低频超声在小鼠大脑皮层引起的广泛反应受到氯胺酮的抑制。

Linli Shi, Christina Mastracchio, Ilyas Saytashev, Meijun Ye
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摘要

频率大于 250 千赫的超声波对神经的调节作用已得到充分证实,但频率较低的超声波能更好地穿过空气和头骨,其对大脑的影响尚不清楚。本研究利用钙成像和小鼠电生理学研究了 40 千赫脉冲超声对大脑的生物影响。我们的研究结果表明,在躯体感觉皮层和听觉皮层中,爆发持续时间依赖性神经反应与体内 12 千赫可听音调的反应相似。体外脑片实验显示,300 kPa 40 kHz 超声波不会引起神经反应,这意味着存在间接网络效应。氯胺酮能完全阻断两个皮层对超声波的神经反应,但只能部分影响躯体感觉皮层对 12 kHz 可听音的反应,对听觉皮层的 12 kHz 反应没有影响。这表明,低频超声对大脑皮层的影响主要依赖于 NMDA 受体,可能涉及间接激活听觉皮层以外的机制。这项研究揭示了低频超声在大脑中的潜在效应和机制,为未来的神经调控提供了一条途径。
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Low frequency ultrasound elicits broad cortical responses inhibited by ketamine in mice
The neuromodulatory effects of >250 kHz ultrasound have been well-demonstrated, but the impact of lower-frequency ultrasound, which can transmit better through air and the skull, on the brain is unclear. This study investigates the biological impact of 40 kHz pulsed ultrasound on the brain using calcium imaging and electrophysiology in mice. Our findings reveal burst duration-dependent neural responses in somatosensory and auditory cortices, resembling responses to 12 kHz audible tone, in vivo. In vitro brain slice experiments show no neural responses to 300 kPa 40 kHz ultrasound, implying indirect network effects. Ketamine fully blocks neural responses to ultrasound in both cortices but only partially affects 12 kHz audible tone responses in the somatosensory cortex and has no impact on auditory cortex 12 kHz responses. This suggests that low-frequency ultrasound’s cortical effects rely heavily on NMDA receptors and may involve mechanisms beyond indirect auditory cortex activation. This research uncovers potential low-frequency ultrasound effects and mechanisms in the brain, offering a path for future neuromodulation. Dr Ye and colleagues investigate the biological impact low-frequency ultrasound pulses can have on the cortex of mice. They observe pulse duration dependent neural responses and find that ketamine can block parameter-dependent brain responses at certain frequencies.
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