An Efficient Circuit for Pulsed Magnetic Neural Stimulation

IF 3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Journal of Electromagnetics RF and Microwaves in Medicine and Biology Pub Date : 2023-06-30 DOI:10.1109/JERM.2023.3289155
Peter M. Asbeck;Sravya Alluri;Vincent Leung;Shaghayegh Abbasi;Milan T. Makale
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Abstract

Pulse stimulation of peripheral nerves (PNS) is extensively used in the diagnosis of nerve abnormalities and can be applied for pain mitigation and to promote nerve regrowth. Nerve stimulation via magnetic pulses can provide advantages over conventional electrical stimulation; it obviates the need for electrode contact with the skin and is typically less painful. This work contributes to the development of compact and portable systems for magnetic PNS (M-PNS). To date, M-PNS has largely employed pulse generation systems developed for repetitive transcranial magnetic stimulation (rTMS). A new circuit is demonstrated to generate pulsed magnetic fields that increases induced electric (E) field intensities over those attainable in conventional rTMS systems. The resultant E-field has a shortened duration. The required external voltage input is below 300 V. A compact circuit implementation produced peak E-fields of 280 V/m at 1.5 cm distance from the magnetic coil, in 23 μs pulses (while 70-280 μs pulses are typically used for rTMS). Although threshold E fields for neural excitation increase with shorter pulse widths, neural excitation is demonstrated in human subjects via ulnar nerve stimulation and electromyography. This circuit technique may facilitate greater feasibility and flexibility in the design of miniaturized and portable PNS medical devices.
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一种有效的脉冲磁神经刺激电路
外周神经脉冲刺激(PNS)广泛用于神经异常的诊断,可用于减轻疼痛和促进神经再生。通过磁脉冲的神经刺激可以提供优于传统电刺激的优点;它消除了电极与皮肤接触的需要,并且通常不那么痛苦。这项工作有助于开发用于磁性PNS(M-PNS)的紧凑和便携式系统。到目前为止,M-PNS在很大程度上采用了为重复经颅磁刺激(rTMS)开发的脉冲产生系统。一种新的电路被证明可以产生脉冲磁场,该脉冲磁场比传统rTMS系统中可获得的感应电场强度增加。由此产生的E字段具有缩短的持续时间。所需的外部电压输入低于300 V。紧凑的电路实现在距离磁线圈1.5厘米处产生峰值电场280 V/m,脉冲为23μs(而70-280μs脉冲通常用于rTMS)。尽管神经兴奋的阈值E场随着脉冲宽度的缩短而增加,但通过尺神经刺激和肌电图在人类受试者中显示了神经兴奋。这种电路技术可以促进在小型化和便携式PNS医疗设备的设计中具有更大的可行性和灵活性。
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CiteScore
5.80
自引率
9.40%
发文量
58
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