EFFECT EVALUATION OF ELECTROSPUN CHITOSAN/POLYLACTIC ACID NERVE CONDUITS FOR REPAIR OF PERIPHERAL NERVE DEFECT IN RATS_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

LIUYandong , DOUYuandong ,  HOUChunlin , LINHaodong

Department of Orthopaedic Surgery, Shanghai Changzheng Hospital, Shanghai, 200003, P. R. China;

Corresponding author：

HOUChunlin, Email: chunlin_hou@163.com

Keywords：

Peripheral nerve defect; Nerve repair; Nerve conduit; Electrospun; Chitosan; Polylactic acid; Rat

DOI：

10.7507/1002-1892.20150130

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Objective To investigate the effect of electrospun chitosan/polylactic acid (ch/PLA) nerve conduit for repairing peripheral nerve defect in rats. Methods Nerve conducts loaded with ch/PLA was made by the way of electrospun. The mechanical property, hydrophility, biocompatibility were tested, and the scanning electron microscope was used to observe the ultrastructure. The same experiments were also performed on pure PLA nerve conducts as a comparison. Then, 54 Sprague Dawley rats were divided into 3 groups randomly, 18 rats in each group. Firstly, the 10 mm defects in the right sciatic nerves were made in the rats and were respectively repaired with ch/PLA (group A), autografts (group B), and no implant (group C). At 4, 8, and 12 weeks after operation, general observations, sciatic functional index (SFI), electrophysiological evaluation, wet weight of gastrocnemius and soleus muscles, histological examination, immunohistological analysis, and transmission electron microscopy were performed to evaluate the effects. Results Compared with pure PLA nerve conducts, the addition of chitosan could improve the mechanical property, hydrophility, biocompatibility, and ultrastructure of the nerve conducts. At 4 weeks postoperatively, the regenerated nerve bridged the nerve defect in group A. The SFI improved gradually in both group A and group B, showing no significant difference (P>0.05). Compound muscle action potentials and nerve conduction velocity could be detected in both group A and group B at 8 and 12 weeks after operation, and significant improvements were shown in both groups (P<0.05). The wet weight and myocyte cross section of gastrocnemius and soleus muscles showed no significant difference between group A and group B (P>0.05), but there was significant difference when compared with group C (P<0.05) at 12 weeks postoperatively. Immunohistological analysis revealed that S-100 positive Schwann cells migrated in both group A and group B, and axon also regenerated by immunohistological staining for growth associated protein 43 and neurofilaments 160. Transmission electron microscopy showed no significant difference in the diameter of nerve fiber between group A and group B (P>0.05), but the thickness of myelin sheath in group A was significantly larger than that in group B (P<0.05). Conclusion The electrospun ch/PLA nerve conduits can effectively promote the peripheral nerve regeneration, and may promise an alternative to nerve autograft for repairing peripheral nerve defect.

Citation： LIUYandong, DOUYuandong, HOUChunlin, LINHaodong. EFFECT EVALUATION OF ELECTROSPUN CHITOSAN/POLYLACTIC ACID NERVE CONDUITS FOR REPAIR OF PERIPHERAL NERVE DEFECT IN RATS. Chinese Journal of Reparative and Reconstructive Surgery, 2015, 29(5): 600-608. doi: 10.7507/1002-1892.20150130 Copy

1.	Kline DG. Surgical repair of peripheral nerve injury. Muscle Nerve, 1990, 13(9):843-852.
2.	Stone L, Keenan MA. Peripheral nerve injuries in the adult with traumatic brain injury. Clin Orthop Relat Res, 1988, (233):136-144.
3.	Schmidt CE, Leach JB. Neural tissue engineering:strategies for repair and regeneration. Annu Rev Biomed Eng, 2003, 5:293-347.
4.	Heath CA, Rutkowski GE. The development of bioartificial nerve grafts for peripheral-nerve regeneration. Tibtech, 1998, 16(4):163-168.
5.	谢峰, 李青峰, 赵林森. 新型复合生物材料导管修复大鼠周围神经缺损的实验研究. 中华整形外科杂志, 2005, 21(4):295-298.
6.	Wu C, Ramaswamy Y, Zhu Y, et al. The effect of mesoporous bioactive glass on the physiochemical, biological and drug-release properties of poly (DL-lactide-co-glycolide) films. Biomaterials, 2009, 30(12):2199-2208.
7.	Bain JR, Mackinnon SE, Hunter DA. Functional evaluation of complete sciatic, peroneal, and posterior tibial nerve lesions in the rat. Plast Reconstr Surg, 1989, 83(1):83-129.
8.	Terris DJ, Cheng ET, Utley DS, et al. Functional recovery following nerve injury and repair by silicon tubulization:comparison of laminin-fibronectin, dialyzed plasma, collagen gel, and phosphate buffered solution. Auris Nasus Larynx, 1999, 26(2):117-122.
9.	Schlosshauer B, Dreesmann L, Schaller HE, et al. Synthetic nerve guide implants in humans:a comprehensive survey. Neurosurgery, 2006, 59(4):740-747.
10.	Chen MB, Zhang F, Lineaweaver WC. Luminal fillers in nerve conduits for peripheral nerve repair. Ann Plast Surg, 2006, 57(4):462-471.
11.	Panseri S, Cunha C, Lowery J, et al. Electrospun micro- and nanofiber tubes for functional nervous regeneration in sciatic nerve transections. BMC Biotechnol, 2008, 8:39.
12.	Lundborg G, Dahlin LB, Danielsen N, et al. Nerve regeneration in si1icone chambers:influence of gap length and of distal stump components. Exp Neurol, 1982, 76(2):361-375.
13.	Xia WS, Liu P, Zhang JL, et al. Biological activities of chitosan and chitooligosaccharides. Food Hydrocolloids, 2011, 25(2):170-179.
14.	Wittaya-areekul S, Prahsarn C. Development and in vitro evaluation of chitosan-polysaccharides composite wound dressings. Int J Pharm, 2006, 313(1-2):123-128.
15.	Jiang X, Lim SH, Mao HQ, et al. Current applications and future perspectives of artificial nerve conduits. Exp Neurol, 2010, 223(1):86-101.
16.	Zhang K, Mo X, Huang C, et al. Electrospun scaffolds from silk fibroin and their cellular compatibility. J Biomed Mater Res A, 2010, 93(3):976-983.
17.	Kim YT, Haftel VK, Kumar S, et al. The role of aligned polymer fiber-based constructs in the bridging of long peripheral nerve gaps. Biomaterials, 2008, 29(21):3117-3127.
18.	Wei X, Lao J, Gu YD. Bridging peripheral nerve defect with chitosan-collagen film. Chin J Traumatol, 2003, 6(3):131-134.
19.	Lin YL, Jen JC, Hsu SH, et al. Sciatic nerve repair by microgrooved nerve conduits made of chitosan-gold nanocomposites. Surg Neurol, 2008, 70 Suppl 1:S1:9-18.
20.	Gu J, Hu W, Deng A, et al. Surgical repair of a 30 mm long human median nerve defect in the distal forearm by implantation of a chitosan-PGA nerve guidance conduit. J Tissue Eng Regen Med, 2012, 6(2):163-168.

1. Kline DG. Surgical repair of peripheral nerve injury. Muscle Nerve, 1990, 13(9):843-852.
2. Stone L, Keenan MA. Peripheral nerve injuries in the adult with traumatic brain injury. Clin Orthop Relat Res, 1988, (233):136-144.
3. Schmidt CE, Leach JB. Neural tissue engineering:strategies for repair and regeneration. Annu Rev Biomed Eng, 2003, 5:293-347.
4. Heath CA, Rutkowski GE. The development of bioartificial nerve grafts for peripheral-nerve regeneration. Tibtech, 1998, 16(4):163-168.
5. 谢峰, 李青峰, 赵林森. 新型复合生物材料导管修复大鼠周围神经缺损的实验研究. 中华整形外科杂志, 2005, 21(4):295-298.
6. Wu C, Ramaswamy Y, Zhu Y, et al. The effect of mesoporous bioactive glass on the physiochemical, biological and drug-release properties of poly (DL-lactide-co-glycolide) films. Biomaterials, 2009, 30(12):2199-2208.
7. Bain JR, Mackinnon SE, Hunter DA. Functional evaluation of complete sciatic, peroneal, and posterior tibial nerve lesions in the rat. Plast Reconstr Surg, 1989, 83(1):83-129.
8. Terris DJ, Cheng ET, Utley DS, et al. Functional recovery following nerve injury and repair by silicon tubulization:comparison of laminin-fibronectin, dialyzed plasma, collagen gel, and phosphate buffered solution. Auris Nasus Larynx, 1999, 26(2):117-122.
9. Schlosshauer B, Dreesmann L, Schaller HE, et al. Synthetic nerve guide implants in humans:a comprehensive survey. Neurosurgery, 2006, 59(4):740-747.
10. Chen MB, Zhang F, Lineaweaver WC. Luminal fillers in nerve conduits for peripheral nerve repair. Ann Plast Surg, 2006, 57(4):462-471.
11. Panseri S, Cunha C, Lowery J, et al. Electrospun micro- and nanofiber tubes for functional nervous regeneration in sciatic nerve transections. BMC Biotechnol, 2008, 8:39.
12. Lundborg G, Dahlin LB, Danielsen N, et al. Nerve regeneration in si1icone chambers:influence of gap length and of distal stump components. Exp Neurol, 1982, 76(2):361-375.
13. Xia WS, Liu P, Zhang JL, et al. Biological activities of chitosan and chitooligosaccharides. Food Hydrocolloids, 2011, 25(2):170-179.
14. Wittaya-areekul S, Prahsarn C. Development and in vitro evaluation of chitosan-polysaccharides composite wound dressings. Int J Pharm, 2006, 313(1-2):123-128.
15. Jiang X, Lim SH, Mao HQ, et al. Current applications and future perspectives of artificial nerve conduits. Exp Neurol, 2010, 223(1):86-101.
16. Zhang K, Mo X, Huang C, et al. Electrospun scaffolds from silk fibroin and their cellular compatibility. J Biomed Mater Res A, 2010, 93(3):976-983.
17. Kim YT, Haftel VK, Kumar S, et al. The role of aligned polymer fiber-based constructs in the bridging of long peripheral nerve gaps. Biomaterials, 2008, 29(21):3117-3127.
18. Wei X, Lao J, Gu YD. Bridging peripheral nerve defect with chitosan-collagen film. Chin J Traumatol, 2003, 6(3):131-134.
19. Lin YL, Jen JC, Hsu SH, et al. Sciatic nerve repair by microgrooved nerve conduits made of chitosan-gold nanocomposites. Surg Neurol, 2008, 70 Suppl 1:S1:9-18.
20. Gu J, Hu W, Deng A, et al. Surgical repair of a 30 mm long human median nerve defect in the distal forearm by implantation of a chitosan-PGA nerve guidance conduit. J Tissue Eng Regen Med, 2012, 6(2):163-168.

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Chinese Journal of Reparative and Reconstructive Surgery

EFFECT EVALUATION OF ELECTROSPUN CHITOSAN/POLYLACTIC ACID NERVE CONDUITS FOR REPAIR OF PERIPHERAL NERVE DEFECT IN RATS

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