A Late Critical Period for Frequency Modulated Sweeps in the Mouse Auditory System

S. Bhumika, Mari Nakamura, Patrícia Valério, Magdalena Sołyga, Henrik Lindén, T. R. Barkat
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引用次数: 15

Abstract

Abstract Neuronal circuits are shaped by experience during time windows of increased plasticity in postnatal development. In the auditory system, the critical period for the simplest sounds—pure frequency tones—is well defined. Critical periods for more complex sounds remain to be elucidated. We used in vivo electrophysiological recordings in the mouse auditory cortex to demonstrate that passive exposure to frequency modulated sweeps (FMS) from postnatal day 31 to 38 leads to long-term changes in the temporal representation of sweep directions. Immunohistochemical analysis revealed a decreased percentage of layer 4 parvalbumin-positive (PV+) cells during this critical period, paralleled with a transient increase in responses to FMS, but not to pure tones. Preventing the PV+ cell decrease with continuous white noise exposure delayed the critical period onset, suggesting a reduction in inhibition as a mechanism for this plasticity. Our findings shed new light on the dependence of plastic windows on stimulus complexity that persistently sculpt the functional organization of the auditory cortex.
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调频扫描在小鼠听觉系统中的后期关键时期
在出生后发育的可塑性增加的时间窗期间,神经元回路是由经验塑造的。在听觉系统中,最简单的声音——纯频率音调——的关键期是明确的。更复杂声音的关键期仍有待阐明。我们使用小鼠听觉皮层的体内电生理记录来证明,从出生后第31天到第38天被动暴露于频率调制扫描(FMS)会导致扫描方向的时间表征的长期变化。免疫组织化学分析显示,在这一关键时期,第4层小蛋白阳性(PV+)细胞的百分比下降,同时对FMS的反应短暂增加,但对纯音的反应没有增加。通过持续的白噪声暴露来防止PV+细胞的减少延迟了关键时期的发作,这表明抑制的减少是这种可塑性的机制之一。我们的研究结果揭示了塑料窗对刺激复杂性的依赖性,这种复杂性持续地塑造了听觉皮层的功能组织。
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