稀疏气味表征与嗅觉学习。

Sparse odor representation and olfactory learning.

作者信息

Ito Iori, Ong Rose Chik-Ying, Raman Baranidharan, Stopfer Mark

机构信息

National Institute of Child Health and Human Development, US National Institutes of Health, Building 35, Room 3A-102, Bethesda, Maryland 20982, USA.

出版信息

Nat Neurosci. 2008 Oct;11(10):1177-84. doi: 10.1038/nn.2192. Epub 2008 Sep 14.

DOI:10.1038/nn.2192

PMID:18794840

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3124899/

Abstract

Sensory systems create neural representations of environmental stimuli and these representations can be associated with other stimuli through learning. Are spike patterns the neural representations that get directly associated with reinforcement during conditioning? In the moth Manduca sexta, we found that odor presentations that support associative conditioning elicited only one or two spikes on the odor's onset (and sometimes offset) in each of a small fraction of Kenyon cells. Using associative conditioning procedures that effectively induced learning and varying the timing of reinforcement relative to spiking in Kenyon cells, we found that odor-elicited spiking in these cells ended well before the reinforcement was delivered. Furthermore, increasing the temporal overlap between spiking in Kenyon cells and reinforcement presentation actually reduced the efficacy of learning. Thus, spikes in Kenyon cells do not constitute the odor representation that coincides with reinforcement, and Hebbian spike timing-dependent plasticity in Kenyon cells alone cannot underlie this learning.

摘要

感觉系统创建环境刺激的神经表征，并且这些表征可以通过学习与其他刺激相关联。在条件作用过程中，尖峰模式是否就是那些直接与强化相关联的神经表征呢？在烟草天蛾中，我们发现支持联想性条件作用的气味呈现，在一小部分肯扬细胞中，仅在气味开始（有时是结束）时引发一两个尖峰。使用有效诱导学习的联想性条件作用程序，并改变强化相对于肯扬细胞中尖峰发放的时间，我们发现这些细胞中由气味引发的尖峰发放早在强化传递之前就结束了。此外，增加肯扬细胞中尖峰发放与强化呈现之间的时间重叠实际上降低了学习效果。因此，肯扬细胞中的尖峰并不构成与强化同时出现的气味表征，仅肯扬细胞中的赫布式尖峰时间依赖性可塑性不能作为这种学习的基础。

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