Surface modification of biomaterials by photochemical immobilization and photograft polymerization to improve hemocompatibility

被引：9

作者：

Feng Y. ^{[1
]}

Zhao H. ^{[1
]}

Zhang L. ^{[1
]}

Guo J. ^{[1
]}

机构：

[1] School of Chemical Engineering and Technology, Tianjin University

来源：

Frontiers of Chemical Engineering in China | 2010年 / 4卷 / 3期

关键词：

Anticoagulative; Biomaterials; Biomimetic; Hemocompatibility; Phosphorylcholine; Photochemical immobilization; Photograft polymerization; Photolinker; Surface modification;

D O I：

10.1007/s11705-010-0005-z

中图分类号：

学科分类号：

摘要：

Thrombus formation and blood coagulation are serious problems associated with blood contacting products, such as catheters, vascular grafts, artificial hearts, and heart valves. Recent progresses and strategies to improve the hemocompatibility of biomaterials by surface modification using photochemical immobilization and photograft polymerization are reviewed in this paper. Three approaches to modify biomaterial surfaces for improving the hemocompatibility, i. e., bioinert surfaces, immobilization of anticoagulative substances and biomimetic surfaces, are introduced. The biomimetic amphiphilic phosphorylcholine and Arg-Gly-Asp (RGD) sequence are the most effective and most often employed biomolecules and peptide sequence for improving hemocompatibility of material surfaces. The RGD sequence can enhance adhesion and growth of endothelial cells (ECs) on material surfaces and increase the retention of ECs under flow shear stress conditions. This surface modification is a promising strategy for biomaterials especially for cardiovascular grafts and functional tissue engineered blood vessels. © 2010 Higher Education Press and Springer-Verlag Berlin Heidelberg.

引用

页码：372 / 381

页数：9

共 71 条

[1]

Lee J.H., Lee H.B., Andrade J.D., Blood compatibility of polyethylene oxide surfaces, Progress in Polymer Science, 20, 6, pp. 1043-1079, (1995)

[2]

Sakuragi M., Tsuzuki S., Hasuda H., Wada A., Matoba K., Kubo I., Ito Y., Synthesis of a photoimmobilizable histidine polymer for surface modification, Journal of Applied Polymer Science, 112, 1, pp. 315-319, (2009)

[3]

Lamponi S., Di Canio C., Forbicioni M., Barbucci R., Heterotypic interaction of fibroblasts and endothelial cells on restricted area, Journal of Biomedical Materials Research, 92 A, 2, pp. 733-745, (2010)

[4]

Matsuda T., Sugawara T., Control of cell adhesion, migration, and orientation on photochemically microprocessed surfaces, Journal of Biomedical Materials Research, 32, 2, pp. 165-173, (1996)

[5]

Bhattacharya A., Misra B.N., Grafting: A versatile means to modify polymers-techniques, factors and applications, Progress in PolymerScience, 29, 8, pp. 767-814, (2004)

[6]

He D.M., Susanto H., Ulbricht M., Photo-irradiation for preparation, modification and stimulation of polymeric membranes, Progress in Polymer Science, 34, 1, pp. 62-98, (2009)

[7]

Susanto H., Ulbricht M., Photografted thin polymer hydrogel layers on PES ultrafiltration membranes: Characterization, stability, and influence on separation performance, Langmuir, 23, 14, pp. 7818-7830, (2007)

[8]

Janorkar A.V., Proulx S.E., Metters A.T., Hirt D.E., Surface-confined photopolymerization of single- and mixed-monomer systems to tailor the wettability of poly(L-lactide) film, Journal of Polymer Science. Part A, Polymer Chemistry, 44, 22, pp. 6534-6543, (2006)

[9]

Zhu S.Q., Hirt D.E., Improving the wettability of deep-groove polypropylene fibers by photografting, Textile Research Journal, 79, 6, pp. 534-547, (2009)

[10]

Suri S., Singh A., Schmidt C.E., Photofunctionalization of materials to promote protein and cell interactions for tissue-engineering applications, Biological Interactions on Materials Surfaces, pp. 297-318, (2009)

← 1 2 3 4 5 6 7 8 →