用于控制心率的迷走神经闭环多模态神经调控技术

Shane A Bender, David B Green, Kevin L Kilgore, Niloy Bhadra, Jeffery L Ardell, Tina L Vrabec
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引用次数: 0

摘要

利用电流调节神经元以实现自主神经调节,需要同时具备上调和下调神经系统的能力。采用这种神经电调控的植入系统还需要实时适应自律神经状态的变化。以 1-30 赫兹的频率刺激自律神经是一种行之有效的增加神经活动的技术。迷走神经刺激(VNS)已被证明对频率调整很敏感,与振幅调制相比,频率调整可用于更精确地控制效果。千赫兹频率交流电(KHFAC)是一种行之有效的阻断动作电位传导以减少神经活动的技术。此外,KHFAC 还可以通过简单的振幅调制进行可靠调制。虽然常用的闭环控制器种类繁多,但许多传统方法都不能很好地应对长时间的系统延迟或不连续性。模糊逻辑控制(FLC)是一种基于状态的控制器,它可以用语言描述系统的不连续性,然后将状态转换转化为连续的输出信号。在我们的研究中,迷走神经上放置了一个双极电极,并由模糊逻辑控制器控制,以提供刺激和 KHFAC 来控制心率。模糊逻辑控制器既能将心率变为选定值,又能在生理扰动时将心率保持在恒定值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Closed-Loop Multimodal Neuromodulation of Vagus Nerve for Control of Heart Rate.

The use of electrical current to modulate neurons for autonomic regulation requires the ability to both up-regulate and down-regulate the nervous system. An implanted system employing this electrical neuromodulation would also need to adapt to changes in autonomic state in real-time. Stimulation of autonomic nerves at frequencies in the range 1-30 Hz has been a well-established technique for increasing neural activity. Vagus nerve stimulation (VNS) has been shown to be sensitive to frequency adjustments, which can be used to more precisely control the effect as compared to amplitude modulation. Kilohertz frequency alternating current (KHFAC) is a proven technique for blocking action potential conduction to reduce neural activity. Additionally, KHFAC can be reliably modulated by simple amplitude modulation. Although there are many types of commonly used closed-loop controllers, many conventional methods do not respond well to long system delays or discontinuities. Fuzzy logic control (FLC) is a state-based controller that can describe the discontinuities of the system linguistically and then translate the state transition to a continuous output signal. In our preparation, a single bipolar electrode was placed on the vagus nerve and controlled by a fuzzy logic controller to deliver both stimulation and KHFAC to control heart rate. The FLC was able to both change the heart rate to selected values and maintain the heart rate at a constant value in response to a physiological perturbation.

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