Spatially and temporally mismatched blood flow and neuronal activity by high-intensity intracortical microstimulation

IF 7.6 1区医学 Q1 CLINICAL NEUROLOGY

Brain Stimulation Pub Date : 2025-04-15 DOI:10.1016/j.brs.2025.04.015

Alexandra Katherine Isis Yonza , Lechan Tao , Xiao Zhang , Dmitry Postnov , Krzysztof Kucharz , Barbara Lind , Antonios Asiminas , Anpan Han , Victor Sonego , Kayeon Kim , Changsi Cai

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引用次数: 0

Abstract

Introduction

Intracortial microstimulation (ICMS) is widely used in neuroprosthetic brain-machine interfacing, particularly in restoring lost sensory and motor functions. Spiking neuronal activity requires increased cerebral blood flow to meet local metabolic demands, a process conventionally denoted as neurovascular coupling (NVC). However, it is unknown precisely how and to what extent ICMS elicits NVC and how the neuronal and blood flow responses to ICMS correlate. Suboptimal NVC by ICMS may compromise oxygen and energy delivery to the activated neurons thus impair neuroprosthetic functionality.

Material and method

We used wide-field imaging (WFI), laser speckle imaging (LSI) and two-photon microscopy (TPM) to study living, transgenic mice expressing calcium (Ca²⁺) fluorescent indicators in either neurons or vascular mural cells (VMC), as well as to measure vascular inner lumen diameters.

Result

By testing a range of stimulation amplitudes and examining cortical tissue responses at different distances from the stimulating electrode tip, we found that high stimulation intensities (≥50 μA) elicited a spatial and temporal neurovascular decoupling in regions most adjacent to electrode tip (<200 μm), with significantly delayed onset times of blood flow responses to ICMS and compromised maximum blood flow increases. We attribute these effects respectively to delayed Ca²⁺ signalling and decreased Ca²⁺ sensitivity in VMCs.

Conclusion

Our study offers new insights into ICMS-associated neuronal and vascular physiology with potentially critical implications towards the optimal design of ICMS in neuroprosthetic therapies: low intensities preserve NVC; high intensities disrupt NVC responses and potentially precipitate blood supply deficits.

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高强度皮质内微刺激在空间和时间上不匹配的血流和神经元活动

皮层内微刺激（ICMS）广泛应用于神经假体脑机接口，特别是在恢复失去的感觉和运动功能方面。神经元活动尖峰需要增加脑血流量来满足局部代谢需求，这一过程通常被称为神经血管耦合（NVC）。然而，目前尚不清楚ICMS如何以及在多大程度上引发NVC，以及神经元和血流对ICMS的反应如何相关。ICMS造成的非最佳NVC可能会损害向激活神经元的氧气和能量输送，从而损害神经假肢的功能。材料和方法我们利用宽视场成像（WFI）、激光散斑成像（LSI）和双光子显微镜（TPM）研究了在神经元或血管壁细胞（VMC）中表达钙（Ca2+）荧光指标的转基因活小鼠，并测量了血管内腔直径。结果通过对刺激幅度范围的测试和对距离刺激电极尖端不同距离的皮质组织反应的检测，我们发现高刺激强度（≥50 μA）在最靠近电极尖端的区域（<200 μA）引发了时空神经血管解耦，显著延迟了ICMS的血流量响应时间，降低了最大血流量的增加。我们将这些影响分别归因于延迟Ca2+信号传导和vmc中Ca2+敏感性降低。我们的研究为ICMS相关的神经元和血管生理学提供了新的见解，对ICMS在神经修复治疗中的优化设计具有潜在的重要意义：低强度保存NVC；高强度会破坏NVC反应，并可能导致血供不足。

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

Brain Stimulation 医学-临床神经学

CiteScore

13.10

自引率

9.10%

发文量

256

审稿时长

72 days

期刊介绍： Brain Stimulation publishes on the entire field of brain stimulation, including noninvasive and invasive techniques and technologies that alter brain function through the use of electrical, magnetic, radiowave, or focally targeted pharmacologic stimulation. Brain Stimulation aims to be the premier journal for publication of original research in the field of neuromodulation. The journal includes: a) Original articles; b) Short Communications; c) Invited and original reviews; d) Technology and methodological perspectives (reviews of new devices, description of new methods, etc.); and e) Letters to the Editor. Special issues of the journal will be considered based on scientific merit.