Dynamic structural remodeling of the human visual system prompted by bilateral retinal gene therapy

Manzar Ashtari , Philip Cook , Mikhail Lipin , Yinxi Yu , Gui-Shuang Ying , Albert Maguire , Jean Bennett , James Gee , Hui Zhang
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Abstract

The impact of changes in visual input on neuronal circuitry is complex and much of our knowledge on human brain plasticity of the visual systems comes from animal studies. Reinstating vision in a group of patients with low vision through retinal gene therapy creates a unique opportunity to dynamically study the underlying process responsible for brain plasticity. Historically, increases in the axonal myelination of the visual pathway has been the biomarker for brain plasticity. Here, we demonstrate that to reach the long-term effects of myelination increase, the human brain may undergo demyelination as part of a plasticity process. The maximum change in dendritic arborization of the primary visual cortex and the neurite density along the geniculostriate tracks occurred at three months (3MO) post intervention, in line with timing for the peak changes in postnatal synaptogenesis within the visual cortex reported in animal studies. The maximum change at 3MO for both the gray and white matter significantly correlated with patients’ clinical responses to light stimulations called full field sensitivity threshold (FST). Our results shed a new light on the underlying process of brain plasticity by challenging the concept of increase myelination being the hallmark of brain plasticity and instead reinforcing the idea of signal speed optimization as a dynamic process for brain plasticity.

Abstract Image

双侧视网膜基因治疗引起的人类视觉系统的动态结构重塑
视觉输入的变化对神经回路的影响是复杂的,我们对人类大脑视觉系统可塑性的了解大多来自动物研究。通过视网膜基因治疗恢复一组低视力患者的视力,为动态研究大脑可塑性的潜在过程创造了一个独特的机会。历史上,视觉通路轴突髓鞘形成的增加一直是大脑可塑性的生物标志物。在这里,我们证明,为了达到髓鞘形成增加的长期影响,人类大脑可能经历脱髓鞘作为可塑性过程的一部分。干预后3个月,初级视觉皮层树突树突和沿genullostriate轨迹的神经突密度发生最大变化,与动物研究中报道的出生后视觉皮层突触发生峰值变化的时间一致。3MO时灰质和白质的最大变化与患者对光刺激的临床反应显著相关,称为全场敏感阈值(full field sensitivity threshold, FST)。我们的研究结果通过挑战髓鞘形成增加是大脑可塑性标志的概念,而不是强化信号速度优化是大脑可塑性动态过程的想法,为大脑可塑性的潜在过程提供了新的视角。
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