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新生桶状皮层时间精度的快速、活动依赖型可塑性。

Rapid, activity-dependent plasticity in timing precision in neonatal barrel cortex.

作者信息

Daw Michael I, Bannister Neil V, Isaac John T R

机构信息

Medical Research Council Centre for Synaptic Plasticity, Department of Anatomy, University of Bristol, Bristol BS8 1TD, United Kingdom.

出版信息

J Neurosci. 2006 Apr 19;26(16):4178-87. doi: 10.1523/JNEUROSCI.0150-06.2006.

DOI:10.1523/JNEUROSCI.0150-06.2006
PMID:16624938
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6673993/
Abstract

Developing neuronal networks acquire the ability to precisely time events, a key feature required for information processing. In the barrel cortex, encoding of information requires a high-precision temporal code with a resolution of approximately 5 ms; however, it is not known what process drives the maturation in timing precision. Here, we report that long-term potentiation (LTP) at thalamocortical synapses in the neonatal layer IV barrel cortex produces a dramatic improvement in the timing of neuronal output and synaptic input. LTP strongly reduces the latency and variability of synaptically evoked action potentials, improving the fidelity of timing to within that predicted to be required for adult sensory processing. Such changes in timing also occur during development in the neonate. LTP also reduces the summation of EPSPs shortening the window for coincidence detection for synaptic input. In contrast to these reliable effects, LTP produced only a modest and variable change in synaptic efficacy. Thus, our findings suggest that the primary role of this form of neonatal LTP is for the acquisition of timing precision and the refinement of coincidence detection, rather than an increase in synaptic strength. Therefore, neonatal thalamocortical LTP may be a critical prerequisite for the maturation of information processing in the barrel cortex.

摘要

正在发育的神经网络获得了精确计时事件的能力,这是信息处理所需的关键特征。在桶状皮层中,信息编码需要一个分辨率约为5毫秒的高精度时间编码;然而,尚不清楚是什么过程驱动了计时精度的成熟。在这里,我们报告新生儿IV层桶状皮层丘脑皮质突触处的长时程增强(LTP)在神经元输出和突触输入的计时方面产生了显著改善。LTP强烈降低了突触诱发动作电位的潜伏期和变异性,将计时保真度提高到成人感觉处理所需的预测范围内。这种计时变化在新生儿发育过程中也会发生。LTP还减少了兴奋性突触后电位(EPSP)的总和,缩短了突触输入的重合检测窗口。与这些可靠的效应相反,LTP在突触效能方面仅产生了适度且可变的变化。因此,我们的研究结果表明,这种形式的新生儿LTP的主要作用是获得计时精度和完善重合检测,而不是增加突触强度。因此,新生儿丘脑皮质LTP可能是桶状皮层信息处理成熟的关键先决条件。

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