Combining gamma neuromodulation and robotic rehabilitation after a stroke restores parvalbumin interneuron dynamics and improves motor recovery in mice.

IF 7.2 1区生物学 Q1 Agricultural and Biological Sciences

PLoS Biology Pub Date : 2025-10-14 eCollection Date: 2025-10-01 DOI:10.1371/journal.pbio.3002806

Livia Vignozzi, Francesca Macchi, Elena Montagni, Maria Pasquini, Alessandra Martello, Antea Minetti, Éléa Coulomb, Anna Letizia Allegra Mascaro, Silvestro Micera, Matteo Caleo, Cristina Spalletti

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引用次数: 0

Abstract

Stroke is a leading cause of long-term disability, frequently associated with persistent motor deficits. Gamma band oscillations, generated by synchronous discharge of parvalbumin-positive interneurons (PV-INs), are critically affected after stroke in humans and animals. Both gamma band and PV-INs play a key role in motor function, thus representing a promising target for poststroke neurorehabilitation. Noninvasive neuromodulatory approaches are considered a safe intervention and can be used for this purpose. Here, we present a novel, clinically relevant, noninvasive, and well-tolerated sub-acute treatment combining robotic rehabilitation with advanced neuromodulation techniques, validated in a mouse model of ischemic injury. During the sub-acute poststroke phase, we scored profound deficits in motor-related gamma band activity in the perilesional cortex. These deficits were accompanied by reduced PV-IN firing rates and increased functional connectivity, both at the perilesional and at the whole-cortex levels. Therefore, we tested the therapeutic potential of coupling robotic rehabilitation with optogenetic PV-IN-driven gamma band stimulation in a subacute poststroke phase during motor training to reinforce the efficacy of the treatment. Frequency-specific movement-related gamma band stimulation, when combined with physical training, significantly improved forelimb motor function. More importantly, by pairing robotic rehabilitation with a clinical-like noninvasive 40 Hz transcranial Alternating Current Stimulation, we achieved similar motor improvements mediated by the effective restoring of movement-related gamma band power, improvement of PV-IN maladaptive network dynamics, and increased PV-IN connections in premotor cortex. Our research introduces a new understanding of the role of parvalbumin-interneurons in poststroke impairment and recovery. These results highlight the synergistic potential of combining perilesional gamma band stimulation with robotic rehabilitation as a promising and realistic therapeutic approach for stroke patients.

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结合伽马神经调节和机器人康复中风后恢复小白蛋白中间神经元动力学和改善运动恢复小鼠。

中风是导致长期残疾的主要原因，常伴有持续性运动障碍。由细小蛋白阳性中间神经元（PV-INs）同步放电产生的伽马带振荡在人类和动物中风后受到严重影响。伽马带和PV-INs都在运动功能中起关键作用，因此代表了卒中后神经康复的一个有希望的目标。无创神经调节入路被认为是一种安全的干预，可用于此目的。在这里，我们提出了一种新的、临床相关的、无创的、耐受性良好的亚急性治疗方法，将机器人康复与先进的神经调节技术相结合，并在小鼠缺血性损伤模型中得到了验证。在亚急性中风后阶段，我们发现病灶周围皮层运动相关的伽马带活动存在严重缺陷。这些缺陷伴随着PV-IN放电率的降低和功能连通性的增加，在病灶周围和整个皮层水平都是如此。因此，我们在运动训练期间的亚急性脑卒中后阶段测试了机器人康复和光遗传pv - in驱动的伽马带刺激相结合的治疗潜力，以增强治疗效果。频率特异性运动相关的伽玛带刺激，当与体能训练相结合时，可显著改善前肢运动功能。更重要的是，通过将机器人康复与临床应用的无创40 Hz经颅交流电刺激相结合，我们通过有效恢复运动相关的伽马波段功率、改善PV-IN不适应网络动力学以及增加运动前皮层的PV-IN连接，实现了类似的运动改善。我们的研究介绍了小白蛋白中间神经元在脑卒中后损伤和恢复中的作用的新认识。这些结果强调了将病灶周围伽玛带刺激与机器人康复相结合的协同潜力，作为一种有希望和现实的治疗中风患者的方法。

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

PLoS Biology BIOCHEMISTRY & MOLECULAR BIOLOGY-BIOLOGY

CiteScore

15.40

自引率

2.00%

发文量

359

审稿时长

3-8 weeks

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