干细胞负载胶原+聚己内酯+多壁碳纳米管纳米神经支架在Wistar大鼠坐骨神经挤压损伤后再生中的应用

IF 2.5 Q3 CELL BIOLOGY Cellular Physiology and Biochemistry Pub Date : 2023-11-15 DOI:10.33594/000000670
Mamta Mishra, Swapan Kumar Maiti, Kalaiselvan Elangovan, Shivaraju Shivaramu, Karam Pal Singh, Amitha Banu S, Merlin Mamachan, Manish Arya, Divya Mishra, Jurgen Hescheler
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引用次数: 0

摘要

背景/目的:所有的身体功能都是由一个庞大而复杂的网络——神经系统——激活、同步和控制的。损伤后,神经损伤的病理生理经过不同的途径。轴突可能从损伤部位退行性缩回一小段距离,除非损伤靠近细胞体,在这种情况下,它继续到体细胞并经历逆行神经元变性。否则,远端部分出现沃勒氏变性,其特征是轴突肿胀、球状体和细胞骨架变性。本研究的目的是评估间充质干细胞负载神经支架和胰岛素样生长因子I (IGF-I)在大鼠坐骨神经损伤后神经再生中的潜力。方法:麻醉动物,在左大腿上开颅外侧切口。暴露坐骨神经,在第二锁定位置使用止血剂进行挤压损伤90秒。采用常规方法缝合肌肉和皮肤,制备大鼠坐骨挤压损伤模型。将动物模型平均分为A、B、C、D、E 5组,分别采用磷酸缓冲盐水(PBS)、碳纳米管神经支架、IGF-I支架、干细胞负载支架和IGF-I干细胞负载支架处理。进行体外支架试验。通过物理-神经元、生化、组织病理学检查,以及NRP-1、NRP-2、GAP-43的相对表达和扫描电镜评估神经再生情况。结果:90秒挤压伤坐骨神经损伤模型标准化并成功应用于本研究。各组生化指标均在正常范围内,未见支架相关变化。物理-神经元、组织病理学、相关基因表达和扫描电镜观察显示,E组和D组有明显的神经再生,其次是C组和b组,a组没有再生。结论:碳纳米管支架为神经再生提供了电导率,而大鼠骨髓源间充质干细胞可诱导轴突萌发、细胞转化;而igf - 1诱导干细胞分化、髓磷脂合成、血管生成和肌肉分化。
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Evaluation of Stem Cell Laden Collagen + Polycaprolactone + Multi-Walled Carbon Nano-Tubes Nano-Neural Scaffold with and Without Insulin Like Growth Factor-I For Sciatic Nerve Regeneration Post Crush Injury in Wistar Rats.

Background/aims: All body functions are activated, synchronized and controlled by a substantial, complex network, the nervous system. Upon injury, pathophysiology of the nerve injury proceeds through different paths. The axon may undergo a degenerative retraction from the site of injury for a short distance unless the injury is near to the cell body, in which case it continues to the soma and undergoes retrograde neuronal degeneration. Otherwise, the distal section suffers from Wallerian degeneration, which is marked by axonal swelling, spheroids, and cytoskeleton degeneration. The objective of the study was to evaluate the potential of mesenchymal stem cell laden neural scaffold and insulin-like growth factor I (IGF-I) in nerve regeneration following sciatic nerve injury in a rat model.

Methods: The animals were anaesthetized and a cranio-lateral incision over left thigh was made. Sciatic nerve was exposed and crush injury was introduced for 90 seconds using haemostat at second locking position. The muscle and skin were sutured in routine fashion and thus the rat model of sciatic crush injury was prepared. The animal models were equally distributed into 5 different groups namely A, B, C, D and E and treated with phosphate buffer saline (PBS), carbon nanotubes based neural scaffold only, scaffold with IGF-I, stem cell laden scaffold and stem cell laden scaffold with IGF-I respectively. In vitro scaffold testing was performed. The nerve regeneration was assessed based on physico-neuronal, biochemical, histopathological examination, and relative expression of NRP-1, NRP-2 and GAP-43 and scanning electron microscopy.

Results: Sciatic nerve injury model with crush injury produced for 90 seconds was standardized and successfully used in this study. All the biochemical parameters were in normal range in all the groups indicating no scaffold related changes. Physico-neuronal, histopathological, relative gene expression and scanning electron microscopy observations revealed appreciable nerve regeneration in groups E and D, followed by C and B. Restricted to no regeneration was observed in group A.

Conclusion: Carbon nanotubes based scaffold provided electro-conductivity for proper neuronal regeneration while rat bone marrow-derived mesenchymal stem cells were found to induce axonal sprouting, cellular transformation; whereas IGF-I induced stem cell differentiation, myelin synthesis, angiogenesis and muscle differentiation.

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来源期刊
CiteScore
5.80
自引率
0.00%
发文量
86
审稿时长
1 months
期刊介绍: Cellular Physiology and Biochemistry is a multidisciplinary scientific forum dedicated to advancing the frontiers of basic cellular research. It addresses scientists from both the physiological and biochemical disciplines as well as related fields such as genetics, molecular biology, pathophysiology, pathobiochemistry and cellular toxicology & pharmacology. Original papers and reviews on the mechanisms of intracellular transmission, cellular metabolism, cell growth, differentiation and death, ion channels and carriers, and the maintenance, regulation and disturbances of cell volume are presented. Appearing monthly under peer review, Cellular Physiology and Biochemistry takes an active role in the concerted international effort to unravel the mechanisms of cellular function.
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