海洋污损生物的粘附已经成为人类开发海洋的一大障碍,研究海洋污损生物的粘附机制对航海运输具有重要意义.本文综述了包括双壳类,多毛虫,菌类等在内的三种海洋污损生物的表面粘附机制,三者释放的粘附蛋白具有高强度、高韧性和防水性的特点,对基底具有极强的粘附能力.这种功能主要源自核心的3,4-二羟基苯丙氨酸(DOPA)介导交联和其与基底之间的相互作用,受其启发,可以设计开发多种基于DOPA的抗粘附材料、生物医用材料及防水粘结剂等,均有着广泛的应用.
参考文献
| [1] | 化学生态学在海洋污损生物防除中的应用[J].应用生态学报,2005(10):1997-2002. |
| [2] | Zhen Cai-Lu;Liang Li-Li;Zhao Zhuo .Marine fouling prevention and control technology research progress[J].Environmental Protection and Circular Economy,2009,29(011):48-50. |
| [3] | 边洁,王威强,管从胜.金属腐蚀防护有机涂料的研究进展[J].材料科学与工程学报,2003(05):769-772. |
| [4] | 刘珊珊;严涛.海洋污损生物防除的现状及展望[A].,2004:53-60. |
| [5] | 胥震,欧阳清,易定和.海洋污损生物防除方法概述及发展趋势[J].腐蚀科学与防护技术,2012(03):192-198. |
| [6] | 周文木,王孝杰,胡碧茹,吴文健.海洋污损生物粘附机制及防污涂层表面工程[J].应用化学,2010(09):993-997. |
| [7] | Maja Wiegemann .Adhesion in blue mussels (Mytilus edulis) and barnacles (genus Balanus): Mechanisms and technical applications[J].Aquatic sciences,2005(2):166-176. |
| [8] | Waite J H .The Phylogeny and Chemical Diversity of Quinonetanned Glues and Varnishes[J].Comparative Biochemistry and Physiology Part B:Comparative Biochemistry,1990,97(01):19-29. |
| [9] | Mary J.Sever;Jaime T.Weisser;Jennifer Monahan;Shalini Srinivasan;Jonathan J.Wilker .Metal-Mediated Cross-Linking in the Generation of a Marine-Mussel Adhesive[J].Angewandte Chemie,2004(4):454-456. |
| [10] | Sun, CJ;Waite, JH .Mapping chemical gradients within and along a fibrous structural tissue, mussel byssal threads[J].The Journal of Biological Chemistry,2005(47):39332-39336. |
| [11] | Peter A.Suci;Gill G.Geesey .Influence of sodiumperiodate and tyrosinase on binding of alginate to adlayers of mytilus edulis foot protein 1[J].Journal of Colloid and Interface Science,2000(2):340-348. |
| [12] | Olivieri M P;Wollman R M;Hurley M I et al.Using Conformational Analysis to Identify Structurally Conserved Regions of MAP Peptides That Exhibit Cellular Attachment Ability[J].Biofouling,2002,18(02):149-159. |
| [13] | Waite JH;Lichtenegger HC;Stucky GD;Hansma P .Exploring molecular and mechanical gradients in structural bioscaffolds[J].Biochemistry,2004(24):7653-7662. |
| [14] | Silverman HG;Roberto FF .Understanding marine mussel adhesion[J].Marine biotechnology,2007(6):661-681. |
| [15] | Ruppert E E;Barnes R D;Fox R S.Invertebrate Zoology[M].Saunders College Pub,1994:205-247. |
| [16] | Waite J H;Jensen R A;Morse D E .Cement Precursor Proteins of the Reef-building Polychaete Phragmatopoma Californica (Fewkes)[J].Biochemistry,1992,31(25):5733-5738. |
| [17] | De Jong H G B.Morphology of coacervates[A].Elsevier Publishing Company,Amsterdam,1949:431. |
| [18] | Stewart RJ;Weaver JC;Morse DE;Waite JH .The tube cement of Phragmatopoma californica: a solid foam[J].The Journal of Experimental Biology,2004(26):4727-4734. |
| [19] | Corpe,W.A.[A].Northwestern Un iv.Press,Evanston,IL,1972:598-608. |
| [20] | Bodenmiller D;Toh E;Brun YV .Development of Surface Adhesion in Caulobacter crescentus.[J].Journal of Bacteriology,2004(5):1438-1447. |
| [21] | Smith CS;Hinz A;Bodenmiller D;Larson DE;Brun YV .Identification of genes required for synthesis of the adhesive holdfast in Caulobacter crescentus.[J].Journal of Bacteriology,2003(4):1432-1442. |
| [22] | Tsang PH;Li GL;Brun YV;Ben Freund L;Tang JX .Adhesion of single bacterial cells in the micronewton range[J].Proceedings of the National Academy of Sciences of the United States of America,2006(15):5764-5768. |
| [23] | 廖智,申望,王日昕.海洋生物黏附蛋白研究进展[J].浙江海洋学院学报(自然科学版),2007(04):439-447. |
| [24] | Sun Pei-Yu;Tian Li-Ying;Zheng Zhen et al.Mussels bionic polyurethane containing dopamine[J].Acta Polymerica Sinica,2009,8:016. |
| [25] | Jeffrey L.Dalsin;Lijun Lin;Samuele Tosatti;Janos Voros;Marcus Textor;Phillip B.Messersmith .Protein Resistance of Titanium Oxide Surfaces Modified by Biologically Inspired mPEG-DOPA[J].Langmuir: The ACS Journal of Surfaces and Colloids,2005(2):640-646. |
| [26] | Wach JY;Malisova B;Bonazzi S;Tosatti S;Textor M;Zurcher S;Gademann K .Protein-Resistant Surfaces through Mild Dopamine Surface Functionalization[J].Chemistry: A European journal,2008(34):10579-10584. |
| [27] | Gao C;Li G;Xue H;Yang W;Zhang F;Jiang S .Functionalizable and ultra-low fouling zwitterionic surfaces via adhesive mussel mimetic linkages.[J].Biomaterials,2010(7):1486-1492. |
| [28] | Lee, H;Lee, KD;Pyo, KB;Park, SY;Lee, H .Catechol-Grafted Poly(ethylene glycol) for PEGylation on Versatile Substrates[J].Langmuir: The ACS Journal of Surfaces and Colloids,2010(6):3790-3793. |
| [29] | C. Yang;G. L. Liang;K. M. Xu;P. Gao;B.Xu .Bactericidal functionalization of wrinkle-free fabrics via covalently bonding TiO_2 @ Ag nanoconjugates[J].Journal of Materials Science,2009(7):1894-1901. |
| [30] | 徐又一,蒋金泓,朱利平,朱宝库.多巴胺的自聚-附着行为与膜表面功能化[J].膜科学与技术,2011(03):32-38. |
| [31] | Taolei Sun;Hong Tan;Dong Han;Qiang Fu;Lei Jiang .No Platelet Can Adhere—Largely Improved Blood Compatibility on Nanostructured Superhydrophobic Surfaces[J].Small,2005(10):959-963. |
| [32] | 屠美,牟善松,周长忍.基材与液晶种类对液晶复合膜血液相容性的影响[J].材料科学与工程学报,2005(03):357-360. |
| [33] | Jin Qi-Lin;Huang Yun-Chao .Influence of Biomaterial on the Behavior of Cytobiolog[J].Journal of Materials Science& Engineering,2007,1:25. |
| [34] | 南开辉,王迎军.复合纳米生物医用材料的研究[J].材料科学与工程学报,2006(01):156-159. |
| [35] | Qian Ye;Feng Zhou;Weimin Liu .Bioinspired catecholic chemistry for surface modification[J].Chemical Society Reviews,2011(7):4244-4258. |
| [36] | Gao JH;Liang GL;Cheung JS;Pan Y;Kuang Y;Zhao F;Zhang B;Zhang XX;Wu EX;Xu B .Multifunctional yolk-shell nanoparticles: A potential MRI contrast and anticancer agent[J].Journal of the American Chemical Society,2008(35):11828-11833. |
| [37] | Haeshin Lee;Norbert F. Scherer;Phillip B. Messersmith .Single-molecule mechanics of mussel adhesion[J].Proceedings of the National Academy of Sciences of the United States of America,2006(35):12999-13003. |
| [38] | Travers H. Anderson;Jing Yu;Abril Estrada;Malte U. Hammer;J. Herbert Waite;Jacob N. Israelachvili .The Contribution of DOPA to Substrate-Peptide Adhesion and Internal Cohesion of Mussel-Inspired Synthetic Peptide Films[J].Advanced functional materials,2010(23):4196-4205. |
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