Construction and biocompatibility <i>in vitro</i> evaluation of electrospun-graphene/silk fibroin nanofilms _Chinese Journal of Reparative and Reconstructive Surgery

Authors：

ZHAO Yahong ^1,2 , NIU Changmei ³ , GONG Jiahuan ² , WANG Hongbo ¹ ,  YANG Yumin ^1,2

1. College of Textile and Clothing, Jiangnan University, Wuxi Jiangsu, 214122, P.R.China;
2. Key Laboratory of Neuro-regeneration of Jiangsu Province, Nantong University, Nantong Jiangsu, 226001, P.R.China;
3. Medical School, Nantong University, Nantong Jiangsu, 226001, P.R.China;

Corresponding author：

YANG Yumin, Email: yangym@ntu.edu.cn

Keywords：

Electrospinning; graphene; silk fibroin; nanofilm; electrical conductivity; Schwann cells

DOI：

10.7507/1002-1892.201703046

Video：

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Objective To explore the construction and biocompatibility in vitro evaluation of the electrospun-graphene (Gr)/silk fibroin (SF) nanofilms. Methods The electrostatic spinning solution was prepared by dissolving SF and different mass ratio (0, 5%, 10%, 15%, and 20%) of Gr in formic acid solution. The hydrophilia and hydrophobic was analyzed by testing the static contact angle of electrostatic spinning solution of different mass ratio of Gr. Gr-SF nanofilms with different mass ratio (0, 5%, 10%, 15%, and 20%, as groups A, B, C, D, and E, respectively) were constructed by electrospinning technology. The structure of nanofilms were observed by optical microscope and scanning electron microscope; electrochemical performance of nanofilms were detected by cyclic voltammetry at electrochemical workstation; the porosity of nanofilms were measured by n-hexane substitution method, and the permeability were observed; L929 cells were used to evaluate the cytotoxicity of nanofilms in vitro at 1, 4, and 7 days after culture. The primary Sprague Dawley rats’ Schwann cells were co-cultured with different Gr-SF nanofilms of 5 groups for 3 days, the morphology and distribution of Schwann cells were identified by toluidine blue staining, the cell adhesion of Schwann cells were determined by cell counting kit 8 (CCK-8) method, the proliferation of Schwann cells were detected by EdU/Hoechst33342 staining. Results The static contact angle measurement confirmed that the hydrophilia of Gr-SF electrospinning solution was decreased by increasing the mass ratio of Gr. Light microscope and scanning electron microscopy showed that Gr-SF nanofilms had nanofiber structure, Gr particles could be dispersed uniformly in the membrane, and the increasing of mass ratio of Gr could lead to the aggregation of particles. The porosity measurement showed that the Gr-SF nanofilms had high porosity (>65%). With the increasing of mass ratio of Gr, the porosity and conductivity of Gr-SF nanofilm increased gradually, the value in the group A was significantly lower than those in groups C, D, and E (P<0.05). In vitro L929 cells cytotoxicity test showed that all the Gr-SF nanofilms had good biocompatibility. Toluidine blue staining, CCK-8 assay, and EdU/Hoechst33342 staining showed that Gr-SF nanofilms with mass ratio of Gr less than 10% could support the survival and proliferation of co-cultured Schwann cells. Conclusion The Gr-SF nanofilm with mass ratio of Gr less than 10% have proper hydrophilia, conductivity, porosity, and other physical and chemical properties, and have good biocompatibility in vitro. They can be used in tissue engineered nerve preparation.

Citation： ZHAO Yahong, NIU Changmei, GONG Jiahuan, WANG Hongbo, YANG Yumin. Construction and biocompatibility in vitro evaluation of electrospun-graphene/silk fibroin nanofilms . Chinese Journal of Reparative and Reconstructive Surgery, 2017, 31(9): 1119-1126. doi: 10.7507/1002-1892.201703046 Copy

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23.	Weinstein DE, Wu R. Isolation and purification of primary Schwann cells. Curr Protoc Neurosci, 2001, Chapter 3: Unit 3.17.
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25.	Shao W, Wang S, Liu H, et al. Preparation of bacterial cellulose/graphene nanosheets composite films with enhanced mechanical performances. Carbohydr Polym, 2016, 138: 166-171.
26.	Kasoju N, Bora U. Silk fibroin in tissue engineering. Adv Healthc Mater, 2012, 1(4): 393-412.
27.	Siemionow M, Uygur S, Ozturk C, et al. Techniques and materials for enhancement of peripheral nerve regeneration: a literature review. Microsurgery, 2013, 33(4): 318-328.
28.	Li C, Adamcik J, Mezzenga R. Biodegradable nanocomposites of amyloid fibrils and graphene with shape-memory and enzyme-sensing properties. Nat Nanotechnol, 2012, 7(7): 421-427.
29.	Oh SH, Park IK, Kim JM, et al. In vitro and in vivo characteristics of PCL scaffolds with pore size gradient fabricated by a centrifugation method. Biomaterials, 2007, 28(9): 1664-1671.
30.	Chan BP, Leong KW. Scaffolding in tissue engineering: general approaches and tissue-specific considerations. Eur Spine J, 2008, 17 Suppl 4: 467-479.
31.	Zhang Y, Ali SF, Dervishi E, et al. Cytotoxicity effects of graphene and single-wall carbon nanotubes in neural phaeochromocytoma-derived PC12 cells. ACS Nano, 2010, 4(6): 3181-3186.

1. 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.
2. Hvistendahl M. China’s push in tissue engineering. Science, 2012, 338(6109): 900-902.
3. Ray WZ, Mahan MA, Guo D, et al. An update on addressing important peripheral nerve problems: challenges and potential solutions. Acta Neurochir (Wien), 2017. [Epub ahead of print].
4. Fan W, Gu J, Hu W, et al. Repairing a 35-mm-long median nerve defect with a chitosan/PGA artificial nerve graft in the human: a case study. Microsurgery, 2008, 28(4): 238-242.
5. Meyer C, Stenberg L, Gonzalez-Perez F, et al. Chitosan-film enhanced chitosan nerve guides for long-distance regeneration of peripheral nerves. Biomaterials, 2016, 76: 33-51.
6. Arslantunali D, Dursun T, Yucel D, et al. Peripheral nerve conduits: technology update. Med Devices (Auckl), 2014, 7: 405-424.
7. Gu X, Ding F, Williams DF. Neural tissue engineering options for peripheral nerve regeneration. Biomaterials, 2014, 35(24): 6143-6156.
8. Muheremu A, Ao Q. Past, Present, and Future of Nerve Conduits in the Treatment of Peripheral Nerve Injury. Biomed Res Int, 2015, 2015: 237507.
9. Willand MP. Electrical Stimulation Enhances Reinnervation After Nerve Injury. Eur J Transl Myol, 2015, 25(4): 243-248.
10. Gopinathan J, Quigley AF, Bhattacharyya A, et al. Preparation, characterisation, and in vitro evaluation of electrically conducting poly (varepsilon-caprolactone)-based nanocomposite scaffolds using PC12 cells. J Biomed Mater Res A, 2016, 104(4): 853-865.
11. Hess LH, Jansen M, Maybeck V, et al. Graphene transistor arrays for recording action potentials from electrogenic cells. Adv Mater, 2011, 23(43): 5045-5049.
12. Kostarelos K, Novoselov KS. Graphene devices for life. Nat Nanotechnol, 2014, 9(10): 744-745.
13. Zhang Y, Ali SF, Dervishi E, et al. Cytotoxicity effects of graphene and single-wall carbon nanotubes in neural phaeochromocytoma-derived PC12 cells. ACS Nano, 2010, 4(6): 3181-3186.
14. Chen CH, Lin CT, Hsu WL, et al. A flexible hydrophilic-modified graphene microprobe for neural and cardiac recording. Nanomed-Nanotechnol, 2013, 9(5): 600-604.
15. Li G, Kong Y, Zhao Y, et al. Fabrication and characterization of polyacrylamide/silk fibroin hydrogels for peripheral nerve regeneration. J Biomater Sci Polym Ed, 2015, 26(14): 899-916.
16. Zhu B, Wang H, Leow WR, et al. Silk Fibroin for Flexible Electronic Devices. Adv Mater, 2016, 28(22): 4250-4265.
17. Zhao Y, Zhao W, Yu S, et al. Biocompatibility evaluation of electrospun silk fibroin nanofibrous mats with primarily cultured rat hippocampal neurons. Biomed Mater Eng, 2013, 23(6): 545-554.
18. Dinis TM, Elia R, Vidal G, et al. Method to form a fiber/growth factor dual-gradient along electrospun silk for nerve regeneration. ACS Appl Mater Interfaces, 2014, 6(19): 16817-16826.
19. Mu Y, Wu F, Lu YR, et al. Progress of electrospun fibers as nerve conduits for neural tissue repair. Nanomedicine-Uk, 2014, 9(12): 1869-1883.
20. Yang Y, Ding F, Wu J, et al. Development and evaluation of silk fibroin-based nerve grafts used for peripheral nerve regeneration. Biomaterials, 2007, 28(36): 5526-5535.
21. Bal DK, Patra S, Ganguly S, et al. Drying characteristics and evolution of the pore space in alginate scaffold with embedded sub-millimeter voids. J Sol-Gel Sci Technol, 2013, 68(2): 254-260.
22. Pillai MM, Gopinathan J, Indumathi B, et al. Silk-PVA Hybrid Nanofibrous Scaffolds for Enhanced Primary Human Meniscal Cell Proliferation. J Membr Biol, 2016, 249(6): 813-822.
23. Weinstein DE, Wu R. Isolation and purification of primary Schwann cells. Curr Protoc Neurosci, 2001, Chapter 3: Unit 3.17.
24. Fan Z, Wang J, Liu F, et al. A new composite scaffold of bioactive glass nanoparticles/graphene: Synchronous improvements of cytocompatibility and mechanical property. Colloids Surf B Biointerfaces, 2016, 145: 438-446.
25. Shao W, Wang S, Liu H, et al. Preparation of bacterial cellulose/graphene nanosheets composite films with enhanced mechanical performances. Carbohydr Polym, 2016, 138: 166-171.
26. Kasoju N, Bora U. Silk fibroin in tissue engineering. Adv Healthc Mater, 2012, 1(4): 393-412.
27. Siemionow M, Uygur S, Ozturk C, et al. Techniques and materials for enhancement of peripheral nerve regeneration: a literature review. Microsurgery, 2013, 33(4): 318-328.
28. Li C, Adamcik J, Mezzenga R. Biodegradable nanocomposites of amyloid fibrils and graphene with shape-memory and enzyme-sensing properties. Nat Nanotechnol, 2012, 7(7): 421-427.
29. Oh SH, Park IK, Kim JM, et al. In vitro and in vivo characteristics of PCL scaffolds with pore size gradient fabricated by a centrifugation method. Biomaterials, 2007, 28(9): 1664-1671.
30. Chan BP, Leong KW. Scaffolding in tissue engineering: general approaches and tissue-specific considerations. Eur Spine J, 2008, 17 Suppl 4: 467-479.
31. Zhang Y, Ali SF, Dervishi E, et al. Cytotoxicity effects of graphene and single-wall carbon nanotubes in neural phaeochromocytoma-derived PC12 cells. ACS Nano, 2010, 4(6): 3181-3186.

Chinese Journal of Reparative and Reconstructive Surgery

Construction and biocompatibility in vitro evaluation of electrospun-graphene/silk fibroin nanofilms

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