DyNeuMo Mk-2:一种具有响应性刺激的生物钟锁定神经调节剂。

Robert Toth, Mayela Zamora, Jon Ottaway, Tom Gillbe, Sean Martin, Moaad Benjaber, Guy Lamb, Tara Noone, Barry Taylor, Alceste Deli, Vaclav Kremen, Gregory Worrell, Timothy G Constandinou, Ivor Gillbe, Stefan De Wachter, Charles Knowles, Andrew Sharott, Antonio Valentin, Alexander L Green, Timothy Denison
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引用次数: 0

摘要

脑深部刺激(DBS)治疗帕金森病、原发性震颤和癫痫是一种公认的姑息治疗方法。DBS使用电神经调控来抑制症状。目前的大多数系统都提供连续模式的固定刺激,临床随访以完善限制在正常办公时间的设置。这种管理策略的一个问题是,刺激对昼夜节律的影响,即睡眠-觉醒节律没有得到充分考虑;无论是在装置设计中还是在临床随访中。由于设备可以植入耦合到网状激活网络的大脑目标中,因此对清醒和睡眠的影响可能是显著的。随着新目标的探索,这个问题可能会加剧,有可能产生与环境影响脱钩的夹带信号。为了解决这个问题,我们为DBS设计了一种新的脑机接口,该接口将基于昼夜节律的慢速自适应刺激模式与快速反应刺激途径相结合,用于癫痫发作管理。为探索多时间尺度自动自适应算法的实用性,进行了首次人体研究试验的准备工作,根据ISO风险管理标准进行了设计和原型设计,确保了患者的安全。最终目的是在嵌入脑机接口和神经调控技术的算法中更广泛地解释时间生物学。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

DyNeuMo Mk-2: An Investigational Circadian-Locked Neuromodulator with Responsive Stimulation for Applied Chronobiology.

DyNeuMo Mk-2: An Investigational Circadian-Locked Neuromodulator with Responsive Stimulation for Applied Chronobiology.

DyNeuMo Mk-2: An Investigational Circadian-Locked Neuromodulator with Responsive Stimulation for Applied Chronobiology.

DyNeuMo Mk-2: An Investigational Circadian-Locked Neuromodulator with Responsive Stimulation for Applied Chronobiology.

Deep brain stimulation (DBS) for Parkinson's disease, essential tremor and epilepsy is an established palliative treatment. DBS uses electrical neuromodulation to suppress symptoms. Most current systems provide a continuous pattern of fixed stimulation, with clinical follow-ups to refine settings constrained to normal office hours. An issue with this management strategy is that the impact of stimulation on circadian, i.e. sleep-wake, rhythms is not fully considered; either in the device design or in the clinical follow-up. Since devices can be implanted in brain targets that couple into the reticular activating network, impact on wakefulness and sleep can be significant. This issue will likely grow as new targets are explored, with the potential to create entraining signals that are uncoupled from environmental influences. To address this issue, we have designed a new brain-machine-interface for DBS that combines a slow-adaptive circadian-based stimulation pattern with a fast-acting pathway for responsive stimulation, demonstrated here for seizure management. In preparation for first-in-human research trials to explore the utility of multi-timescale automated adaptive algorithms, design and prototyping was carried out in line with ISO risk management standards, ensuring patient safety. The ultimate aim is to account for chronobiology within the algorithms embedded in brain-machine-interfaces and in neuromodulation technology more broadly.

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