用于定向啮齿动物大脑刺激的高性能磁芯线圈。

IF 5 Q1 ENGINEERING, BIOMEDICAL BME frontiers Pub Date : 2022-03-05 eCollection Date: 2022-01-01 DOI:10.34133/2022/9854846
Hedyeh Bagherzadeh, Qinglei Meng, Hanbing Lu, Elliott Hong, Yihong Yang, Fow-Sen Choa
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引用次数: 3

摘要

目标和影响声明。需要开发能够靶向脑刺激的啮齿动物线圈,用于治疗神经精神疾病和了解大脑机制。我们描述了一种新颖的啮齿动物线圈设计,以提高小啮齿动物大脑中靶向刺激的聚焦性。介绍经颅磁刺激(TMS)在治疗神经精神疾病和了解大脑机制方面变得越来越重要。临床前研究允许进行侵入性操作,对于从机制上理解TMS效应和探索疾病模型中的治疗结果至关重要。然而,现有的TMS工具缺乏针对性刺激的重点。值得注意的是,关于开发能够对啮齿动物等小动物大脑深部区域进行局部刺激的线圈的基础研究有限。方法。在这项研究中,将铁磁芯添加到一种新颖的角度调谐线圈设计中,以提高线圈在穿透深度和聚焦方面的性能。进行了数值模拟和实验电场测量,以优化线圈设计。后果与现有线圈相比,所提出的线圈系统表现出明显更小的刺激点尺寸和增强的电场衰减率。添加铁磁芯可将啮齿动物大脑刺激的能量需求降低60%。模拟结果通过实验测量和通过靶向运动皮层激活的超阈值啮齿动物肢体兴奋的演示得到了验证。结论新开发的线圈是用于啮齿动物大脑局部刺激的合适工具,因为它们的刺激点尺寸更小,电场衰减率提高。
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High-Performance Magnetic-core Coils for Targeted Rodent Brain Stimulations.

Objective and Impact Statement. There is a need to develop rodent coils capable of targeted brain stimulation for treating neuropsychiatric disorders and understanding brain mechanisms. We describe a novel rodent coil design to improve the focality for targeted stimulations in small rodent brains. Introduction. Transcranial magnetic stimulation (TMS) is becoming increasingly important for treating neuropsychiatric disorders and understanding brain mechanisms. Preclinical studies permit invasive manipulations and are essential for the mechanistic understanding of TMS effects and explorations of therapeutic outcomes in disease models. However, existing TMS tools lack focality for targeted stimulations. Notably, there has been limited fundamental research on developing coils capable of focal stimulation at deep brain regions on small animals like rodents. Methods. In this study, ferromagnetic cores are added to a novel angle-tuned coil design to enhance the coil performance regarding penetration depth and focality. Numerical simulations and experimental electric field measurements were conducted to optimize the coil design. Results. The proposed coil system demonstrated a significantly smaller stimulation spot size and enhanced electric field decay rate in comparison to existing coils. Adding the ferromagnetic core reduces the energy requirements up to 60% for rodent brain stimulation. The simulated results are validated with experimental measurements and demonstration of suprathreshold rodent limb excitation through targeted motor cortex activation. Conclusion. The newly developed coils are suitable tools for focal stimulations of the rodent brain due to their smaller stimulation spot size and improved electric field decay rate.

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CiteScore
7.10
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审稿时长
16 weeks
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