视觉阈值是由视网膜中的线性和非线性机制设定的,可以减轻噪声:视网膜中的神经回路如何提高单光子响应的信噪比。
Visual threshold is set by linear and nonlinear mechanisms in the retina that mitigate noise: how neural circuits in the retina improve the signal-to-noise ratio of the single-photon response.
机构信息
Zilkha Neurogenetic Institute, University of Southern California, Los Angeles, CA, USA.
出版信息
Bioessays. 2011 Jun;33(6):438-47. doi: 10.1002/bies.201100014. Epub 2011 Apr 7.
Abstract
In sensory biology, a major outstanding question is how sensory receptor cells minimize noise while maximizing signal to set the detection threshold. This optimization could be problematic because the origin of both the signals and the limiting noise in most sensory systems is believed to lie in stimulus transduction. Signal processing in receptor cells can improve the signal-to-noise ratio. However, neural circuits can further optimize the detection threshold by pooling signals from sensory receptor cells and processing them using a combination of linear and nonlinear filtering mechanisms. In the visual system, noise limiting light detection has been assumed to arise from stimulus transduction in rod photoreceptors. In this context, the evolutionary optimization of the signal-to-noise ratio in the retina has proven critical in allowing visual sensitivity to approach the limits set by the quantal nature of light. Here, we discuss how noise in the mammalian retina is mitigated to allow for highly sensitive night vision.
摘要
在感觉生物学中,一个主要的悬而未决的问题是感觉受体细胞如何在将检测阈值最小化噪声的同时最大化信号。这种优化可能会有问题,因为在大多数感觉系统中,信号和限制噪声的起源都被认为在于刺激转导。受体细胞中的信号处理可以提高信噪比。然而,神经回路可以通过从感觉受体细胞中汇集信号并使用线性和非线性滤波机制的组合来进一步优化检测阈值。在视觉系统中,人们认为限制光检测的噪声源于棒状光感受器中的刺激转导。在这种情况下,视网膜中信号与噪声比的进化优化对于使视觉敏感性接近光的量子性质所设定的极限至关重要。在这里,我们讨论了哺乳动物视网膜中的噪声如何得到缓解,以实现高度敏感的夜视。
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