1. |
CRANFORD S W,TARAKANOVA A,PUGNO N M,et al.Nonlinear material behaviour of spider silk yields robust webs[J].Nature,2012,482(7383):72-76.
|
2. |
裔婷婷,潘志娟.静电纺再生加工对横纹金珠丝微观结构的影响[J].纺织学报,2012,33(4):1-5.
|
3. |
CHUNG H,KIM T Y,LEE S Y.Recent advances in production of recombinant spider silk proteins[J].Curr Opin Biotechnol,2012,23(6):957-964.
|
4. |
LEWICKA M,HERMANSON O,RISING A U.Recombinant spider silk matrices for neural stem cell cultures[J].Biomaterials,2012,33(31):7712-7717.
|
5. |
赵亮,徐艳丽,邱慧,等.蛛丝蛋白双层小直径血管支架的制备及其血液相容性体外实验[J].中国修复重建外科杂志,2013,27(7):800-804.
|
6. |
WIDHE M,JOHANSSON J,HEDHAMMAR M,et al.Current progress and limitations of spider silk for biomedical applications[J].Biopolymers,2012,97(6):468-478.
|
7. |
HEIDEBRECHT A,SCHEIBEL T.Recombinant production of spider silk proteins[J].Adv Appl Microbiol,2013,82:115-153.
|
8. |
GAO Zhenwei,LIN Zhi,HUANG Weidong,et al.Structural characterization of minor ampullate spidroin domains and their distinct roles in fibroin solubility and fiber formation[J].PLoS One,2013,8(2):e56142.
|
9. |
王金雷,陈格飞,李佳,等.悦目金蛛丝蛋白TuSp1重复模块特征[J].东华大学学报:自然科学版,2013,39(2):196-201.
|
10. |
PAQUET-MERCIER F,LEFEVRE T,AUGER M A.Evidence by infrared spectroscopy of the presence of two types of β-sheets in major ampullate spider silk and silkworm silk[J].Soft Matter,2013,9(1):208-215.
|
11. |
杨子江,陈格飞,孟清.大腹园蛛次壶腹腺丝的表达[J].生物工程学报,2013,29(9):1323-1331.
|
12. |
TEULÉ F,ADDISON B,COOPER A R,et al.Combining flagelliform and dragline spider silk motifs to produce tunable synthetic biopolymer fibers[J].Biopolymers,2012,97(6):418-431.
|
13. |
RISING A,WIDHE M,JOHANSSON J,et al.Spider silk proteins:recent advances in recombinant production,structure-function relationships and biomedical applications[J].Cell Mol Life Sci,2011,68(2):169-184.
|
14. |
WEN Hongxiu,LAN Xiqian,ZHANG Yuansong,et al.Transgenic silkworms (Bombyx mori) produce recombinant spider dragline silk in cocoons[J].Mol Biol Rep,2010,37(4):1815-1821.
|
15. |
XIA Xiaoxia,QIAN Zhigang,KI C S,et al.Native-sized recombinant spider silk protein produced in metabolically engineered Escherichia coli results in a strong fiber[J].Proc Natl Acad Sci U S A,2010,107(32):14059-14063.
|
16. |
TOKAREVA O,MICHALCZECHEN-LACERDA V A,RECH E L,et al.Recombinant DNA production of spider silk proteins[J].Microb Biotechnol,2013,6(6):651-663.
|
17. |
HUMENIK M,SMITH A M,SCHEIBEL T.Recombinant spider silks-biopolymers with potential for future applications[J].Polymers (Basel),2011,3(1):640-661.
|
18. |
ASKARIEH G,HEDHAMMAR M,NORDLING K,et al.Self-assembly of spider silk proteins is controlled by a pH-sensitive relay[J].Nature,2010,465(7295):236-238.
|
19. |
HAGN F,EISOLDT L,HARDY J G,et al.A conserved spider silk domain acts as a molecular Switch that controls fibre assembly[J].Nature,2010,465(7295):239-242.
|
20. |
SLOTTA U,MOUGIN N,ROEMER L,et al.Synthetic spider silk proteins and threads[J].Chemical Engineering Progress,2012,108(5):43-49.
|
21. |
HU X,VASANTHAVADA K,KOHLER K,et al.Molecular mechanisms of spider silk[J].Cell Mol Life Sci,2006,63(17):1986-1999.
|
22. |
RISING A,JOHANSSON J,LARSON G,et al.Major ampullate spidroins from Euprosthenops australis: multiplicity at protein,mRNA and gene levels[J].Insect Mol Biol,2007,5(16):551-561.
|
23. |
KETEN S,XU Zhiping,IHLE B,et al.Nanoconfinement controls stiffness,strength and mechanical toughness of β-sheet crystals in silk[J].Nat Mater,2010,9(4):359-367.
|
24. |
RAMMENSEE S,SLOTTA U,SCHEIBEL T,et al.Assembly mechanism of recombinant spider silk proteins[J].Proc Natl Acad Sci U S A,2008,105(18):6590-6595.
|
25. |
HAGN F,THAMM C,SCHEIBEL T,et al.pH-dependent dimerization and salt-dependent stabilization of the N-terminal domain of spider dragline silk——implications for fiber formation[J].Angew Chem Int Ed Engl,2011,50(1):310-313.
|
26. |
赵晓,张袁松,曾峥,等.基于天然蚕丝及蜘蛛丝蛋白的生物材料研究进展[J].蚕学通讯,2010,30(2):31-37.
|
27. |
RABOTYAGOVA O S,CEBE P,KAPLAN D L.Self-assembly of genetically engineered spider silk block copolymers[J].Biomacromolecules,2009,10(2):229-236.
|
28. |
LAMMEL A,SCHWAB M,SLOTTA U,et al.Processing conditions for the formation of spider silk microspheres[J].ChemSusChem,2008,1(5):413-416.
|
29. |
LAMMEL A,SCHWAB M,HOFER M,et al.Recombinant spider silk particles as drug delivery vehicles[J].Biomaterials,2011,32(8):2233-2240.
|
30. |
HOFER M,WINTER G,MYSCHIK J.Recombinant spider silk particles for controlled delivery of protein drugs[J].Biomaterials,2012,33(5):1554-1562.
|
31. |
LIEBMANN B,HVMMERICH D,SCHEIBEL T,et al.Formulation of poorly water-soluble substances using self-assembling spider silk protein[J].Colloids Surf A Physicochem Eng Asp,2008,331(1/2):126-132.
|
32. |
YOUNG S L,GUPTA M,HANSKE C,et al.Utilizing conformational changes for patterning thin films of recombinant spider silk proteins[J].Biomacromolecules,2012,13(10):3189-3199.
|
33. |
SPIESS K,LAMMEL A,SCHEIBEL T.Recombinant spider silk proteins for applications in biomaterials[J].Macromol Biosci,2010,10(9):998-1007.
|
34. |
RENAULT A,RIOUX-DUBÉ J F,LEFÈVRE T,et al.Structure and mechanical properties of spider silk films at the air-water interface[J].Langmuir,2013,29(25):7931-7938.
|
35. |
HORINEK D,SERR A,GEISLER M,et al.Peptide adsorption on a hydrophobic surface results from an interplay of solvation,surface,and intrapeptide forces[J].Proc Natl Acad Sci U S A,2008,105(8):2842-2847.
|
36. |
HERMANSON K D,HUEMMERICH D,SCHEIBEL T A.Engineered microcapsules fabricated from reconstituted spider silk[J].Adv Mater,2007,19(14):1810.
|
37. |
EISOLDT L,SMITH A,SCHEIBEL T.Decoding the secrets of spider silk[J].Materialstoday,2011,14(3):80-86.
|
38. |
SLOTTA U,HESS S,SPIESS K,et al.Spider silk and amyloid fibrils:a structural comparison[J].Macromol Biosci,2007,7(2):183-188.
|
39. |
RAMMENSEE S,HUEMMERICH D,HERMANSON K D,et al.Rheological characterization of hydrogels formed by recombinantly produced spider silk[J].Appl Phys A Mater Sci Process,2006,82(2):261-264.
|
40. |
LEAL-EGAÑA A,SCHEIBEL T.Silk-based materials for biomedical applications[J].Biotechnol Appl Biochem,2010,55(3):155-167.
|
41. |
SCHACHT K,SCHEIBEL T.Controlled hydrogel formation of a recombinant spider silk protein[J].Biomacromolecules,2011,12(7):2488-2495.
|
42. |
HUEMMERICH D,SLOTTA U,SCHEIBEL T.Processing and modification of films made from recombinant spider silk proteins[J].Appl Phys A Mater Sci Process,2006,82(2):219-222.
|
43. |
SPIESS K,WOHLRAB S,SCHEIBEL T.Structural characterization and functionalization of engineered spider silk films[J].Soft Matter,2010,6(17):4168-4174.
|
44. |
WOHLRAB S,MVLLER S,SCHMIDT A,et al.Cell adhesion and proliferation on RGD-modified recombinant spider silk proteins[J].Biomaterials,2012,33(28):6650-6659.
|
45. |
TEULÉ F,MIAO Yungen,SOHN B H,et al.Silkworms transformed with chimeric silkworm/spider silk genes spin composite silk fibers with improved mechanical properties[J].Proc Natl Acad Sci U S A,2012,109(3):923-928.
|
46. |
HAUPTMANN V,WEICHERT N,MENZEL M,et al.Native-sized spider silk proteins synthesized in planta via intein-based multimerization[J].Transgenic Res,2013,22(2):369-377.
|
47. |
HUANG Huahua,HU Jinlian,ZHU Yong.Shape-memory biopolymers based on β-sheet structures of polyalanine segments inspired by spider silks[J].Macromol Biosci,2013,13(2):161-166.
|
48. |
CURRIE H A,DESCHAUME O,NAIK R R,et al.Genetically engineered chimeric silk-silver binding proteins[J].Adv Funct Mater,2011,21(15):2889-2895.
|
49. |
KRISHNAJI S T,KAPLAN D L.Bioengineered chimeric spider silk-uranium binding proteins[J].Macromol Biosci,2013,13(2):256-264.
|
50. |
刘全勇,江雷.仿生学与天然蜘蛛丝仿生材料[J].高等学校化学学报,2010,31(6):1065-1071.
|