Computational analysis of multichannel magnetothermal neural stimulation using magnetic resonator array.

IF 3.2 4区 医学 Q2 ENGINEERING, BIOMEDICAL
Biomedical Engineering Letters Pub Date : 2023-02-10 eCollection Date: 2023-05-01 DOI:10.1007/s13534-023-00267-x
Kyungmo Sung, Seonghoon Jo, Jaewook Lee, Jeong Hoan Park, Young Hoon Park, Jeongjoo Moon, Sung June Kim, Joonsoo Jeong, Jonghwan Lee, Kyungsik Eom
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引用次数: 0

Abstract

Heating nanoparticles with a magnetic field could facilitate selective remote control of neural activity in deep tissue. However, current magnetothermal stimulation approaches are limited to single-channel stimulation. Here, we investigated various designs for multichannel magnetothermal stimulation based on an array of resonant coils that are driven by a single loop coil. Using a tuning capacitor that allows resonant coils to resonate at the operating frequency, each coil's ON and OFF resonance can be controlled, enabling us to select stimulation channels. We found that smaller inner diameters of resonant coils produce more localized magnetic fields while larger coils produce magnetic fields over a longer distance. The constructed multichannel resonant coil arrays can provide a high enough magnetic field intensity to raise the temperature of nanoparticles by 8 °C when we apply 35.2 W into the loop coil that is spaced 1 mm from the target neurons. This multichannel stimulation using a simple resonant circuit approach would be useful for clinical applications of magnetothermal neural stimulation.

利用磁共振阵列进行多通道磁热神经刺激的计算分析。
用磁场加热纳米粒子可促进对深层组织神经活动的选择性远程控制。然而,目前的磁热刺激方法仅限于单通道刺激。在此,我们研究了基于由单个环形线圈驱动的谐振线圈阵列的各种多通道磁热刺激设计。利用调谐电容器使谐振线圈在工作频率上产生共振,可以控制每个线圈的导通和关断共振,从而使我们能够选择刺激通道。我们发现,谐振线圈的内径越小,产生的局部磁场越大,而线圈越大,产生的磁场距离越长。当我们向距离目标神经元 1 毫米的环形线圈施加 35.2 W 的功率时,所构建的多通道谐振线圈阵列能提供足够高的磁场强度,使纳米粒子的温度升高 8 °C。这种使用简单谐振电路的多通道刺激方法将有助于磁热神经刺激的临床应用。
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
Biomedical Engineering Letters
Biomedical Engineering Letters ENGINEERING, BIOMEDICAL-
CiteScore
6.80
自引率
0.00%
发文量
34
期刊介绍: Biomedical Engineering Letters (BMEL) aims to present the innovative experimental science and technological development in the biomedical field as well as clinical application of new development. The article must contain original biomedical engineering content, defined as development, theoretical analysis, and evaluation/validation of a new technique. BMEL publishes the following types of papers: original articles, review articles, editorials, and letters to the editor. All the papers are reviewed in single-blind fashion.
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