Regulation of arousal and performance of a healthy non-human primate using closed-loop central thalamic deep brain stimulation.

Jonathan L Baker, Robert Toth, Alceste Deli, Mayela Zamora, John E Fleming, Moaad Benjaber, Dana Goerzen, Jae-Wook Ryou, Keith P Purpura, Nicholas D Schiff, Timothy Denison
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Abstract

Application of closed-loop approaches in systems neuroscience and brain-computer interfaces holds great promise for revolutionizing our understanding of the brain and for developing novel neuromodulation strategies to restore lost function. The anterior forebrain mesocircuit (AFM) of the mammalian brain is hypothesized to underlie arousal regulation of the cortex and striatum, and support cognitive functions during wakefulness. Dysfunction of arousal regulation is hypothesized to contribute to cognitive dysfunctions in various neurological disorders, and most prominently in patients following traumatic brain injury (TBI). Several clinical studies have explored the use of daily central thalamic deep brain stimulation (CT-DBS) within the AFM to restore consciousness and executive attention in TBI patients. In this study, we explored the use of closed-loop CT-DBS in order to episodically regulate arousal of the AFM of a healthy non-human primate (NHP) with the goal of restoring behavioral performance. We used pupillometry and near real-time analysis of ECoG signals to episodically initiate closed-loop CT-DBS and here we report on our ability to enhance arousal and restore the animal's performance. The initial computer based approach was then experimentally validated using a customized clinical-grade DBS device, the DyNeuMo-X, a bi-directional research platform used for rapidly testing closed-loop DBS. The successful implementation of the DyNeuMo-X in a healthy NHP supports ongoing clinical trials employing the internal DyNeuMo system (NCT05437393, NCT05197816) and our goal of developing and accelerating the deployment of novel neuromodulation approaches to treat cognitive dysfunction in patients with structural brain injuries and other etiologies.

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使用闭环中央丘脑深部脑刺激调节健康非人类灵长类动物的觉醒和表现。
闭环方法在系统神经科学和脑机接口中的应用为彻底改变我们对大脑的理解和开发新的神经调节策略来恢复失去的功能提供了巨大的希望。哺乳动物大脑的前前脑中脑回路(AFM)被假设为皮层和纹状体觉醒调节的基础,并支持清醒时的认知功能。唤醒调节功能障碍被认为会导致各种神经系统疾病的认知功能障碍,尤其是在创伤性脑损伤(TBI)患者中。一些临床研究已经探索了在AFM中使用每日中央丘脑深部脑刺激(CT-DBS)来恢复TBI患者的意识和执行注意力。在这项研究中,我们探索了使用闭环CT-DBS来间歇性地调节健康非人灵长类动物(NHP)的AFM唤醒,以恢复行为表现。我们使用瞳孔测量和近实时的ECoG信号分析来间歇性地启动闭环CT-DBS,在这里我们报告了我们增强唤醒和恢复动物表现的能力。最初的基于计算机的方法随后使用定制的临床级DBS设备dypneumo - x进行了实验验证,dypneumo - x是一种用于快速测试闭环DBS的双向研究平台。DyNeuMo内部系统(NCT05437393, NCT05197816)的临床试验正在进行中,DyNeuMo- x在健康的NHP患者中的成功实施支持了我们开发和加速部署新型神经调节方法来治疗结构性脑损伤和其他病因患者的认知功能障碍的目标。
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Regulation of arousal and performance of a healthy non-human primate using closed-loop central thalamic deep brain stimulation. The Design of Brainstem Interfaces: Characterisation of Physiological Artefacts and Implications for Closed-loop Algorithms. Medial Tractography Analysis (MeTA) for White Matter Population Analyses Across Datasets Inferring Pyramidal Neuron Morphology using EAP Data. Reverse engineering information processing in lateral amygdala during auditory tones.
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