Alike Yamuhanmode, Yushan Maimaiaili, Keremu Ajimu, Abulaiti Alimujiang, Liu Zhen-Hui, Fu Wei, Yan Li-Wei, Yusufu Aihemaitijiang, Zhu Qing-Tang
Department of Microrepair and Reconstruction, the First Affiliated Hospital of Xinjiang Medical University, Urumqi, Xinjiang Uygur Autonomous Region, China.
Orthopedic Center, the First People's Hospital of Kashgar, Kashi, Xinjiang Uygur Autonomous Region, China.
Neural Regen Res. 2019 Dec;14(12):2173-2182. doi: 10.4103/1673-5374.262601.
The intermingling of regenerated nerve fibers inside nerve grafts is the main reason for mismatched nerve fibers. This is one of the key factors affecting limb function recovery after nerve injury. Previous research has shown that the accuracy of axon regeneration can be improved by a bionic structural implant. To this aim, iodine and freeze-drying high-resolution micro-computed tomography was performed to visualize the 3D topography of the New Zealand rabbit sciatic nerve (25 mm). A series of 1-, 2-, 3-, and 4-custom anatomy-based nerve conduits (CANCs) were fabricated based on the anatomical structure of the nerve fascicle. The match index, luminal surface, and mechanical properties of CANCs were evaluated before implanting in a 10-mm gap of the sciatic nerve. Recovery was evaluated by histomorphometric analyses, electrophysiological study, gastrocnemius muscle weight recovery ratio, and behavioral assessments at 12 and 24 weeks postoperatively. The accuracy of nerve regeneration was determined by changes in fluorescence-labeled profile number during simultaneous retrograde tracing. Our results showed that the optimal preprocessing condition for high-resolution micro-computed tomography visualization was treatment of the sciatic nerve with 40% Lugol's solution for 3 days followed by lyophilization for 2 days. In vitro experiments demonstrated that the match index was highest in the 3-CANC group, followed by the 2-, 1-, and 4-CANC groups. The luminal surface was lowest in the 1-CANC group. Mechanical properties (transverse compressive and bending properties) were higher in the 3- and 4-CANC groups than in the 1-CANC group. In vivo experiments demonstrated that the recovery (morphology of regenerated fibers, compound muscle action potential, gastrocnemius muscle weight recovery ratio, pain-related autotomy behaviors, and range of motion) in the 3-CANC group was superior to the other CANC groups, and achieved the same therapeutic effect as the autograft. The simultaneous retrograde tracing results showed that the percentages of double-labeled profiles of the 2-, 3-, and 4-CANC groups were comparatively lower than that of the 1-CANC group, which indicates that regenerated nerve fascicles were less intermingled in the 2-, 3-, and 4-CANC groups. These findings demonstrate that the visualization of the rabbit sciatic nerve can be achieved by iodine and freeze-drying high-resolution micro-computed tomography, and that this method can be used to design CANCs with different channels that are based on the anatomical structure of the nerve. Compared with the 1-CANC, 3-CANC had a higher match index and luminal surface, and improved the accuracy of nerve regeneration by limiting the intermingling of the regenerated fascicles. All procedures were approved by the Animal Care and Use Committee, Xinjiang Medical University, China on April 4, 2017 (ethics approval No. IACUC20170315-02).
神经移植物内部再生神经纤维的相互交织是神经纤维错配的主要原因。这是影响神经损伤后肢体功能恢复的关键因素之一。先前的研究表明,仿生结构植入物可提高轴突再生的准确性。为此,采用碘和冷冻干燥高分辨率微型计算机断层扫描来可视化新西兰兔坐骨神经(25毫米)的三维地形。基于神经束的解剖结构制作了一系列1、2、3和4个基于定制解剖结构的神经导管(CANC)。在将CANC植入坐骨神经10毫米间隙之前,评估其匹配指数、管腔表面和机械性能。术后12周和24周通过组织形态计量学分析、电生理研究、腓肠肌重量恢复率和行为评估来评估恢复情况。通过同步逆行追踪期间荧光标记轮廓数的变化来确定神经再生的准确性。我们的结果表明,高分辨率微型计算机断层扫描可视化的最佳预处理条件是用40%卢戈氏溶液处理坐骨神经3天,然后冷冻干燥2天。体外实验表明,3-CANC组的匹配指数最高,其次是2-CANC组、1-CANC组和4-CANC组。1-CANC组的管腔表面最低。3-CANC组和4-CANC组的机械性能(横向压缩和弯曲性能)高于1-CANC组。体内实验表明,3-CANC组的恢复情况(再生纤维形态、复合肌肉动作电位、腓肠肌重量恢复率、疼痛相关的自残行为和活动范围)优于其他CANC组,并且达到了与自体移植相同的治疗效果。同步逆行追踪结果表明,2-CANC组、3-CANC组和4-CANC组的双标记轮廓百分比相对低于1-CANC组,这表明2-CANC组、3-CANC组和4-CANC组中再生神经束的相互交织较少。这些发现表明,通过碘和冷冻干燥高分辨率微型计算机断层扫描可以实现兔坐骨神经的可视化,并且该方法可用于设计基于神经解剖结构的具有不同通道的CANC。与1-CANC相比,3-CANC具有更高的匹配指数和管腔表面,并通过限制再生束的相互交织提高了神经再生的准确性。所有程序均于2017年4月4日获得中国新疆医科大学动物护理和使用委员会的批准(伦理批准号IACUC20170315-02)。
