Zhang Bin, Bi Hua, Sakai Eiichi, Maruko Ichiro, Zheng Jianghe, Smith Earl L, Chino Yuzo M
College of Optometry, University of Houston, 505 J. Davis Armistead Building, Houston, TX 77204-2020, USA.
Proc Natl Acad Sci U S A. 2005 Jun 21;102(25):9026-31. doi: 10.1073/pnas.0500280102. Epub 2005 Jun 14.
The basic sets of cortical connections are present at birth in the primate visual system. The maintenance and refinement of these innate connections are highly dependent on normal visual experience, and prolonged exposure to binocularly uncorrelated signals early in life severely disrupts the normal development of binocular functions. However, very little is known about how rapidly these changes in the functional organization of primate visual cortex emerge or what are the sequence and the nature of the abnormal neural events that occur immediately after experiencing binocular decorrelation. In this study, we investigated how brief periods of ocular misalignment (strabismus) at the height of the critical period alter the cortical circuits that support binocular vision. After only 3 days of optically imposed strabismus, there was a striking increase in the prevalence of V1 neurons that exhibited binocular suppression, i.e., binocular responses were weaker than monocular responses. However, the sensitivity of these neurons to interocular spatial phase disparity was not significantly altered. These contrasting results suggest that the first significant change in V1 caused by early binocular decorrelation is binocular suppression, and that this suppression originates at a site(s) beyond where binocular signals are initially combined.
在灵长类视觉系统中,出生时就存在基本的皮质连接集。这些先天连接的维持和精细化高度依赖于正常的视觉经验,生命早期长时间暴露于双眼不相关信号会严重破坏双眼功能的正常发育。然而,对于灵长类视觉皮层功能组织的这些变化多快出现,或者在经历双眼去相关后立即发生的异常神经事件的顺序和性质是什么,我们知之甚少。在本研究中,我们调查了关键期高峰时短暂的眼位不正(斜视)如何改变支持双眼视觉的皮质回路。仅经过3天光学诱导的斜视后,表现出双眼抑制(即双眼反应比单眼反应弱)的V1神经元的比例显著增加。然而,这些神经元对两眼间空间相位差异的敏感性没有显著改变。这些对比结果表明,早期双眼去相关引起的V1的第一个显著变化是双眼抑制,并且这种抑制起源于双眼信号最初合并位点之外的某个部位。