用磁电纳米粒子控制动作电位

IF 7.6 1区 医学 Q1 CLINICAL NEUROLOGY
Elric Zhang , Max Shotbolt , Chen-Yu Chang , Aidan Scott-Vandeusen , Shawnus Chen , Ping Liang , Daniela Radu , Sakhrat Khizroev
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引用次数: 0

摘要

针对大脑任何区域的无创或微创无线脑刺激是工程学和神经科学领域的一个未决问题,对治疗多种神经系统疾病具有重要意义。尽管最近在推进新的神经调控方法方面取得了重大进展,但还没有一种方法能成功复制传统有线刺激的疗效,并在不引入新的并发症的情况下改进其缺点。磁电纳米粒子(MENP)神经调控技术具有将磁场转化为局部电场的能力,是最近提出的一种基于新材料的神经调控框架,可使神经元对特定的低强度交流磁场(50Hz 1.7kOe 磁场)产生局部敏感性。然而,目前对这一神经调控概念的研究还处于非常早期的阶段,理论上可行的改变游戏规则的优势仍有待实验证明。为了打破这一僵局,本研究利用了对 MENPs 非线性特性以及纳米粒子与细胞微环境的磁场相互作用的理解。特别是,应用磁场的强度和频率是根据纳米粒子的 M-H 磁滞回线量身定制的。此外,采用矩形棱柱而非传统的 "球形 "纳米粒子形状是为了(i) 使磁电效应最大化;(ii) 改善纳米粒子-细胞-膜表面界面。在对 2446 个大鼠海马神经元进行的一系列探索性体外实验中,对神经调控性能进行了评估。实验采用线性混合效应模型,通过考虑同步发射中的固定邻接效应来确保样本的独立性。神经活动的测量重复进行了 4 分钟,包括 90 秒的基线测量、90 秒的刺激测量和 60 秒的刺激后测量。87.5%的刺激尝试会使神经活动发生显著变化(P < 0.05),其中 58.3% 的刺激尝试会使神经活动发生较大变化(P < 0.01)。在使用零或不含纳米粒子的 1.7kOe 强度电场的阴性对照组中,没有实验能使神经活动发生显著变化(P > 0.05 和 P > 0.15)。此外,对直流(DC)磁场的探索性分析表明,直流磁场可与 MENPs 一起用于抑制神经元活动(P < 0.01)。这些实验证明了磁电神经调控的潜力,它与传统的电极刺激具有近乎一对一的功能匹配,无需手术干预或基因修饰即可获得成功,而是依靠这些纳米粒子的物理特性作为 "开/关 "控制机制。一句话总结:这项体外神经细胞培养研究探讨了如何利用磁电纳米粒子的非线性和各向异性特性进行无线神经调制、磁场强度和频率匹配对优化的重要性,并首次证明磁电神经调制可以抑制神经反应。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Controlling action potentials with magnetoelectric nanoparticles

Non-invasive or minutely invasive and wireless brain stimulation that can target any region of the brain is an open problem in engineering and neuroscience with serious implications for the treatment of numerous neurological diseases. Despite significant recent progress in advancing new methods of neuromodulation, none has successfully replicated the efficacy of traditional wired stimulation and improved on its downsides without introducing new complications. Due to the capability to convert magnetic fields into local electric fields, MagnetoElectric NanoParticle (MENP) neuromodulation is a recently proposed framework based on new materials that can locally sensitize neurons to specific, low-strength alternating current (AC) magnetic fields (50Hz 1.7 kOe field). However, the current research into this neuromodulation concept is at a very early stage, and the theoretically feasible game-changing advantages remain to be proven experimentally. To break this stalemate phase, this study leveraged understanding of the non-linear properties of MENPs and the nanoparticles' field interaction with the cellular microenvironment. Particularly, the applied magnetic field's strength and frequency were tailored to the M − H hysteresis loop of the nanoparticles. Furthermore, rectangular prisms instead of the more traditional “spherical” nanoparticle shapes were used to: (i) maximize the magnetoelectric effect and (ii) improve the nanoparticle-cell-membrane surface interface. Neuromodulation performance was evaluated in a series of exploratory in vitro experiments on 2446 rat hippocampus neurons. Linear mixed effect models were used to ensure the independence of samples by accounting for fixed adjacency effects in synchronized firing. Neural activity was measured over repeated 4-min segments, containing 90 s of baseline measurements, 90 s of stimulation measurements, and 60 s of post stimulation measurements. 87.5 % of stimulation attempts produced statistically significant (P < 0.05) changes in neural activity, with 58.3 % producing large changes (P < 0.01). In negative controls using either zero or 1.7 kOe-strength field without nanoparticles, no experiments produced significant changes in neural activity (P > 0.05 and P > 0.15 respectively). Furthermore, an exploratory analysis of a direct current (DC) magnetic field indicated that the DC field could be used with MENPs to inhibit neuron activity (P < 0.01). These experiments demonstrated the potential for magnetoelectric neuromodulation to offer a near one-to-one functionality match with conventional electrode stimulation without requiring surgical intervention or genetic modification to achieve success, instead relying on physical properties of these nanoparticles as “On/Off” control mechanisms.

One-sentence summary

This in vitro neural cell culture study explores how to exploit the non-linear and anisotropic properties of magnetoelectric nanoparticles for wireless neuromodulation, the importance of magnetic field strength and frequency matching for optimization, and demonstrates, for the first time, that magnetoelectric neuromodulation can inhibit neural responses.

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来源期刊
Brain Stimulation
Brain Stimulation 医学-临床神经学
CiteScore
13.10
自引率
9.10%
发文量
256
审稿时长
72 days
期刊介绍: Brain Stimulation publishes on the entire field of brain stimulation, including noninvasive and invasive techniques and technologies that alter brain function through the use of electrical, magnetic, radiowave, or focally targeted pharmacologic stimulation. Brain Stimulation aims to be the premier journal for publication of original research in the field of neuromodulation. The journal includes: a) Original articles; b) Short Communications; c) Invited and original reviews; d) Technology and methodological perspectives (reviews of new devices, description of new methods, etc.); and e) Letters to the Editor. Special issues of the journal will be considered based on scientific merit.
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