Fixational Eye Movements Enhance the Precision of Visual Information Transmitted by the Primate Retina.

Eric G Wu, Nora Brackbill, Colleen Rhoades, Alexandra Kling, Alex R Gogliettino, Nishal P Shah, Alexander Sher, Alan M Litke, Eero P Simoncelli, E J Chichilnisky
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Abstract

Fixational eye movements alter the number and timing of spikes transmitted from the retina to the brain, but whether these changes enhance or degrade the retinal signal is unclear. To quantify this, we developed a Bayesian method for reconstructing natural images from the recorded spikes of hundreds of retinal ganglion cells (RGCs) in the macaque retina (male), combining a likelihood model for RGC light responses with the natural image prior implicitly embedded in an artificial neural network optimized for denoising. The method matched or surpassed the performance of previous reconstruction algorithms, and provides an interpretable framework for characterizing the retinal signal. Reconstructions were improved with artificial stimulus jitter that emulated fixational eye movements, even when the eye movement trajectory was assumed to be unknown and had to be inferred from retinal spikes. Reconstructions were degraded by small artificial perturbations of spike times, revealing more precise temporal encoding than suggested by previous studies. Finally, reconstructions were substantially degraded when derived from a model that ignored cell-to-cell interactions, indicating the importance of stimulus-evoked correlations. Thus, fixational eye movements enhance the precision of the retinal representation.

Abstract Image

Abstract Image

Abstract Image

固定眼球运动可提高灵长类视网膜传递视觉信息的准确性。
固定性眼球运动会改变从视网膜传递到大脑的尖峰的数量和时间,但这些变化是增强还是降低视觉信号尚不清楚。为了量化这一点,我们开发了一种贝叶斯方法,用于从数百个主要细胞类型的猕猴视网膜神经节细胞(RGC)的记录尖峰重建自然图像,将RGC光反应的似然模型与自然图像相结合,该自然图像预隐嵌入为去噪优化的人工神经网络中。该方法匹配或超过了以前重建算法的性能,并为表征视网膜信号提供了一个可解释的框架。模拟注视眼球运动的人工刺激抖动改善了重建,即使抖动轨迹是从视网膜尖峰推断出来的。重建被尖峰时间的小的人工扰动所退化,揭示了比先前研究所建议的更精确的时间编码。最后,当从忽略细胞间相互作用的模型中导出重建时,重建显著退化,这表明了刺激诱发相关性的重要性。因此,注视性眼球运动提高了视网膜表现的准确性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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