Sarabia-Estrada Rachel, Bañuelos-Pineda Jacinto, Osuna Carrasco Laura P, Jiménez-Vallejo Salvador, Jiménez-Estrada Ismael, Rivas-Celis Efrain, Dueñas-Jiménez Judith M, Dueñas-Jiménez Sergio H
Department of Veterinary Medicine, CUCBA, Universidad de Guadalajara;
Departments of 2 Neuroscience and.
J Neurosurg. 2015 Jul;123(1):270-82. doi: 10.3171/2014.12.JNS132519. Epub 2015 Feb 13.
Transection of peripheral nerves produces loss of sensory and/or motor function. After complete nerve cutting, the distal and proximal segment ends retract, but if both ends are bridged with unaltered chitosan, progesterone-impregnated chitosan, or silicone tubes, an axonal repair process begins. Progesterone promotes nerve repair and has neuroprotective effects thwarting regulation of neuron survival, inflammation, and edema. It also modulates aberrant axonal sprouting and demyelination. The authors compared the efficacy of nerve recovery after implantation of progesterone-loaded chitosan, unaltered chitosan, or silicone tubes after sciatic nerve transection in rats.
After surgical removal of a 5-mm segment of the proximal sciatic nerve, rats were implanted with progesterone-loaded chitosan, unaltered chitosan, or silicone tubes in the transected nerve for evaluating progesterone and chitosan effects on sciatic nerve repair and ipsilateral hindlimb kinematic function, as well as on gastrocnemius electro-myographic responses. In some experiments, tube implantation was performed 90 minutes after nerve transection.
At 90 days after sciatic nerve transection and tube implantation, rats with progesterone-loaded chitosan tubes showed knee angular displacement recovery and better outcomes for step length, velocity of locomotion, and normal hindlimb raising above the ground. In contrast, rats with chitosan-only tubes showed reduced normal raising and pendulum-like hindlimb movements. Aberrant fibers coming from the tibial nerve innervated the gastrocnemius muscle, producing electromyographic responses. Electrical responses in the gastrocnemius muscle produced by sciatic nerve stimulation occurred only when the distal nerve segment was stimulated; they were absent when the proximal or intratubular segment was stimulated. A clear sciatic nerve morphology with some myelinated fiber fascicles appeared in the tube section in rats with progesterone-impregnated chitosan tubes. Some gastrocnemius efferent fibers were partially repaired 90 days after nerve resection. The better outcome in knee angle displacement may be partially attributable to the aberrant neuromuscular synaptic effects, since nerve conduction in the gastrocnemius muscle could be blocked in the progesterone-impregnated chitosan tubes. In addition, in the region of the gap produced by the nerve resection, the number of axons and amount of myelination were reduced in the sciatic nerve implanted with chitosan, progesterone-loaded chitosan, and silicone tubes. At 180 days after sciatic nerve sectioning, the knee kinematic function recovered to a level observed in control rats of a similar age. In rats with progesterone-loaded chitosan tubes, stimulation of the proximal and intratubular sciatic nerve segments produced an electromyographic response. The axon morphology of the proximal and intratubular segments of the sciatic nerve resembled that of the contralateral nontransected nerve.
Progesterone-impregnated chitosan tubes produced aberrant innervation of the gastrocnemius muscle, which allowed partial recovery of gait locomotion and could be adequate for reinnervating synergistic denervated muscles while a parent innervation is reestablished. Hindlimb kinematic parameters differed between younger (those at 90 days) and older (those at 180 days) rats.
外周神经横断会导致感觉和/或运动功能丧失。在神经完全切断后,远、近端神经断端会回缩,但如果两端用未改性的壳聚糖、含孕酮的壳聚糖或硅胶管桥接,轴突修复过程就会开始。孕酮可促进神经修复,并具有神经保护作用,可抑制神经元存活、炎症和水肿的调节。它还能调节异常的轴突发芽和脱髓鞘。作者比较了大鼠坐骨神经横断后植入含孕酮壳聚糖、未改性壳聚糖或硅胶管后神经恢复的效果。
在手术切除近端坐骨神经5毫米节段后,将含孕酮壳聚糖、未改性壳聚糖或硅胶管植入大鼠横断的神经中,以评估孕酮和壳聚糖对坐骨神经修复、同侧后肢运动功能以及腓肠肌肌电图反应的影响。在一些实验中,在神经横断90分钟后进行管植入。
在坐骨神经横断和管植入90天后,植入含孕酮壳聚糖管的大鼠膝关节角位移恢复,步长、运动速度以及后肢正常离地抬高情况的结果更好。相比之下,仅植入壳聚糖管的大鼠正常抬高减少,后肢出现钟摆样运动。来自胫神经的异常纤维支配腓肠肌,产生肌电图反应。坐骨神经刺激在腓肠肌产生的电反应仅在刺激远端神经节段时出现;刺激近端或管内节段时则无反应。在植入含孕酮壳聚糖管的大鼠的管段中,出现了具有一些有髓纤维束的清晰坐骨神经形态。神经切除90天后,一些腓肠肌传出纤维得到部分修复。膝关节角位移更好的结果可能部分归因于异常的神经肌肉突触效应,因为在含孕酮壳聚糖管中腓肠肌的神经传导可能被阻断。此外,在神经切除产生的间隙区域,植入壳聚糖、含孕酮壳聚糖和硅胶管的坐骨神经中轴突数量和髓鞘化程度均减少。在坐骨神经切断180天后,膝关节运动功能恢复到同龄对照大鼠观察到的水平。在植入含孕酮壳聚糖管的大鼠中,刺激坐骨神经近端和管内节段会产生肌电图反应。坐骨神经近端和管内节段的轴突形态与对侧未横断神经相似。
含孕酮壳聚糖管导致腓肠肌出现异常神经支配,这使得步态运动部分恢复,并且在重建主要神经支配时可能足以重新支配协同失神经肌肉。年轻(90天龄)和年长(180天龄)大鼠的后肢运动学参数有所不同。
