听觉皮层回路中的突触短期可塑性。
Synaptic short-term plasticity in auditory cortical circuits.
机构信息
Center for Neural Science, New York University, NY 10003, United States.
出版信息
Hear Res. 2011 Sep;279(1-2):60-6. doi: 10.1016/j.heares.2011.04.017. Epub 2011 May 10.
Abstract
The auditory system must be able to adapt to changing acoustic environment and still maintain accurate representation of signals. Mechanistically, this is a difficult task because the responsiveness of a large heterogeneous population of interconnected neurons must be adjusted properly and precisely. Synaptic short-term plasticity (STP) is widely regarded as a viable mechanism for adaptive processes. Although the cellular mechanism for STP is well characterized, the overall effect on information processing at the network level is poorly understood. The main challenge is that there are many cell types in auditory cortex, each of which exhibit different forms and degrees of STP. In this article, I will review the basic properties of STP in auditory cortical circuits and discuss the possible impact on signal processing.
摘要
听觉系统必须能够适应不断变化的声学环境,同时仍然能够准确地表示信号。从机制上讲,这是一项艰巨的任务,因为必须适当地、精确地调整大量相互连接的异构神经元群体的响应能力。突触短期可塑性 (STP) 被广泛认为是一种可行的自适应机制。尽管 STP 的细胞机制已得到很好的描述,但对网络级信息处理的整体影响仍知之甚少。主要的挑战是,听觉皮层中有许多细胞类型,每种细胞类型都表现出不同形式和程度的 STP。在本文中,我将回顾听觉皮层回路中 STP 的基本特性,并讨论其对信号处理的可能影响。
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