Single cell electrophysiological alterations under dynamic loading at ultrasonic frequencies

Q3 Engineering
M. Tamayo-Elizalde, C. Kayal, H. Ye, A. Jérusalem
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引用次数: 3

Abstract

The use of ultrasound as a non-invasive means to modulate neuronal electrophysiological signals in experimental in vivo and in vitro models has recently been gaining momentum. Paradoxically, the intrinsic mechanisms linking high-frequency minute mechanical vibrations to electrophysiological alterations at the cellular scale are yet to be identified in this context. To this end, this work combines patch clamp and nanoindentation to study the action potential alterations induced by direct mechanical vibrations at ultrasonic frequencies of dorsal root ganglion-derived neuronal single cells. The characteristics of the action potentials are studied under oscillatory shear loadings of 25 and 50 nm displacement amplitudes at frequencies ranging from 250 kHz to 1 MHz. Results show significantly narrower action potentials, with faster depolarisations and shorter rising and falling phases when induced after 1 MHz. The faster action potential dynamics appearing once the oscillation is removed points towards a cumulative or lagged effect of mechanical stimulation at ultrasonic frequencies, also observed in ultrasound neuromodulation studies. It is hypothesised here that this action potential modulation arises as a consequence of remarkable membrane properties changes induced above a threshold frequency, situated between 370 kHz and 960 kHz, and possibly related to membrane stiffening and membrane phase state alterations. These observations demonstrate the ability of mechanical cues at the cellular level to modify the neuronal signal and assert the importance of the direct mechanical vibrations induced by ultrasound stimulation protocols in assisting the observed neuromodulatory effects.

Statement of Significance

In the last few decades, transcranial ultrasound stimulation (TUS) has established itself as one of the most promising non-invasive neuromodulating techniques. In particular, by avoiding both the lack of spatial specificity and surgical needs plaguing other established techniques, TUS offers new avenues for the treatment of neurological diseases. In order to enhance its specificity and efficacy, and, ultimately, optimise the sonication parameters for a given application, a better understanding of the underlying mechanisms linking mechanical vibrations to electrophysiological alterations is needed. By focusing on this coupling down to the cellular scale, this work demonstrates at the cellular scale that a transition between 400 kHz and 1 MHz exists above which mechanical vibrations are able to modulate the neuronal action potential by accelerating its dynamics.

超声频率动态加载下单细胞电生理变化
近年来,超声作为一种非侵入性手段在体内和体外实验模型中调节神经元电生理信号的研究势头日益增强。矛盾的是,在这种情况下,将高频微小机械振动与细胞尺度上的电生理改变联系起来的内在机制尚未被确定。为此,本研究结合膜片钳和纳米压痕技术,研究了超声频率下直接机械振动对背根神经节源性神经元单细胞动作电位的影响。在250 kHz至1 MHz频率范围内,研究了位移幅度为25和50 nm的振荡剪切载荷下的动作电位特性。结果表明,在1 MHz后诱导时,动作电位明显变窄,去极化更快,上升和下降相更短。在超声神经调节研究中也观察到,一旦振荡消除,出现的更快的动作电位动力学指向超声频率下机械刺激的累积效应或滞后效应。这里假设,这种动作电位调制是由于高于阈值频率(位于370 kHz和960 kHz之间)引起的显著膜特性变化而引起的,并且可能与膜硬化和膜相态改变有关。这些观察结果证明了机械信号在细胞水平上改变神经元信号的能力,并断言超声刺激方案诱导的直接机械振动在协助观察到的神经调节作用中的重要性。在过去的几十年里,经颅超声刺激(TUS)已经成为最有前途的非侵入性神经调节技术之一。特别是,通过避免空间特异性的缺乏和困扰其他成熟技术的手术需求,TUS为神经系统疾病的治疗提供了新的途径。为了提高其特异性和有效性,并最终优化给定应用的超声参数,需要更好地理解将机械振动与电生理改变联系起来的潜在机制。通过关注这种耦合到细胞尺度,这项工作表明,在细胞尺度上,存在一个介于~ 400 kHz和~ 1 MHz之间的过渡,在此过渡之上,机械振动能够通过加速其动力学来调节神经元动作电位。
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
Brain multiphysics
Brain multiphysics Physics and Astronomy (General), Modelling and Simulation, Neuroscience (General), Biomedical Engineering
CiteScore
4.80
自引率
0.00%
发文量
0
审稿时长
68 days
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