Sage Journals: Discover world-class research

Abstract

With electrospinning technology, recombinant spider silk protein/PCL blend submicrofibrous mat was prepared. Its properties as a potential wound dressing material were evaluated by Scanning Electron Microscopy (SEM) and Fourier Transform Infrared Spectroscopy (FTIR). When the proportion of recombinant spider silk protein/polycaprolactone (PCL) reached 1:20, the appropriate concentration of spinning solution was 30%. Also, the fibre diameter increased as the nozzle-to-ground distance decreased, or as the extrusion speed increased. The fibres tended to be non-uniform. As shown by FTIR, PCL and recombinant spider silk protein blended together without obvious molecular interaction. MTT assay analysis showed that, compared with PCL scaffold, the toxic level of pNSR16/PCL composite scaffold was below 1, which meets the criteria for biomaterials. NIH-3T3 cells cultivation on the composite scaffolds indicated that pNSR16/PCL composite scaffolds with RGD had better cell adhesion than PCL scaffolds. Immunohistochemical experiments proved that cells on the pNSR16/PCL composite scaffold materials had no effect on normal growth. pNSR16/PCL composite scaffold guaranteed good crawling capacity of cells.

Keywords

Recombinant spider silk protein PCL Electrospinning Submicrofibre Cytocompatibility Composite scaffolds

References

Boontheekul

, and Mooney

D.J.

, Curr. Opin. Biotech., 14(5), (2003) 559–565.

Shachar

, Tsur

G.O.

, Dvir

, Leor

, and Cohen

, Acta. Biomater., 7(1) (2011) 152–162.

Yang

G.L.

, and Zhao

S.F.

, J. Int. Stomatol., 34(3) (2007) 210–212.

, and Wang

Y.J.

, Mater. Rev., 19(1) (2005) 24–27.

, Huang

J.K.

, Tu

G.Y.

, and Huang

, J. Bio. Eng., 21(6) (2004) 1006–1010.

, Tu

G.Y.

, Huang

Z.H.

, and Huang

, J. Bio. Eng., 22(6) (2005), 1206–1209.

Ruan

C.R.

, Huang

J.X.

, Wei

M.H.

, and Li

, Chin. J. Biotechnol., 23(5) (2007), 858–861.

Wang

T.J.

, Wang

I.J.

, Lu

J.N.

, and Young

T.H.

, Mol. Vis., 18(2012), 255–64.

Hutmacher

D.W.

, Schantz

J.T.

, and Tamai

T.K.

, Tissue Eng., 7(2001), 441–455.

10.

Chen

D.L.

, Li

, and Fang

, Chin. J. Rep. Reconstruct. Sur., 13(4) (2005), 411–415.

11.

Benjamin

, Benjamin

, and Fang

, Biodegradable and/or Bioabsorbable Fibrous Articles and Methods for Using the Articles in Medical Applications. PCT: WO 02/092 339, 2002.5.15.

12.

Coburn

, Gibson

, Bandalini

P. A.

, and Laird

, Smart. Struct. Syst., 7(3) (2011) 213–222.

13.

Daniel

, Darrell

, and Woraphon

, Electrospun Skin Masks and Uses thereof. PCT / US:00/27 775, 2000.10.6.

14.

Hiep

N.T.

, and Lee

B.T.

, J. Mater. Sci. Mater. Med., 21(6) (2010) 1969–1978.

15.

Grafahrend

, Lleixa

, and Salber

, J. Mater. Sci., Mater. Med., 19(4) (2008) 1479–1484.

16.

Chon

E.J.

, Phan

T.T.

, and Lim

I.J.

, Acta. Biomaterialia, 3(3) (2007), 321–330.

17.

Linnemann

, Ali

, and Grie

, Text. Int. Her., 4(2006), 22–24.

18.

, Chen

D.L.

, and Wu

Q.Y.

, Electrospinning Instrument. Patent [P]: CN 200610125960.6, 2006.

19.

She

H.D.

, Preparation and Study of HA/PCL Composite Scaffold. Fujian Normal University [D], 2007, 20.

20.

Chen

D.L.

, Fang

, Tu

G.Y.

, Huang

, and Li

, J. Func. Mater, 38(7) (2007) 1194–1196.

21.

, Chen

D.L.

, and Tu

G.Y.

, Recombinant Spider Silk Protein-polymer Porous Scaffold for Tissue Engineering. Patent [P]:CN200510076750.8, 2005.

22.

B.Y.

, Zheng

, and Chen

D.L.

Burns, 36(6) (2010) 891–896.

Preparation of a Recombinant Spider Silk Protein/Pcl Blend Submicrofibrous Mat and Its Cytocompatibility

Abstract

Keywords

References