Preferential motor reinnervation is modulated by both repair site and distal nerve environments.

IF 4.6 2区 医学 Q1 NEUROSCIENCES
C Li, N Rassekh, A O'Daly, F Kebaisch, R Wolinsky, A Vyas, R Skolasky, A Hoke, T Brushart
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引用次数: 0

Abstract

To restore function after nerve injury, axons must regenerate from the injury site to the periphery, then reinnervate appropriate end organs when they arrive. Only 10 % of adults who suffer nerve injury will regain normal function, often because axons regenerate to functionally inappropriate targets (Brushart, 2011). The peripheral destination of these axons is largely determined by the pathways they enter at the site of nerve repair. To improve clinical outcomes, it is thus critical to improve the accuracy of axon pathfinding. In rodents, motor axons regenerating in mixed nerve preferentially reinnervate pathways leading to muscle, a process termed preferential motor reinnervation (PMR). Previous experiments have shown that PMR can be enhanced by predegenerating nerve grafts to enhance growth factor production and remove inhibitory factors (Abdullah et al., 2013). The current experiments explore the relative contributions of motor pathways, sensory pathways, and the repair environment to this enhancement. Sensory and/or motor pathways within rat femoral nerve grafts were predegenerated for 3 weeks to optimize growth factor production (Brushart et al., 2013) or for 12 weeks to deplete it. Optimizing the environment within previously motor Schwann cell tubes promoted PMR, regardless of whether adjacent sensory pathways were optimized or chronically denervated. However, this positive effect was abolished when sensory pathways were undergoing acute Wallerian degeneration immediately after nerve repair. The repair environment thus precluded motor axon pathfinding in spite of an optimized distal motor pathway. When sensory pathways were optimized and motor pathways were chronically denervated, not only was PMR abolished, but motoneurons failed to respond to the greater volume of growth factors in the sensory nerve. Small sensory neurons, however, selectively reinnervated cutaneous nerve under these conditions. These experiments thus strengthen the concept that, in adult rats, sensory and motor pathways have unique identities capable of influencing both sensory and motor axon regeneration. Furthermore, they demonstrate that, in the rat, delaying nerve repair for 3 weeks to enhance growth factor production and clear the products of acute Wallerian degeneration can enhance regeneration specificity without the need for exogenous treatments.

优先运动再支配受修复部位和远端神经环境的影响。
为了在神经损伤后恢复功能,轴突必须从损伤部位再生到外周,然后在到达适当的末端器官时重新支配它们。只有10%的成人神经损伤患者能恢复正常功能,这通常是因为轴突再生到了功能不适当的目标(Brushart,2011年)。这些轴突的外周去向在很大程度上取决于它们在神经修复部位进入的路径。因此,要改善临床疗效,提高轴突寻路的准确性至关重要。在啮齿类动物中,混合神经再生的运动轴突会优先重新支配通往肌肉的通路,这一过程被称为优先运动再支配(PMR)。之前的实验表明,通过预再生神经移植物来增强生长因子的产生并去除抑制因子,可以增强运动再支配(PMR)(Abdullah 等人,2013 年)。目前的实验探索了运动通路、感觉通路和修复环境对这种增强的相对贡献。对大鼠股神经移植物的感觉和/或运动通路进行为期 3 周的预退化以优化生长因子的产生(Brushart 等人,2013 年),或为期 12 周以耗尽生长因子的产生。无论邻近的感觉通路是经过优化还是长期去神经支配,优化之前运动的许旺细胞管内的环境都会促进 PMR。然而,当感觉通路在神经修复后立即发生急性沃勒里变性时,这种积极效应就会消失。因此,尽管远端运动通路得到了优化,但修复环境阻碍了运动轴突的寻路。当感觉通路被优化而运动通路被慢性去神经支配时,不仅 PMR 被取消,而且运动神经元也无法对感觉神经中更大量的生长因子做出反应。然而,在这些条件下,小的感觉神经元会选择性地重新支配皮神经。因此,这些实验加强了这样一个概念,即成年大鼠的感觉和运动通路具有独特的特性,能够影响感觉和运动轴突的再生。此外,这些实验还证明,在大鼠体内,延迟神经修复 3 周以促进生长因子的产生并清除急性 Wallerian 退化的产物,可以提高再生的特异性,而无需外源治疗。
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来源期刊
Experimental Neurology
Experimental Neurology 医学-神经科学
CiteScore
10.10
自引率
3.80%
发文量
258
审稿时长
42 days
期刊介绍: Experimental Neurology, a Journal of Neuroscience Research, publishes original research in neuroscience with a particular emphasis on novel findings in neural development, regeneration, plasticity and transplantation. The journal has focused on research concerning basic mechanisms underlying neurological disorders.
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