A green route for the fabrication of thermo-sensitive chitosan nerve conduits and their property evaluation_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

WEI Changzheng , YANG Xiaoyuan ,  WANG Xiaotong

Shanghai Qisheng Biological Preparation Co., Ltd, Shanghai, 201106, P.R.China;

Corresponding?author：

WANG Xiaotong, Email: wangxt123@3healthcare.com

Keywords：

Nerve tissue engineering; nerve conduit; thermo-sensitive chitosan; green route

DOI：

10.7507/1002-1892.201904009

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

Objective To explore a green route for the fabrication of thermo-sensitive chitosan nerve conduits, improve the mechanical properties and decrease the degradation rate of the chitosan nerve conduits. Methods Taking advantage of the ionic specific effect of the thermo-sensitive chitosan, the strengthened chitosan nerve conduits were obtained by immersing the gel-casted conduits in salt solution for ion-induced phase transition, and rinsing, lyophilization, and ⁶⁰Co sterilization afterwards. The nerve conduits after immersing in NaCl solutions for 0, 4, 12, 24, 36, 48, and 72 hours were obtained and characterized the general observation, diameters and mechanical properties. According to the above results, the optimal sample was chosen and characterized the microstructure, degradation properties, and cytocompatibility. The left sciatic nerve defect 15 mm in length was made in 20 male Sprague Dawley rats. The autologous nerves (control group, n=10) and the nerve conduits (experimental group, n=10) were used to repair the defects. At 8 weeks after operation, the compound muscle action potential (CMAP) was measured. The regenerated nerves were investigated by gross observation and toluidine blue staining. The gastrocnemius muscle was observed by HE staining. Results With the increased ionic phase transition time, the color of the conduit was gradually deepened and the diameter was gradually decreased, which showed no difference during 12 hours. The tensile strength of the nerve conduit was increased gradually. The ultimate tensile strength showed significant difference between the 48 hours and 12, 24, and 36 hours groups (P<0.05), and no significant difference between the 48 hours and 72 hours groups (P>0.05). As a result, the nerve conduit after ion-induced phase transition for 48 hours was chosen for further study. The scanning electron microscope (SEM) images showed that the nerve conduit had a uniform porous structure. The degradation rate of the the nerve conduit after ion-induced phase transition for 48 hours was significantly decreased as compared with that of the conduit without ion-induced phase transition. The nerve conduit could support the attachment and proliferation of rat Schwann cells on the inner surface. The animal experiments showed that at 8 weeks after operation, the CMAPs of the experimental and control groups were (3.5±0.9) and (4.3±1.1) m/V, respectively, which showed no significant difference between the two groups (P<0.05), and were significantly lower than that of the contralateral site ［(45.6±5.6 m/V), P>0.05］. The nerve conduit of the experimental group could repair the nerve defect. There was no significant difference between the experimental and control groups in terms of the histomorphology of the regenerated nerve fibers and the gastrocnemius muscle. Conclusion The green route for the fabrication of thermo-sensitive chitosan nerve conduits is free of any toxic reagents, and has simple steps, which is beneficial to the industrial transformation of the chitosan nerve conduit products. The prepared chitosan nerve conduit can be applied to rat peripheral nerve defect repair and nerve tissue engineering.

Citation： WEI Changzheng, YANG Xiaoyuan, WANG Xiaotong. A green route for the fabrication of thermo-sensitive chitosan nerve conduits and their property evaluation. Chinese Journal of Reparative and Reconstructive Surgery, 2019, 33(11): 1439-1445. doi: 10.7507/1002-1892.201904009 Copy

1.	Houshyar S, Bhattacharyya A, Shanks R. Peripheral nerve conduit: materials and structures. ACS Chem Neurosci, 2019, 10(8): 3349-3365.
2.	陳勇, 范林, 付貞, 等. 神經導管支架修復外周神經損傷的研究與現狀. 中國組織工程研究, 2017, 21(30): 4901-4907.
3.	儲成艷, 朱亮, 王蘇平, 等. 膠原凝膠構建神經組織工程支架的實驗研究. 中國修復重建外科雜志, 2017, 31(3): 363-368.
4.	陳曦, 范永恒, 肖志峰, 等. 膠原支架結合腦源性神經營養因子移植促進全橫斷脊髓損傷大鼠軸突再生及運動功能恢復的研究. 中國修復重建外科雜志, 2018, 32(6): 650-659.
5.	Reddy N, Reddy R, Jiang Q. Crosslinking biopolymers for biomedical applications. Trends Biotechnol, 2015, 33(6): 362-369.
6.	Wang H, Heilshorn SC. Adaptable hydrogel networks with reversible linkages for tissue engineering. Adv Mater, 2015, 27(25): 3717-3736.
7.	Hu S, Bi S, Yan D, et al. Preparation of composite hydroxybutyl chitosan sponge and its role in promoting wound healing. Carbohydr Polym, 2018, 184: 154-163.
8.	Bao Z, Jiang C, Wang Z, et al. The influence of solvent formulations on thermosensitive hydroxybutyl chitosan hydrogel as a potential delivery matrix for cell therapy. Carbohydr Polym, 2017, 170: 80-88.
9.	Wang X, Wei C, Cao B, et al. Fabrication of multiple-layered hydrogel scaffolds with elaborate structure and good mechanical properties via 3D printing and ionic reinforcement. ACS Appl Mater Interfaces, 2018, 10(21): 18338-18350.
10.	Huang W, Xu H, Xue Y, et al. Layer-by-layer immobilization of lysozyme-chitosan-organic rectorite composites on electrospun nanofibrous mats for pork preservation. Food Res Int, 2012, 48(2): 784-791.
11.	Sahariah P, Másson M. Antimicrobial chitosan and chitosan derivatives: A review of the structure-activity relationship. Biomacromolecules, 2017, 18(11): 3846-3868.
12.	Mohebbi S, Nezhad MN, Zarrintaj P, et al. Chitosan in biomedical engineering: A critical review. Curr Stem Cell Res Ther, 2019, 14(2): 93-116.
13.	Neubrech F, Sauerbier M, Moll W, et al. Enhancing the outcome of traumatic sensory nerve lesions of the hand by additional use of a chitosan nerve tube in Primary Nerve Repair. Plast Reconstr Surg, 2018, 142(2): 415-424.
14.	Muheremu A, Chen L, Wang X, et al. Chitosan nerve conduits seeded with autologous bone marrow mononuclear cells for 30 mm goat peroneal nerve defect. Sci Rep, 2017, 7: 44002.
15.	Dietzmeyer N, F?rthmann M, Leonhard J, et al. Two-chambered chitosan nerve guides with increased bendability support recovery of skilled forelimb reaching similar to autologous nerve grafts in the rat 10 mm median nerve injury and repair model. Front Cell Neurosci, 2019, 13: 149.
16.	姬琳琳, 魏在榮. 殼聚糖神經導管聯合施萬細胞橋接修復周圍神經缺損新進展. 中國臨床解剖學雜志, 2018, 36(5): 593-595.
17.	Jiao J, Huang J, Zhang Z. Hydrogels based on chitosan in tissue regeneration: How do they work? A mini review J Appl Polym Sci, 2019, 136(13): 47235.
18.	陸江, 陳絢麗, 唐核心, 等. 新型組織工程化改性膠原-殼聚糖復合支架制備與神經細胞的相容性. 中國組織工程研究, 2017, 21(18): 2913-2919.
19.	Baniasadi H, Ramazani SAA, Mashayekhan S. Fabrication and characterization of conductive chitosan/gelatin-based scaffolds for nerve tissue engineering. Int J Biol Macromol, 2015, 74: 360-366.
20.	劉奔, 張彩順, 高緒斌, 等. 聚己內酯/殼聚糖神經導管復合骨髓間充質干細胞促進大鼠坐骨神經損傷修復的研究. 中國生物工程雜志, 2014, 34(2): 34-38.
21.	Oh SH, Kang JG, Kim TH, et al. Enhanced peripheral nerve regeneration through asymmetrically porous nerve guide conduit with nerve growth factor gradient. J Biomed Mater Res A, 2018, 106(1): 52-64.
22.	Sekar M, Roopmani P, Krishnan U. Development of a novel porous polyvinyl formal (PVF) microfibrous scaffold for nerve tissue engineering. Polymer, 2018, 142: 170-182.

1. Houshyar S, Bhattacharyya A, Shanks R. Peripheral nerve conduit: materials and structures. ACS Chem Neurosci, 2019, 10(8): 3349-3365.
2. 陳勇, 范林, 付貞, 等. 神經導管支架修復外周神經損傷的研究與現狀. 中國組織工程研究, 2017, 21(30): 4901-4907.
3. 儲成艷, 朱亮, 王蘇平, 等. 膠原凝膠構建神經組織工程支架的實驗研究. 中國修復重建外科雜志, 2017, 31(3): 363-368.
4. 陳曦, 范永恒, 肖志峰, 等. 膠原支架結合腦源性神經營養因子移植促進全橫斷脊髓損傷大鼠軸突再生及運動功能恢復的研究. 中國修復重建外科雜志, 2018, 32(6): 650-659.
5. Reddy N, Reddy R, Jiang Q. Crosslinking biopolymers for biomedical applications. Trends Biotechnol, 2015, 33(6): 362-369.
6. Wang H, Heilshorn SC. Adaptable hydrogel networks with reversible linkages for tissue engineering. Adv Mater, 2015, 27(25): 3717-3736.
7. Hu S, Bi S, Yan D, et al. Preparation of composite hydroxybutyl chitosan sponge and its role in promoting wound healing. Carbohydr Polym, 2018, 184: 154-163.
8. Bao Z, Jiang C, Wang Z, et al. The influence of solvent formulations on thermosensitive hydroxybutyl chitosan hydrogel as a potential delivery matrix for cell therapy. Carbohydr Polym, 2017, 170: 80-88.
9. Wang X, Wei C, Cao B, et al. Fabrication of multiple-layered hydrogel scaffolds with elaborate structure and good mechanical properties via 3D printing and ionic reinforcement. ACS Appl Mater Interfaces, 2018, 10(21): 18338-18350.
10. Huang W, Xu H, Xue Y, et al. Layer-by-layer immobilization of lysozyme-chitosan-organic rectorite composites on electrospun nanofibrous mats for pork preservation. Food Res Int, 2012, 48(2): 784-791.
11. Sahariah P, Másson M. Antimicrobial chitosan and chitosan derivatives: A review of the structure-activity relationship. Biomacromolecules, 2017, 18(11): 3846-3868.
12. Mohebbi S, Nezhad MN, Zarrintaj P, et al. Chitosan in biomedical engineering: A critical review. Curr Stem Cell Res Ther, 2019, 14(2): 93-116.
13. Neubrech F, Sauerbier M, Moll W, et al. Enhancing the outcome of traumatic sensory nerve lesions of the hand by additional use of a chitosan nerve tube in Primary Nerve Repair. Plast Reconstr Surg, 2018, 142(2): 415-424.
14. Muheremu A, Chen L, Wang X, et al. Chitosan nerve conduits seeded with autologous bone marrow mononuclear cells for 30 mm goat peroneal nerve defect. Sci Rep, 2017, 7: 44002.
15. Dietzmeyer N, F?rthmann M, Leonhard J, et al. Two-chambered chitosan nerve guides with increased bendability support recovery of skilled forelimb reaching similar to autologous nerve grafts in the rat 10 mm median nerve injury and repair model. Front Cell Neurosci, 2019, 13: 149.
16. 姬琳琳, 魏在榮. 殼聚糖神經導管聯合施萬細胞橋接修復周圍神經缺損新進展. 中國臨床解剖學雜志, 2018, 36(5): 593-595.
17. Jiao J, Huang J, Zhang Z. Hydrogels based on chitosan in tissue regeneration: How do they work? A mini review J Appl Polym Sci, 2019, 136(13): 47235.
18. 陸江, 陳絢麗, 唐核心, 等. 新型組織工程化改性膠原-殼聚糖復合支架制備與神經細胞的相容性. 中國組織工程研究, 2017, 21(18): 2913-2919.
19. Baniasadi H, Ramazani SAA, Mashayekhan S. Fabrication and characterization of conductive chitosan/gelatin-based scaffolds for nerve tissue engineering. Int J Biol Macromol, 2015, 74: 360-366.
20. 劉奔, 張彩順, 高緒斌, 等. 聚己內酯/殼聚糖神經導管復合骨髓間充質干細胞促進大鼠坐骨神經損傷修復的研究. 中國生物工程雜志, 2014, 34(2): 34-38.
21. Oh SH, Kang JG, Kim TH, et al. Enhanced peripheral nerve regeneration through asymmetrically porous nerve guide conduit with nerve growth factor gradient. J Biomed Mater Res A, 2018, 106(1): 52-64.
22. Sekar M, Roopmani P, Krishnan U. Development of a novel porous polyvinyl formal (PVF) microfibrous scaffold for nerve tissue engineering. Polymer, 2018, 142: 170-182.

Chinese Journal of Reparative and Reconstructive Surgery

A green route for the fabrication of thermo-sensitive chitosan nerve conduits and their property evaluation

Abstract Full text Figures/Tables Video References Cited by

Previous Article

Next Article

Format

Content