Research of acellular xenogeneic nerve combined with adipose-derived stem cells and platelet rich plasma in repair of rabbit facial nerve injury_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

SUN Yanna ,  ZHANG Rongming , MAO Xu , ZHANG Mengshu

Department of Burn Plastic Surgery, the First Affiliated Hospital of Jinzhou Medical University, Jinzhou Liaoning, 121000, P.R.China;

Corresponding?author：

ZHANG Rongming, Email: zrm99999@126.com

Keywords：

Tissue engineered nerve; facial nerve repair; adipose-derived stem cells; acellular xenogeneic nerve; platelet rich plasma; rabbit

DOI：

10.7507/1002-1892.201711079

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ObjectiveTo investigate the early effects of acellular xenogeneic nerve combined with adipose-derived stem cells (ADSCs) and platelet rich plasma (PRP) in repairing facial nerve injury in rabbits.MethodsThe bilateral sciatic nerves of 15 3-month-old male Sprague-Dawley rats were harvested and decellularized as xenografts. The allogeneic ADSCs were extracted from the neck and back fat pad of healthy adult New Zealand rabbits with a method of digestion by collagenase type Ⅰ and the autologous PRP was prepared by two step centrifugation. The 3rd generation ADSCs with good growth were labelled with CM-Dil living cell stain, and the labelling and fluorescence attenuation of the cells were observed by fluorescence microscope. Another 32 New Zealand rabbits were randomly divided into 4 groups and established the left facial nerve defect in length of 1 cm (n=8). The nerve defects of groups A, B, C, and D were repaired with CM-Dil-ADSCs composite xenogeneic nerve+autologous PRP, CM-Dil-ADSCs composite xenogeneic nerve, xenogeneic nerve, and autologous nerve, respectively. At 1 and 8 weeks after operation, the angle between the upper lip and the median line of the face (angle θ) was measured. At 4 and 8 weeks after operation, the nerve conduction velocity was recorded by electrophysiological examination. At 8 weeks after operation, the CM-Dil-ADSCs at the distal and proximal ends of regenerative nerve graft segment in groups A and B were observed by fluorescence microscopy; after toluidine blue staining, the number of myelinated nerve fibers in regenerated nerve was calculated; the structure of regenerated nerve fibers was observed by transmission electron microscope.ResultsADSCs labelled by CM-Dil showed that the labelling rate of cells was more than 90% under fluorescence microscope, and the labelled cells proliferated well, and the fluorescence attenuated slightly after passage. All the animals survived after operation, the incision healed well and no infection occurred. At 1 week after operation, all the animals in each group had different degrees of dysfunction. The angle θ of the left side in groups A, B, C, and D were (53.4±2.5), (54.0±2.6), (53.7±2.4), and (53.0±2.1)°, respectively; showing significant differences when compared with the healthy sides (P<0.05). At 8 weeks after operation, the angle θ of the left side in groups A, B, C, and D were (61.9±4.7), (56.8±4.2), (54.6±3.8), and (63.8±5.8)°, respectively; showing significant differences when compared with the healthy sides and with the values at 1 week (P<0.05). Gross observation showed that the integrity and continuity of regenerated nerve in 4 groups were good, and no neuroma and obvious enlargement was found. At 4 and 8 weeks after operation, the electrophysiological examination results showed that the nerve conduction velocity was significantly faster in groups A and D than in groups B and C (P<0.05), and in group B than in group C (P<0.05); no significant difference was found between groups A and D (P>0.05). At 8 weeks after operation, the fluorescence microscopy observation showed a large number of CM-Dil-ADSCs passing through the distal and proximal transplants in group A, and relatively few cells passing in group B. Toluidine blue staining showed that the density of myelinated nerve fibers in groups A and D were significantly higher than those in groups B and C (P<0.05), and in group B than in group C (P<0.05); no significant difference was found between groups A and D (P>0.05). Transmission electron microscope observation showed that the myelinated nerve sheath in group D was large in diameter and thickness in wall. The morphology of myelin sheath in group A was irregular and smaller than that in group D, and there was no significant difference between groups B and C.ConclusionADSCs can survive as a seed cell in vivo, and can be differentiated into Schwann-like cells under PRP induction. It can achieve better results when combined with acellular xenogeneic nerve to repair peripheral nerve injury in rabbits.

Citation： SUN Yanna, ZHANG Rongming, MAO Xu, ZHANG Mengshu. Research of acellular xenogeneic nerve combined with adipose-derived stem cells and platelet rich plasma in repair of rabbit facial nerve injury. Chinese Journal of Reparative and Reconstructive Surgery, 2018, 32(6): 736-744. doi: 10.7507/1002-1892.201711079 Copy

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14.	Zuk PA, Zhu M, Mizuno H, et al. Multilineage cells from human adipose tissue: implications for cell-based therapies. Tissue Eng, 2001, 7(2): 211-228.
15.	Tamaki T, Uchiyama Y, Hirata M, et al. Therapeutic isolation and expansion of human skeletal muscle-derived stem cells for the use of muscle-nerve-blood vessel reconstitution. Front Physiol, 2015, 6: 165.
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22.	張興安, 吳蜀江, 盧海彬, 等. 自體富血小板血漿修復面神經損傷. 中國組織工程研究, 2013, 17(28): 5145-5150.
23.	丁昌榮, 楊選影, 韓迎秋, 等. 富血小板血漿誘導骨髓間充質干細胞結合化學萃取去細胞神經修復坐骨神經缺損. 中國組織工程研究與臨床康復, 2010, 14(27): 4946-4950.
24.	唐乙. 體外誘導小鼠肌源干細胞向類雪旺細胞分化的條件和機制研究. 上海: 第二軍醫大學, 2012.

1. 孫菲. ADSCs-復合去細胞動脈導管對大鼠面神經缺損的修復. 西安: 第四軍醫大學, 2011.
2. Liu Z, Zhu S, Liu L, et al. A magnetically responsive nanocomposite scaffold combined with Schwann cells promotes sciatic nerve regeneration upon exposure to magnetic field. Int J Nanomedicine, 2017, 12: 7815-7832.
3. Gu X, Ding F, Yang Y, et al. Construction of tissue engineered nerve grafts and their application in peripheral nerve regeneration. Prog Neurobiol, 2011, 93(2): 204-230.
4. Deal DN, Griffin JW, Hogan MV. Nerve conduits for nerve repair or reconstruction. J Am Acad Orthop Surg, 2012, 20(2): 63-68.
5. 池昊天, 陽運康. 干細胞與脫細胞異體神經支架在周圍神經長段缺損中的應用. 中國組織工程研究, 2014, 18(21): 3398-3405.
6. Jiang CQ, Hu J, Xiang JP, et al. Tissue-engineered rhesus monkey nerve grafts for the repair of long ulnar nerve defects: similar outcomes to autologous nerve grafts. Neural Regen Res, 2016, 11(11): 1845-1850.
7. Kusaba H, Terada-Nakaishi M, Wang W, et al. Comparison of nerve regenerative efficacy between decellularized nerve graft and nonwoven chitosan conduit. Biomed Mater Eng, 2016, 27(1): 75-85.
8. Hudson TW, Liu SY, Schmidt CE. Engineering an improved acellular nerve graft via optimized chemical processing. Tissue Eng, 2004, 10(9-10): 1346-1358.
9. 張琳, 富澤龍, 馮銳. 人脂肪干細胞復合富血小板血漿治療裸鼠放射性皮膚損傷的實驗研究. 醫學研究雜志, 2015, 44(7): 57-61.
10. Gao S, Zheng Y, Cai Q, et al. Comparison of morphology and biocompatibility of acellular nerve scaffolds processed by different chemical methods. J Mater Sci Mater Med, 2014, 25(5): 1283-1291.
11. Jiang X, Lim SH, Mao HQ, et al. Current applications and future perspectives of artificial nerve conduits. Exp Neurol, 2010, 223(1): 86-101.
12. Webber CA, Christie KJ, Cheng C, et al. Schwann cells direct peripheral nerve regeneration through the Netrin-1 receptors, DCC and Unc5H2. Glia, 2011, 59(10): 1503-1517.
13. Negishi H, Dezawa M, Oshitari T, et al. Optic nerve regeneration within artificial Schwann cell graft in the adult rat. Brain Res Bull, 2001, 55(3): 409-419.
14. Zuk PA, Zhu M, Mizuno H, et al. Multilineage cells from human adipose tissue: implications for cell-based therapies. Tissue Eng, 2001, 7(2): 211-228.
15. Tamaki T, Uchiyama Y, Hirata M, et al. Therapeutic isolation and expansion of human skeletal muscle-derived stem cells for the use of muscle-nerve-blood vessel reconstitution. Front Physiol, 2015, 6: 165.
16. 金長鑫, 吳瓊, 劉燁, 等. 富血小板血漿凝膠聯合脂肪干細胞促進大鼠創面修復的實驗研究. 東南國防醫藥, 2016, 18(4): 349-353.
17. 林顥, 李鵬, 孫杰聰, 等. 富血小板血漿對人臍帶間充質干細胞增殖及成骨分化的影響. 廣東醫學, 2016, 37(9): 1274-1277.
18. Mariani E, Canella V, Berlingeri A, et al. Leukocyte presence does not increase microbicidal activity of Platelet-rich Plasma in vitro. BMC Microbiology, 2015, 15(1): 149-161.
19. 杜剛, 李林, 張波, 等. 富血小板血漿聯合骨髓間充質干細胞對大鼠脊髓損傷的作用. 現代預防醫學, 2015, 42(5): 878-881.
20. 余剛, 徐斌, 涂俊, 等. 外周血間充質干細胞復合富血小板血漿對腱骨界面愈合的影響. 安徽醫科大學學報, 2017, 52(5): 770-773.
21. 程文俊, 左偉, 肖志宏, 等. 復合富血小板血漿成骨微環境對兔骨髓間充質干細胞增殖分化的影響. 中華實驗外科雜志, 2016, 33(11): 2469-2471.
22. 張興安, 吳蜀江, 盧海彬, 等. 自體富血小板血漿修復面神經損傷. 中國組織工程研究, 2013, 17(28): 5145-5150.
23. 丁昌榮, 楊選影, 韓迎秋, 等. 富血小板血漿誘導骨髓間充質干細胞結合化學萃取去細胞神經修復坐骨神經缺損. 中國組織工程研究與臨床康復, 2010, 14(27): 4946-4950.
24. 唐乙. 體外誘導小鼠肌源干細胞向類雪旺細胞分化的條件和機制研究. 上海: 第二軍醫大學, 2012.

Chinese Journal of Reparative and Reconstructive Surgery

Research of acellular xenogeneic nerve combined with adipose-derived stem cells and platelet rich plasma in repair of rabbit facial nerve injury

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