PREPARATION OF SPIDER SILK PROTEIN BILAYER SMALL DIAMETER VASCULAR SCAFFOLD AND BLOOD COMPATIBILITY ANALYSIS IN VITRO_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

ZHAO Liang , XU Yanli , QIU Hui , LI Min , CHEN Yuqing.

College of Life Sciences, Fujian Normal University, Fuzhou Fujian, 350108, P.R.China. Corresponding author: LI Min, E-mail: mli@fjnu.edu.cn;

Corresponding author：

Keywords：

Tissue engineered artery; Spider silk protein; Bilayer small diameter vascular scaffold; Electrosp-inning; Blood compatibility

DOI：

10.7507/1002-1892.20130176

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Objective To prepare a spider silk protein bilayer small diameter vascular scaffold using electrospinning, and to observe the blood compatibility in vitro. Methods The Arg-Gly-Asp-recombinant spider silk protein (pNSR16), polycaprolactone (PCL), gelatin (Gt), and heparin (Hep) were blended. Spider silk protein bilayer small diameter vascular scaffold (experimental group) was prepared by electrospinning, with pNSR16 ∶ PCL ∶ Hep (5 ∶ 85 ∶ 10, W/W) hybrid electrospun solution as inner spinning solution and pNSR16 ∶ PCL ∶ Gt (5 ∶ 85 ∶ 10, W/W) hybrid electrospun solution as outer spinning solution, but pNSR16 ∶ PCL (5 ∶ 85, W/W) hybrid electrospun solution was used as inner spinning solution in control group. The scaffold structure of experimental group was observed under scanning electron microscope (SEM); and the hemolysis rate, recalcification clotting time, dynamic clotting time, platelet adhesion, and platelet activation in vitro were compared between 2 groups. Results SEM results showed that bilayer fibers of scaffold were quite different in experimental group; the diameter distribution of inner layer fibers was relatively uniform with small pores, however diameter difference of the outer layer fiber was relatively big with big pores. The contact angle, hemolysis rate, recalcification clotting time, and P-selectin expression of scaffold were (35 ± 3) ° , 1.2% ± 0.1%, (340 ± 11) s, and 0.412 ± 0.027 respectively in experimental group, and were (70 ± 4) ° , 1.9% ± 0.1%, (260 ± 16) s, and 0.678 ± 0.031 respectively in control group; significant difference were found in indexes between 2 groups (P lt; 0.05). With the extension of time, the curve of coagulation time in experimental group sloped downward slowly and had a long time; the blood clotting index values before 30 minutes were significantly higher than those in control group (P lt; 0.05). Platelet adhesion test showed that the scaffold surface almost had no platelet adhesion in experimental group. Conclusion The spider silk protein bilayer small diameter vascular scaffold could be prepared through electrospinning, and it has good blood compatibility in vitro.

Citation： ZHAO Liang,XU Yanli,QIU Hui,LI Min,CHEN Yuqing.. PREPARATION OF SPIDER SILK PROTEIN BILAYER SMALL DIAMETER VASCULAR SCAFFOLD AND BLOOD COMPATIBILITY ANALYSIS IN VITRO. Chinese Journal of Reparative and Reconstructive Surgery, 2013, 27(7): 800-804. doi: 10.7507/1002-1892.20130176 Copy

1.	Patterson JT, Gilliland T, Maxfield MW, et al. Tissue-engineered vascular grafts for use in the treatment of congenital heart disease: from the bench to the clinic and back again. Regen Med, 2012, 7(3): 409-419.
2.	Hong Y, Ye SH, Nieponice A. A small diameter, fibrous vascular conduit generated from a poly (ester urethane) urea and phospholipid polymer blend. Biomaterials, 2009, 30(13): 2457-2467.
3.	Phipps MC, Clem WC, Grunda JM, et al. Increasing the pore sizes of bone-mimetic electrospun scaffolds comprised of polycaprolactone, collagen I and hydroxyapatite to enhance cell infiltration. Biomaterials, 2012, 33(2): 524-534.
4.	虞希高, 陈正坚, 蒋宏亮, 等. 静电纺丝小直径人造血管机械力学性质. 中国生物医学工程学报, 2010, 29(5): 770-776.
5.	Osnat H, David PK, Fritz V, et al. Spider and mulberry silkworm silks as compatible biomaterials. Composites Part B: Engineering, 2007, 38(3): 324-337.
6.	Neppalli R, Marega, Marigo A, et al. Poly (epsilon-caprolactone) filled with electrospun nylon fibres: a model for a facile composite fabrication. Eur Polym J, 2010, 46(5): 968-976.
7.	Kanda N, Morimoto N, Ayvazyan AA, et al. Evaluation of a novel collagen-gelatin scaffold for achieving the sustained release of basic fibroblast growth factor in a diabetic mouse model. J Tissue Eng Regen Med, 2012. [Epub ahead of print].
8.	Liu Y, Chen JR, Yang Y, et al. Improved blood compatibility of poly (ethylene terephthalate) films modified with L-arginine. J Biomater Sci Polym Ed, 2008, 19(4): 497-507.
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10.	Xiang P, Li M, Zhang CY, et al. Cytocompatibility of electrospun nanofiber tubuLar scaffolds for small diameter tissue engineering blood vessels. Int J Biological Macromol, 2011, 49(3): 281-288.
11.	黄莹莹, 齐民, 杨大智, 等. 冠脉支架表面 PLGA 涂层制备及其血液相容性研究. 功能材料, 2006, 37(3): 411-414.
12.	Li ZF, Ruckenstein E. Grafting of poly (ethylene oxide) to the surface of polyaniline films through a chlorosulfonation method and the biocompatibility of the modified films. J Colloid Interface Sci, 2004, 269(1): 62-71.
13.	Wang HY, Feng YK, Zhao H, et al. Electrospun hemocompatible PU/Gelatin-Heparin nanofibrous bilayer scaffolds as potential artificial blood vessels. Macromolecular Research, 2012, 20(4): 347-350.
14.	Kong X, Han B, Li H, et al. New biodegradable small-diameter artificial vascular prosthesis: A feasibility study. J Biomed Mater Res A, 2012, 100(6): 1494-1504.
15.	Ayoub NA, Garb JE, Kuelbs A, et al. Ancient properties of spider silks revealed by the complete gene sequence of the prey-wrapping silk protein (AcSp1). Mol Biol Evol, 2013, 30(3): 589-601.
16.	Ruckh TT, Carroll DA, Weaver JR, et al. Mineralization content alters osteogenic responses of bone marrow stromal cells on hydroxyapatite/polycaprolactone composite nanofiber scaffolds. J Funct Biomater, 2012, 3(4): 776-798.
17.	Pok S, Myers JD, Madihally SV, et al. A multilayered scaffold of a chitosan and gelatin hydrogel supported by a PCL core for cardiac tissue engineering. Acta Biomater, 2013, 9(3): 5630-5642.
18.	Harris NC, Davydova N, Roufail S, et al. The propeptides of VEGF-D determine heparin binding, receptor heterodimerization and effects on tumor biology. J Biol Chem, 2013, 288(12): 8176-8186.
19.	Zhang H, Jia XL, Han F, et al. Dual-delivery of VEGF and PDGF by double-layered electrospunmembranes for blood vessel regeneration. Biomaterials, 2013, 34(9): 2202-2212.
20.	Nowak E, Combes G, Stitt EH, et al. A comparison of contact angle measurement techniques applied to highly porous catalyst supports. Powder Technology, 2013, 233: 52-64.
21.	陈佳龙, 李全利, 陈俊英, 等. 利用胶原-肝素自组装多层膜改善纯钛表面血液相容性的研究. 功能材料, 2008, 39(8): 1363-1366.
22.	Huang B, Chen YT, Tong FY, et al. Modification of hydrophilic property of polypropylene fiber film with water-soluble chitosan for improvement of blood compatibility. Advanced Science Letters, 2012, 7: 16-20.
23.	Huang ZW, Ding TT, Sun J. Study of effect on cell proliferation and hemolysis of HAP and TCP nanometer particles. Advanced Materials Research, 2011, 378-379: 711-714.
24.	国家质量监督检验检疫总局. GB/T 16886.4-2003/ISO 10993-4: 2002, 医疗器械生物学评价第4部分: 与血液相互作用试验选择. 北京: 中国标准出版社, 2003.
25.	周素琼, 李国明. 聚氨酯/硫酸酯化壳聚糖复合膜的制备及其血液相容性的研究. 化工时刊, 2007, 21(5): 1-4.
26.	Wang ZX, Sun B, Zhang M, et al. Functionalization of electrospun poly (ε-caprolactone) scaffold with heparin and vascular endothelial growth factors for potential application as vascular grafts. J Bioactive Compatible Polymer, 2013, 28(2): 154-166.
27.	Tan J, McClung WG, Brash JL. Non-fouling biomaterials based on blends of polyethylene oxide copolymers and polyurethane: simultaneous measurement of platelet adhesion and fibrinogen adsorption from flowing whole blood. J Biomater Sci Polym Ed, 2013, 24(4): 497-506.

1. Patterson JT, Gilliland T, Maxfield MW, et al. Tissue-engineered vascular grafts for use in the treatment of congenital heart disease: from the bench to the clinic and back again. Regen Med, 2012, 7(3): 409-419.
2. Hong Y, Ye SH, Nieponice A. A small diameter, fibrous vascular conduit generated from a poly (ester urethane) urea and phospholipid polymer blend. Biomaterials, 2009, 30(13): 2457-2467.
3. Phipps MC, Clem WC, Grunda JM, et al. Increasing the pore sizes of bone-mimetic electrospun scaffolds comprised of polycaprolactone, collagen I and hydroxyapatite to enhance cell infiltration. Biomaterials, 2012, 33(2): 524-534.
4. 虞希高, 陈正坚, 蒋宏亮, 等. 静电纺丝小直径人造血管机械力学性质. 中国生物医学工程学报, 2010, 29(5): 770-776.
5. Osnat H, David PK, Fritz V, et al. Spider and mulberry silkworm silks as compatible biomaterials. Composites Part B: Engineering, 2007, 38(3): 324-337.
6. Neppalli R, Marega, Marigo A, et al. Poly (epsilon-caprolactone) filled with electrospun nylon fibres: a model for a facile composite fabrication. Eur Polym J, 2010, 46(5): 968-976.
7. Kanda N, Morimoto N, Ayvazyan AA, et al. Evaluation of a novel collagen-gelatin scaffold for achieving the sustained release of basic fibroblast growth factor in a diabetic mouse model. J Tissue Eng Regen Med, 2012. [Epub ahead of print].
8. Liu Y, Chen JR, Yang Y, et al. Improved blood compatibility of poly (ethylene terephthalate) films modified with L-arginine. J Biomater Sci Polym Ed, 2008, 19(4): 497-507.
9. 李敏, 陈登龙, 吴钦缘. 静电纺丝仪: 中国, 100457985[P]. 2007-02-07.
10. Xiang P, Li M, Zhang CY, et al. Cytocompatibility of electrospun nanofiber tubuLar scaffolds for small diameter tissue engineering blood vessels. Int J Biological Macromol, 2011, 49(3): 281-288.
11. 黄莹莹, 齐民, 杨大智, 等. 冠脉支架表面 PLGA 涂层制备及其血液相容性研究. 功能材料, 2006, 37(3): 411-414.
12. Li ZF, Ruckenstein E. Grafting of poly (ethylene oxide) to the surface of polyaniline films through a chlorosulfonation method and the biocompatibility of the modified films. J Colloid Interface Sci, 2004, 269(1): 62-71.
13. Wang HY, Feng YK, Zhao H, et al. Electrospun hemocompatible PU/Gelatin-Heparin nanofibrous bilayer scaffolds as potential artificial blood vessels. Macromolecular Research, 2012, 20(4): 347-350.
14. Kong X, Han B, Li H, et al. New biodegradable small-diameter artificial vascular prosthesis: A feasibility study. J Biomed Mater Res A, 2012, 100(6): 1494-1504.
15. Ayoub NA, Garb JE, Kuelbs A, et al. Ancient properties of spider silks revealed by the complete gene sequence of the prey-wrapping silk protein (AcSp1). Mol Biol Evol, 2013, 30(3): 589-601.
16. Ruckh TT, Carroll DA, Weaver JR, et al. Mineralization content alters osteogenic responses of bone marrow stromal cells on hydroxyapatite/polycaprolactone composite nanofiber scaffolds. J Funct Biomater, 2012, 3(4): 776-798.
17. Pok S, Myers JD, Madihally SV, et al. A multilayered scaffold of a chitosan and gelatin hydrogel supported by a PCL core for cardiac tissue engineering. Acta Biomater, 2013, 9(3): 5630-5642.
18. Harris NC, Davydova N, Roufail S, et al. The propeptides of VEGF-D determine heparin binding, receptor heterodimerization and effects on tumor biology. J Biol Chem, 2013, 288(12): 8176-8186.
19. Zhang H, Jia XL, Han F, et al. Dual-delivery of VEGF and PDGF by double-layered electrospunmembranes for blood vessel regeneration. Biomaterials, 2013, 34(9): 2202-2212.
20. Nowak E, Combes G, Stitt EH, et al. A comparison of contact angle measurement techniques applied to highly porous catalyst supports. Powder Technology, 2013, 233: 52-64.
21. 陈佳龙, 李全利, 陈俊英, 等. 利用胶原-肝素自组装多层膜改善纯钛表面血液相容性的研究. 功能材料, 2008, 39(8): 1363-1366.
22. Huang B, Chen YT, Tong FY, et al. Modification of hydrophilic property of polypropylene fiber film with water-soluble chitosan for improvement of blood compatibility. Advanced Science Letters, 2012, 7: 16-20.
23. Huang ZW, Ding TT, Sun J. Study of effect on cell proliferation and hemolysis of HAP and TCP nanometer particles. Advanced Materials Research, 2011, 378-379: 711-714.
24. 国家质量监督检验检疫总局. GB/T 16886.4-2003/ISO 10993-4: 2002, 医疗器械生物学评价第4部分: 与血液相互作用试验选择. 北京: 中国标准出版社, 2003.
25. 周素琼, 李国明. 聚氨酯/硫酸酯化壳聚糖复合膜的制备及其血液相容性的研究. 化工时刊, 2007, 21(5): 1-4.
26. Wang ZX, Sun B, Zhang M, et al. Functionalization of electrospun poly (ε-caprolactone) scaffold with heparin and vascular endothelial growth factors for potential application as vascular grafts. J Bioactive Compatible Polymer, 2013, 28(2): 154-166.
27. Tan J, McClung WG, Brash JL. Non-fouling biomaterials based on blends of polyethylene oxide copolymers and polyurethane: simultaneous measurement of platelet adhesion and fibrinogen adsorption from flowing whole blood. J Biomater Sci Polym Ed, 2013, 24(4): 497-506.

Chinese Journal of Reparative and Reconstructive Surgery

PREPARATION OF SPIDER SILK PROTEIN BILAYER SMALL DIAMETER VASCULAR SCAFFOLD AND BLOOD COMPATIBILITY ANALYSIS IN VITRO

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