Ultrasound pulse repetition frequency preferentially activates different neuron populations independent of cell type.

Jack Sherman, Emma Bortz, Erynne San Antonio, Hua-An Tseng, Laura Raiff, Xue Han
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Abstract

Objective. Transcranial ultrasound (US) stimulation serves as an external input to a neuron, and thus the evoked response relies on neurons' intrinsic properties. Neural activity is limited to a couple hundred hertz and often exhibits preference to input frequencies. Accordingly, US pulsed at specific physiologic pulse repetition frequencies (PRFs) may selectively engage neurons with the corresponding input frequency preference. However, most US parametric studies examine the effects of supraphysiologic PRFs. It remains unclear whether pulsing US at different physiologic PRFs could activate distinct neurons in the awake mammalian brain.Approach. We recorded cellular calcium responses of individual motor cortex neurons to US pulsed at PRFs of 10, 40, and 140 Hz in awake mice. We compared the evoked responses across these PRFs in the same neurons. To further understand the cell-type dependent effects, we categorized the recorded neurons as parvalbumin positive fast spiking interneurons or putative excitatory neurons and analyzed single-cell mechanosensitive channel expression in mice and humans using the Allen Brain Institute's RNA-sequencing databases.Main results. We discovered that many neurons were preferentially activated by only one PRF and different PRFs selectively engaged distinct neuronal populations. US-evoked cellular calcium responses exhibited the same characteristics as those naturally occurring during spiking, suggesting that US increases intrinsic neuronal activity. Furthermore, evoked responses were similar between fast-spiking inhibitory neurons and putative excitatory neurons. Thus, variation in individual neuron's cellular properties dominates US-evoked response heterogeneity, consistent with our observed cell-type independent expression patterns of mechanosensitive channels across individual neurons in mice and humans. Finally, US transiently increased network synchrony without producing prolonged over-synchronization that could be detrimental to neural circuit functions.Significance. These results highlight the feasibility of activating distinct neuronal subgroups by varying PRF and the potential to improve neuromodulation effects by combining physiologic PRFs.

超声脉冲重复频率可优先激活不同的神经元群,而与细胞类型无关。
目的经颅超声刺激是神经元的外部输入,因此诱发反应依赖于神经元的内在特性。神经活动仅限于几百赫兹,而且通常对输入频率有偏好。因此,以特定生理脉冲重复频率(PRF)发出的超声波可选择性地吸引具有相应输入频率偏好的神经元。然而,大多数超声参数研究都是研究超生理脉冲重复频率的效果。目前仍不清楚不同生理 PRF 的脉冲超声是否能激活清醒哺乳动物大脑中不同的神经元:我们在清醒的小鼠体内记录了单个运动皮层神经元对 PRF 为 10、40 和 140 Hz 的脉冲超声的细胞钙反应。我们比较了同一神经元在不同 PRF 下的诱发反应。为了进一步了解细胞类型依赖效应,我们将记录的神经元归类为parvalbumin阳性快速尖峰中间神经元或假定兴奋神经元,并利用艾伦脑研究所的RNA测序数据库分析了小鼠和人类单细胞机械敏感通道的表达:我们发现,许多神经元只被一种 PRF 优先激活,而不同的 PRF 会选择性地激活不同的神经元群。超声诱发的细胞钙反应表现出与尖峰冲刺时自然发生的反应相同的特征,这表明超声增加了神经元的内在活动。此外,快速尖峰抑制性神经元和假定兴奋性神经元之间的诱发反应相似。因此,单个神经元细胞特性的变化主导了超声诱发反应的异质性,这与我们观察到的小鼠和人类单个神经元机械敏感通道独立于细胞类型的表达模式是一致的。最后,超声波能短暂提高网络同步性,但不会产生可能对神经回路功能有害的长期过度同步:这些结果凸显了通过改变 PRF 激活不同神经元亚群的可行性,以及通过结合生理 PRF 改善神经调节效果的潜力。
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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