再生(生物学)
坐骨神经
生物医学工程
周围神经损伤
复合肌肉动作电位
自愈水凝胶
肌电图
电气导管
神经导管
组织工程
轴突
外围设备
医学
化学
解剖
电生理学
内科学
机械工程
有机化学
精神科
生物
工程类
细胞生物学
作者
Cheuk Sun Edwin Lai,Viridiana Leyva-Aranda,Victoria H. Kong,Tania L. Lopez‐Silva,Adam C. Farsheed,Carlo D. Cristobal,Joseph W. R. Swain,Hyun Kyoung Lee,Jeffrey D. Hartgerink
标识
DOI:10.1021/acsabm.2c00132
摘要
Transected peripheral nerve injury (PNI) affects the quality of life of patients, which leads to socioeconomic burden. Despite the existence of autografts and commercially available nerve guidance conduits (NGCs), the complexity of peripheral nerve regeneration requires further research in bioengineered NGCs to improve surgical outcomes. In this work, we introduce multidomain peptide (MDP) hydrogels, as intraluminal fillers, into electrospun poly(ε-caprolactone) (PCL) conduits to bridge 10 mm rat sciatic nerve defects. The efficacy of treatment groups was evaluated by electromyography and gait analysis to determine their electrical and motor recovery. We then studied the samples' histomorphometry with immunofluorescence staining and automatic axon counting/measurement software. Comparison with negative control group shows that PCL conduits filled with an anionic MDP may improve functional recovery 16 weeks postoperation, displaying higher amplitude of compound muscle action potential, greater gastrocnemius muscle weight retention, and earlier occurrence of flexion contracture. In contrast, PCL conduits filled with a cationic MDP showed the least degree of myelination and poor functional recovery. This phenomenon may be attributed to MDPs' difference in degradation time. Electrospun PCL conduits filled with an anionic MDP may become an attractive tissue engineering strategy for treating transected PNI when supplemented with other bioactive modifications.
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