EXPERIMENTAL STUDY ON GRADIENT OF NERVE GROWTH FACTOR IMMOBILIZED CONDUITS PROMOTING PERIPHERAL NERVE REGENERATION IN RATS_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

 LINQiang ¹ , CAIYangting ² , LIHaoshen ²

1. Department of Orthopedic Surgery, Guangdong Provincial Hospital of Traditional Chinese Medicine, Guangzhou Guangdong, 510120, P. R. China;
2. Second School of Clinical Medicine, Guangzhou University of Chinese Medicine, Guangzhou Guangdong, 510120, P. R. China;

Corresponding author：

LINQiang, Email: qiang_linm@163.com

Keywords：

Nerve tissue engineering; Nerve conduits; Nerve growth factor; Peripheral nerve defect; Rat

DOI：

10.7507/1002-1892.20140037

Video：

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Abstract Full text Figures/Tables Video References Cited by

Objective To study the effect of the loaded concentration gradient of nerve growth factor (NGF) immobilized conduit on rat peripheral nerve defect repair. Methods The peripheral nerve conduits made of poly (ε-caprolactone)-block-poly (L-lactide-co-ε-caprolactone) were prepared with uniform loads or concentration gradient loads by combining differential absorption of NGF/silk fibroin (SF) coating, and the gradient of NGF was immobilized in the nerve conduits. ELISA method was used to exam the NGF release for 12 weeks in vitro. Twenty-four male Sprague Dawley rats (weighing, 220-250 g) were selected to establish the right sciatic nerve defect model (14 mm in length) and randomly divided into 4 groups according to repair methods. The transected nerve was bridged by a blank conduit without NGF in group A, by a conduit containing uniform loads of NGF in group B, by a conduit concentration gradient loads of NGF in group C, and by the autogenous nerve segment in group D. The gross observation, electrophysiological examination, histological observation, and transmission electron microscope observation were carried out to assess the nerve regeneration at 12 weeks after surgery. Results The cumulative release amount of NGF was (14.2±1.4) ng/mg and (13.7±1.3) ng/mg in gradient of NGF loaded conduits and uniform NGF loaded conduits respectively at 12 weeks, showing no significant difference (t=0.564, P=0.570). All the animals survived to completion of the experiment; plantar ulcers occurred at 4 days, which healed at 12 weeks; groups C and D were better than groups A and B in ulcerative healing. At 12 weeks after surgery, the compound muscle action potential of group A was significantly lower than that of groups B, C, and D (P<0.05), and group B was significantly lower than groups C and D (P<0.05), but no significant difference was found between groups C and D (P>0.05). The axon density of group C was significantly higher that of groups A, B, and D (P<0.05); group D was significantly higher than groups A, B, and C, and group C was significantly higher than groups A and B in the axon number, axon diameter, and area of muscle fiber (P<0.05); the thickness of myelin sheath of groups C and D was significantly larger than that of groups A and B (P<0.05), but no significant difference was found between groups C and D (P>0.05). Conclusion Gradient of NGF loaded nerve condnits for rat sciatic nerve defect has similar results to autogenous nerve, with a good bridge, which can promote the sciatic nerve regeneration, improve the myelinization of the regenerating nerve, and accelerate the function reconstruction of the regenerating nerve.

Citation： LINQiang, CAIYangting, LIHaoshen. EXPERIMENTAL STUDY ON GRADIENT OF NERVE GROWTH FACTOR IMMOBILIZED CONDUITS PROMOTING PERIPHERAL NERVE REGENERATION IN RATS. Chinese Journal of Reparative and Reconstructive Surgery, 2014, 28(2): 167-172. doi: 10.7507/1002-1892.20140037 Copy

1.	唐圆,刘湘华,刘丹,等.以组织工程建构技术修复周围神经损伤的难点.中国组织工程研究,2013,17(7):1295-1304.
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11.	饶毅,吴瑛.神经细胞迁移导向的分子机制.生理科学进展,2000,31(3):198-204.
12.	Li J,Zhu L,Zhang M,et al.Microfluidic device for studying cell migration in single or co-existing chemical gradients and electric fields.Biomicrofluidics,2012,6(2):24121-2412113.
13.	Roam JL,Xu H,Nguyen PK,et al.The formation of protein concentration gradients mediated by density differences of poly (ethylene glycol) microspheres.Biomaterials,2010,31(33):8642-8650.
14.	Vetter I,Pujic Z,Goodhill GJ.The response of dorsal root ganglion axons to nerve growth factor gradients depends on spinal level.J Neurotrauma,2010,27(8):1379-1386.
15.	Wenk E,Merkle HP,Meinel L.Silk fibroin as a vehicle for drug delivery applications.J Control Release,2011,150(2):128-141.
16.	Sheng XY,Fan LP,Mo XM,et al.Electrospun silk fibroin composite nanofibrous mats loaded with vitamin A and E.J Control Release,2013,172(1):e35-e36.
17.	朱超,蒋欣泉,张志愿.丝蛋白作为骨组织工程支架材料的研究进展.国际口腔医学杂志,2010,37(5):541-543.
18.	Lu S,Wang X,Lu Q,et al.Stabilization of enzymes in silk films.Biomacromolecules,2009,10(5):1032-1042.
19.	Mortimer D,Feldner J,Vaughan T,et al.Bayesian model predicts the response of axons to molecular gradients.Proc Natl Acad Sci U S A,2009,106(25):10296-10301.
20.	Luo L.Actin cytoskeleton regulation in neuronal morphogenesis and structural plasticity.Annu Rev Cell Dev Biol,2002,18:601-635.
21.	Zheng JQ,Wan JJ,Poo MM.Essential role of filopodia in chemotropic turning of nerve growth cone induced by a glutamate gradient.J Neurosci,1996,16(3):1140-1149.
22.	Leung KM,van Horck FP,Lin AC,et al.Asymmetrical beta-actin mRNA translation in growth cones mediates attractive turning to netrin-1.Nat Neurosci,2006,9(10):1247-1256.
23.	Tang X,Xue C,Wang Y,et al.Bridging peripheral nerve defects with a tissue engineered nerve graft composed of an in vitro cultured nerve equivalent and a silk fibroin-based scaffold.Biomaterials,2012,33(15):3860-3867.

1. 唐圆,刘湘华,刘丹,等.以组织工程建构技术修复周围神经损伤的难点.中国组织工程研究,2013,17(7):1295-1304.
2. 袁逖飞,彭瀚,徐聪,等.轴突生长导向因子简介.临床和实验医学杂志,2006,5(11):1847-1849.
3. Xiong Y,Zhu JX,Fang ZY,et al.Coseeded Schwann cells myelinate neurites from differentiated neural stem cells in neurotrophin-3-loaded PLGA carriers.Int J Nanomedicine,2012,7:1977-1989.
4. 朱继翔,全大萍.PCL-b-PLLA嵌段共聚物纳米纤维结构支架的制备及体外降解.中国科技论文,2012,7(6):447-453.
5. Lu Q,Wang X,Hu X,et al.Stabilization and release of enzymes from silk films.Macromol Biosci,2010,10(4):359-368.
6. Oh SH,Kim JH,Song KS,et al.Peripheral nerve regeneration within an asymmetrically porous PLGA/Pluronic F127 nerve guide conduit.Biomaterials,2008,29(11):1601-1609.
7. Hill PS,Apel PJ,Barnwell J,et al.Repair of peripheral nerve defects in rabbits using keratin hydrogel scaffolds.Tissue Eng Part A,2011,17(11-12):1499-1505.
8. Cao J,Sun C,Zhao H,et al.The use of laminin modified linear ordered collagen scaffolds loaded with laminin-binding ciliary neurotrophic factor for sciatic nerve regeneration in rats.Biomaterials,2011,32(16):3939-3948.
9. Mai J,Fok L,Gao H,et al.Axon initiation and growth cone turning on bound protein gradients.J Neurosci,2009,29(23):7450-7458.
10. Yao L,de Ruiter GC,Wang H,et al.Controlling dispersion of axonal regeneration using a multichannel collagen nerve conduit.Biomaterials,2010,31(22):5789-5797.
11. 饶毅,吴瑛.神经细胞迁移导向的分子机制.生理科学进展,2000,31(3):198-204.
12. Li J,Zhu L,Zhang M,et al.Microfluidic device for studying cell migration in single or co-existing chemical gradients and electric fields.Biomicrofluidics,2012,6(2):24121-2412113.
13. Roam JL,Xu H,Nguyen PK,et al.The formation of protein concentration gradients mediated by density differences of poly (ethylene glycol) microspheres.Biomaterials,2010,31(33):8642-8650.
14. Vetter I,Pujic Z,Goodhill GJ.The response of dorsal root ganglion axons to nerve growth factor gradients depends on spinal level.J Neurotrauma,2010,27(8):1379-1386.
15. Wenk E,Merkle HP,Meinel L.Silk fibroin as a vehicle for drug delivery applications.J Control Release,2011,150(2):128-141.
16. Sheng XY,Fan LP,Mo XM,et al.Electrospun silk fibroin composite nanofibrous mats loaded with vitamin A and E.J Control Release,2013,172(1):e35-e36.
17. 朱超,蒋欣泉,张志愿.丝蛋白作为骨组织工程支架材料的研究进展.国际口腔医学杂志,2010,37(5):541-543.
18. Lu S,Wang X,Lu Q,et al.Stabilization of enzymes in silk films.Biomacromolecules,2009,10(5):1032-1042.
19. Mortimer D,Feldner J,Vaughan T,et al.Bayesian model predicts the response of axons to molecular gradients.Proc Natl Acad Sci U S A,2009,106(25):10296-10301.
20. Luo L.Actin cytoskeleton regulation in neuronal morphogenesis and structural plasticity.Annu Rev Cell Dev Biol,2002,18:601-635.
21. Zheng JQ,Wan JJ,Poo MM.Essential role of filopodia in chemotropic turning of nerve growth cone induced by a glutamate gradient.J Neurosci,1996,16(3):1140-1149.
22. Leung KM,van Horck FP,Lin AC,et al.Asymmetrical beta-actin mRNA translation in growth cones mediates attractive turning to netrin-1.Nat Neurosci,2006,9(10):1247-1256.
23. Tang X,Xue C,Wang Y,et al.Bridging peripheral nerve defects with a tissue engineered nerve graft composed of an in vitro cultured nerve equivalent and a silk fibroin-based scaffold.Biomaterials,2012,33(15):3860-3867.

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EXPERIMENTAL STUDY ON GRADIENT OF NERVE GROWTH FACTOR IMMOBILIZED CONDUITS PROMOTING PERIPHERAL NERVE REGENERATION IN RATS

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