Richmond B J, Optican L M
J Neurophysiol. 1987 Jan;57(1):147-61. doi: 10.1152/jn.1987.57.1.147.
The purpose of this study was to describe how the responses of neurons in inferior temporal (IT) cortex represent visual stimuli. In the preceding paper we described the responses of IT neurons to a large set of two-dimensional black and white patterns. The responses to different stimuli showed temporal modulation of the spike trains. This paper develops a method for quantifying temporal modulation and shows that the stimulus determines the distribution over time, as well as the number, of spikes in a response. The responses were quantified using an orthogonal set of temporal waveforms called principal components. The principal components related to each neuron were extracted from all the responses of that neuron to all of the stimuli, regardless of which stimulus elicited which response. Each response was then projected onto the set of principal components to obtain a set of coefficients that quantified its temporal modulation. This decomposition produces coefficients that are uncorrelated with each other. Thus each coefficient could be tested individually, with univariate statistics, to determine whether its relation to the stimulus was nonrandom. The waveforms of the principal components are unconstrained and depend only on the responses from which they are derived; hence, they can assume any shape. Nonetheless, the 21 neurons we analyzed all had principal components that belonged to only one of two sets. The two sets could be characterized by their first principal component, which was either phasic or tonic. This suggests that these neurons may use as few as two different mechanisms in generating responses. The first principal component was highly correlated with spike count, and both were driven by the stimulus. Higher principal components were uncorrelated with spike count, yet some of them were also driven by the stimulus. Thus the principal components form a richer description of the stimulus-dependent aspects of a neuronal response than does spike count. Bootstrap tests showed that several principal components (usually 3 or 4) were determined by the stimulus. Since higher principal components were not correlated with the spike count, the stimulus must have determined the distribution of spikes in the response as well as their number. However, it is possible that the number and distribution of spikes are both determined by the same characteristics of the stimulus. In this case, the temporal modulation would be redundant, and a simple univariate measure would be sufficient to characterize the stimulus-response relationship.(ABSTRACT TRUNCATED AT 400 WORDS)
本研究的目的是描述颞下(IT)皮质中神经元的反应如何表征视觉刺激。在之前的论文中,我们描述了IT神经元对大量二维黑白图案的反应。对不同刺激的反应显示出脉冲序列的时间调制。本文开发了一种量化时间调制的方法,并表明刺激决定了反应中脉冲的时间分布以及数量。使用一组称为主成分的正交时间波形对反应进行量化。与每个神经元相关的主成分是从该神经元对所有刺激的所有反应中提取的,而不考虑哪个刺激引发了哪个反应。然后将每个反应投影到主成分集上,以获得一组量化其时间调制的系数。这种分解产生的系数相互不相关。因此,每个系数都可以通过单变量统计单独进行测试,以确定其与刺激的关系是否是非随机的。主成分的波形不受约束,仅取决于从中导出它们的反应;因此,它们可以呈现任何形状。尽管如此,我们分析的21个神经元都有属于两个集合之一的主成分。这两个集合可以通过它们的第一主成分来表征,第一主成分要么是相位的,要么是紧张性的。这表明这些神经元在产生反应时可能只使用两种不同的机制。第一主成分与脉冲计数高度相关,并且两者都由刺激驱动。更高阶的主成分与脉冲计数不相关,但其中一些也由刺激驱动。因此,与脉冲计数相比,主成分对神经元反应的刺激依赖性方面形成了更丰富的描述。自助法检验表明,几个主成分(通常为3或4个)由刺激决定。由于更高阶的主成分与脉冲计数不相关,刺激必定既决定了反应中脉冲的分布,也决定了其数量。然而,脉冲的数量和分布都由刺激的相同特征决定也是有可能的。在这种情况下,时间调制将是多余的,一个简单的单变量测量就足以表征刺激 - 反应关系。(摘要截选至400字)
