水凝胶是在水中溶胀并保持大量水分而又不溶解的聚合物,与生物机体组织很相似.蛋白基水凝胶具有良好的生物相容性和生物降解性,在组织工程中的应用主要是恢复、维持或改善受损机体组织与器官的形态和功能,以达到修复再生的目的,被誉为下一代最具潜力的组织工程用生物材料.综述了组织工程用天然蛋白基和合成蛋白基水凝胶的研究进展,并指出了其优、缺点及发展方向.
参考文献
| [1] | Yoshiaki Hirano;David J. Mooney .Peptide and Protein Presenting Materials for Tissue Engineering[J].Advanced Materials,2004(1):17-25. |
| [2] | Rocha LB;Goissis G;Rossi MA .Biocompatibility of anionic collagen matrix as scaffold for bone healing.[J].Biomaterials,2002(2):449-456. |
| [3] | Xiao Y;Qian H;Young WG;Bartold PM .Tissue engineering for bone regeneration using differentiated alveolar bone cells in collagen scaffolds.[J].Tissue engineering,2003(6):1167-1177. |
| [4] | Shih Y R V;Chen C N;Tsai S W et al.Growth of mesen-chymal stern cells on electrospun type I collagen nanofibers[J].Stem Cells,2006,24(11):2391. |
| [5] | Chandler L A;Gu D L;Ma C L et al.Matrix-enabled gene transfer for cutaneous wound repair[J].Wound Repair and Regeneration,2000,8(06):473. |
| [6] | Okarnoto T;Yamamoto Y;Gotoh M et al.Slow release of bone rnorphogenetic protein-from a gelatin sponge to pro-mote regeneration of tracheal cartilage in a canine rnodel[J].Journal of Thoracic and Cardiovascular Surgery,2004,127(02):329. |
| [7] | Ito A;Mase A;Takizawa Y et al.Transglutaminase-rnedi-ated gelatin matrices incorporating cell adhesion factors as a biomaterial for tissue engineering[J].Journal of Bioscience and Bioengineering,2003,95(02):196. |
| [8] | Holland TA;Tabata Y;Mikos AG .Dual growth factor delivery from degradable oligo(poly(ethylene glycol) fumarate) hydrogel scaffolds for cartilage tissue engineering[J].Journal of Controlled Release: Official Journal of the Controlled Release Society,2005(1/3):111-125. |
| [9] | Park H;Temenoff JS;Holland TA;Tabata Y;Mikos AG .Delivery of TGF-beta 1 and chondrocytes via injectable, biodegradable hydrogels for cartilage tissue engineering applications[J].Biomaterials,2005(34):7095-7103. |
| [10] | Young S;Wong M;Tabata Y;Mikos AG .Gelatin as a delivery vehicle for the controlled release of bioactive molecules[J].Journal of Controlled Release: Official Journal of the Controlled Release Society,2005(1/3):256-274. |
| [11] | Olsen D;Yang C;Bodo M;Chang R;Leigh S;Baez J;Carmichael D;Perala M;Hamalainen ER;Jarvinen M;Polarek J .Recombinant collagen and gelatin for drug delivery.[J].Advanced drug delivery reviews,2003(12):1547-1567. |
| [12] | Hellio D;Djabourov M .Physically and chemically crosslinked gelatin gels[J].Macromolecular symposia,2006(0):23-27. |
| [13] | Bessho M;Furuta M;Kojima T et al.Gelatin hydrogels cross-linked by gamma-ray irradiation:materials for absorp-tion and release of dye[J].Journal of Biomaterials Science-Polymer Edition,2005,16(06):715. |
| [14] | Ozeki M;Tabata Y .In vivo degradability of hydrogels pre-pared from different gelatins by various cross-linking meth-ods[J].Journal of Biomaterials Science-Polymer Edition,2005,16(05):549. |
| [15] | Fini M;Motta A;Torricelli P;Giavaresi G;Nicoli Aldini N;Tschon M;Giardino R;Migliaresi C .The healing of confined critical size cancellous defects in the presence of silk fibroin hydrogel.[J].Biomaterials,2005(17):3527-3536. |
| [16] | Inounye K;Kurokawa M;Nishikawa S et al.Use of Bom-byx mori silk fibroin as a substratum for cultivation of ani-mal cells[J].Journal of Biochemical and Biophysical Methods,1998,37(03):159. |
| [17] | Min BM;Lee G;Kim SH;Nam YS;Lee TS;Park WH .Electrospinning of silk fibroin nanofibers and its effect on the adhesion and spreading of normal human keratinocytes and fibroblasts in vitro.[J].Biomaterials,2004(7/8):1289-1297. |
| [18] | Ehrbar M;Metters A;Zammaretti P;Hubbell JA;Zisch AH .Endothelial cell proliferation and progenitor maturation by fibrin-bound VEGF variants with differential susceptibilities to local cellular activity[J].Journal of Controlled Release: Official Journal of the Controlled Release Society,2005(1/3):93-109. |
| [19] | Willerth SM;Arendas KJ;Gottlieb DI;Sakiyama-Elbert SE .Optimization of fibrin scaffolds for differentiation of murine embryonic stem cells into neural lineage cells[J].Biomaterials,2006(36):5990-6003. |
| [20] | Schantz JT;Brandwood A;Hutmacher DW;Khor HL;Bittner K .Osteogenic differentiation of mesenchymal progenitor cells in computer designed fibrin-polymer-ceramic scaffolds manufactured by fused deposition modeling[J].Journal of Materials Science. Materials in Medicine,2005(9):807-819. |
| [21] | Gwak SJ;Kim SS;Sung K;Han J;Choi CY;Kim BS .Synergistic effect of keratinocyte transplantation and epidermal growth factor delivery on epidermal regeneration.[J].Cell transplantation,2005(10):809-817. |
| [22] | Geer D J;Swartz D D;Andreadis S T .Biomimetic delivery of keratinocyte growth factor upon cellular demand for accel-erated wound holing in vitro and in vivo[J].American Journal of Pathology,2005,167:1575. |
| [23] | Jung RE;Schmoekel HG;Zwahlen R;Kokovic V;Hammerle CH;Weber FE .Platelet-rich plasma and fibrin as delivery systems for recombinant human bone morphogenetic protein-2.[J].Clinical oral implants research,2005(6):676-682. |
| [24] | Kelpke S S;Zinn K R;Rue LW et al.Site-specific delivery of acidic fibroblast growth factor stimulates angiogenic and osteogenic responses in vivo[J].Journal of Biomedical Materials Research Part A,2004,71A(02):316. |
| [25] | Poland E D;Matthews J A;Pawlowski K J et al.Electro-spinning collagen and elastin:preliminary vascular tissue en-gineering[J].Frontiers in Bioscience,2004,9:1422. |
| [26] | Neuenschwander S;P Hoerstrup S .Heart valve tissue engineering.[J].Transplant immunology,2004(3/4):359-365. |
| [27] | Xu JW;Johnson TS;Motarjem PM;Peretti GM;Randolph MA;Yaremchuk MJ .Tissue-engineered flexible ear-shaped cartilage.[J].Plastic and reconstructive surgery,2005(6):1633-1641. |
| [28] | Bellingham C M;Lillie M A;Gosline J M et al.Recombi-nant human elastin polypeptides selfassemble into biomateri-als with elastin-like properties[J].Biopolymers,2003,70:445. |
| [29] | Mithieux SM;Rasko JE;Weiss AS .Synthetic elastin hydrogels derived from massive elastic assemblies of self-organized human protein monomers.[J].Biomaterials,2004(20):4921-4927. |
| [30] | Wright E R;McMillan R A;Cooper A et al.Thermoplas-tic elastomer hydrogels via self-assembly of an elastinmimet-ic triblock polypeptide[J].Advanced Functional Materials,2002,12:149. |
| [31] | Herrero-Vanrell R;Rincon AC;Alonso M;Reboto V;Molina-Martinez IT;Rodriguez-Cabello JC .Self-assembled particles of an elastin-like polymer as vehicles for controlled drug release[J].Journal of Controlled Release: Official Journal of the Controlled Release Society,2005(1):113-122. |
| [32] | Zhou Z;Zheng H;Wei M;Huang J;Chen Y .Structure and mechanical properties of cellulose derivatives/soy protein isolate blends[J].Journal of Applied Polymer Science,2008(5):3267-3274. |
| [33] | Zheng H;Zhou ZY;Chen Y;Huang J;Xiong FL .PH-Sensitive alginate/soy protein microspheres as drug transporter[J].Journal of Applied Polymer Science,2007(2):1034-1041. |
| [34] | Claudia M.Vaz;P.F.N.M.van Doeveren;R.L.Reis;A.M.Cunha .Development and design of double-layer co-injection moulded soy protein based drug delivery devices[J].Polymer: The International Journal for the Science and Technology of Polymers,2003(19):5983-5992. |
| [35] | Cappelloa J;Crissmana J W;Crissmana M et al.In-situ self-assembling protein polymer gel systems for administra-tion,delivery,and release of drugs[J].J Controlled Re-lease,1998,53(1-3):105. |
| [36] | Wright ER;Conticello VP .Self-assembly of block copolymers derived from elastin-mimetic polypeptide sequences.[J].Advanced drug delivery reviews,2002(8):1057-1073. |
| [37] | Ghandehari H;Cappello J .Genetic engineering of protein-based polymers: potential in controlled drug delivery.[J].Pharmaceutical research,1998(6):813-815. |
| [38] | Gerd G Kochendoerfer;Stephen BH Kent .Chemical protein synthesis[J].Current opinion in chemical biology,1999(6):665-671. |
| [39] | Deming TJ .Methodologies for preparation of synthetic block copolypeptides: materials with future promise in drug delivery.[J].Advanced drug delivery reviews,2002(8):1145-1155. |
| [40] | Deming T J .Facile synthesis of block copolypeptides of de-fined architecture[J].Nature,1997,390:386. |
| [41] | McGrath K P;Fournier M J;Mason T L et al.Genetically directed syntheses of new polymeric materials.Expression of artificial genes encoding proteins with repeating-(AlaGly)ProGhiGly-elements[J].Journal of the American Chemical Society,1992,114:727. |
| [42] | Hong M.;Isailovic D.;McMillan RA.;Conticello VP. .Structure of an elastin-mimetic polypeptide by solid-state NMR chemical shift analysis[J].Biopolymers: Original Research on Biomolecules and Biomolecular Assemblies,2003(2):158-168. |
| [43] | Wei Shen;Rob G.H.Lammertink;Jill K.Sakata;Julia A.Kornfield;David A.Tirrell .Assembly of an Artificial Protein Hydrogel through Leucine Zipper Aggregation and Disulfide Bond Formation[J].Macromolecules,2005(9):3909-3916. |
| [44] | Shi-Wen Huang;Jun Wang;Peng-Chi Zhang;Hai-Quan Mao;Ren-Xi Zhuo;Kam W.Leong .Effect of Chemistry and Morphology on the Biofunctionality of Self-Assembling Diblock Copolypeptide Hydrogels[J].Biomacromolecules,2004(2):306-311. |
| [45] | Tang A.;Stewart RJ.;Kopecek J.;Wang C. .The coiled coils in the design of protein-based constructs: hybrid hydrogels and epitope displays[J].Journal of Controlled Release: Official Journal of the Controlled Release Society,2001(1/3):57-70. |
| [46] | Wu SC;Yu JC;Hsu SH;Chen DC .Artificial extracellular matrix proteins contain heparin-binding and RGD-containing domains to improve osteoblast-like cell attachment and growth.[J].Journal of biomedical materials research, Part A,2006(3):557-565. |
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