimulation recruits cortical neurons in a morphology-dependent manner.

IF 4.4 2区 医学 Q1 NEUROSCIENCES
David Berling, Luca Baroni, Antoine Chaffiol, Gregory Gauvain, Serge Picaud, Ján Antolík
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引用次数: 0

Abstract

Single-photon optogenetics enables precise, cell-type-specific modulation of neuronal circuits, making it a crucial tool in neuroscience. Its miniaturization in the form of fully implantable wide-field stimulator arrays enables long-term interrogation of cortical circuits and bares promise for Brain-Machine Interfaces for sensory and motor function restoration. However, achieving selective activation of functional cortical representations poses a challenge, as studies show that targeted optogenetic stimulation results in activity spread beyond one functional domain. While recurrent network mechanisms contribute to activity spread, here we demonstrate with detailed simulations of isolated pyramidal neurons from cat of unknown sex that already neuron morphology causes a complex spread of optogenetic activity at the scale of one cortical column. Since the shape of a neuron impacts its optogenetic response, we find that a single stimulator at the cortical surface recruits a complex spatial distribution of neurons that can be inhomogeneous and vary with stimulation intensity and neuronal morphology across layers. We explore strategies to enhance stimulation precision, finding that optimizing stimulator optics may offer more significant improvements than preferentially somatic expression of the opsin through genetic targeting. Our results indicate that, with the right optical setup, single-photon optogenetics can precisely activate isolated neurons at the scale of functional cortical domains spanning several hundred micrometers.Significance Statement Sensory features, such as the position or orientation of a visual stimulus, are mapped onto the surface of cortex as functional domains. Their selective activation, that may enable eliciting complex percepts, is intensively pursued for basic science and clinical applications. However, delivery of light into one functional domain in optogenetically transfected cortex results in complex, widespread neuronal activity, spreading beyond the targeted domain. Our computational study reveals that neuron morphology contributes to this diffuse response in a cortical-layer and intensity-dependent manner. We show that enhancing the stimulator optics is more effective than soma-targeting of the opsin in increasing spatial precision of stimulation. Our simulations provide insights for designing optogenetic stimulation protocols and hardware to achieve selective activation of functional domains.

光遗传刺激以形态依赖的方式招募皮层神经元
单光子光遗传学能够对神经元回路进行精确的、针对特定细胞类型的调控,是神经科学领域的重要工具。单光子光遗传学以可完全植入的宽场刺激器阵列的形式实现了微型化,从而能够对皮层电路进行长期检查,并为恢复感觉和运动功能的脑机接口带来了希望。然而,实现对大脑皮层功能表征的选择性激活是一项挑战,因为研究表明,有针对性的光遗传刺激会导致活动扩散到一个功能域之外。虽然递归网络机制有助于活动扩散,但我们在这里通过对性别不明猫的分离锥体神经元进行详细模拟,证明神经元形态已经导致光遗传活动在一个皮质列的范围内复杂扩散。由于神经元的形状会影响其光遗传学响应,我们发现皮层表面的单个刺激器会招募到复杂的神经元空间分布,这种分布可能是不均匀的,并随着刺激强度和神经元形态的不同而变化。我们探索了提高刺激精确度的策略,发现优化刺激器的光学特性可能比通过基因靶向优先体表表达蛋白更能显著提高刺激精确度。我们的研究结果表明,通过正确的光学设置,单光子光遗传学可以在跨越数百微米的皮层功能域范围内精确激活孤立的神经元。 意义声明 感觉特征,如视觉刺激的位置或方向,作为功能域映射到皮层表面。选择性激活这些功能域可激发复杂的知觉,因此在基础科学和临床应用方面受到广泛关注。然而,在光遗传学转染的大脑皮层中,将光传递到一个功能域会导致复杂、广泛的神经元活动,并扩散到目标域之外。我们的计算研究发现,神经元形态以皮质层和强度依赖的方式促成了这种扩散反应。我们的研究表明,在提高刺激的空间精确度方面,增强刺激器的光学性能比靶向蛋白的体瘤更有效。我们的模拟为设计光遗传刺激方案和硬件以实现选择性激活功能域提供了启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Neuroscience
Journal of Neuroscience 医学-神经科学
CiteScore
9.30
自引率
3.80%
发文量
1164
审稿时长
12 months
期刊介绍: JNeurosci (ISSN 0270-6474) is an official journal of the Society for Neuroscience. It is published weekly by the Society, fifty weeks a year, one volume a year. JNeurosci publishes papers on a broad range of topics of general interest to those working on the nervous system. Authors now have an Open Choice option for their published articles
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