Your search keyword '"Daniel V. Bax"' showing total 53 results

51. Elastin-based materialsPart of the peptide- and protein-based materials themed issue.

Author

Jessica F. Almine, Daniel V. Bax, Suzanne M. Mithieux, Lisa Nivison-Smith, Jelena Rnjak, Anna Waterhouse, Steven G. Wise, and Anthony S. Weiss

Subjects

BIOMEDICAL materials, ELASTIN, PEPTIDES, RECOMBINANT proteins, ELASTICITY, CELL communication

Abstract

Elastin is a versatile elastic protein that dominates flexible tissues capable of recoil, and facilitates commensurate cell interactions in these tissues in all higher vertebrates. Elastin's persistence and insolubility hampered early efforts to construct versatile biomaterials. Subsequently the field has progressed substantially through the adapted use of solubilized elastin, elastin-based peptides and the increasing availability of recombinant forms of the natural soluble elastin precursor, tropoelastin. These interactions allow for the formation of a sophisticated range of biomaterial constructs and composites that benefit from elastin's physical properties of innate assembly and elasticity, and cell interactive properties as discussed in this tutorial review. [ABSTRACT FROM AUTHOR]

Published

2010

52. Optimisation of UV irradiation as a binding site conserving method for crosslinking collagen-based scaffolds

Author

Samir W. Hamaia, Ruth E. Cameron, Daniel V. Bax, Serena M. Best, Natalia Davidenko, Carlos F. Schuster, Richard W. Farndale, Bax, Daniel [0000-0002-1162-5319], Farndale, Richard [0000-0001-6130-8808], Best, Serena [0000-0001-7866-8607], Cameron, Ruth [0000-0003-1573-4923], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Materials science, food.ingredient, Ultraviolet Rays, Biomedical Engineering, Biophysics, Bioengineering, 02 engineering and technology, Gelatin, Collagen Type I, Biomaterials, 03 medical and health sciences, chemistry.chemical_compound, food, Tissue engineering, Cell Line, Tumor, Cell Adhesion, Animals, Humans, Organic chemistry, Denaturation (biochemistry), Reactivity (chemistry), Destabilisation, Irradiation, Cell Proliferation, Integrin binding, Carbodiimide, Binding Sites, Tissue Scaffolds, Biomaterials Synthesis and Characterization, 021001 nanoscience & nanotechnology, 030104 developmental biology, chemistry, Microscopy, Electron, Scanning, Chemical Engineering(all), Cattle, 0210 nano-technology

Abstract

Short wavelength (λ = 254 nm) UV irradiation was evaluated over a range of intensities (0.06 to 0.96 J/cm2) as a means of cross-linking collagen- and gelatin-based scaffolds, to tailor their material characteristics whilst retaining biological functionality. Zero-link carbodiimide treatments are commonly applied to collagen-based materials, forming cross-links from carboxylate anions (for example the acidic E of GFOGER) that are an essential part of integrin binding sites on collagen. Cross-linking these amino acids therefore disrupts the bioactivity of collagen. In contrast, UV irradiation forms bonds from less important aromatic tyrosine and phenylalanine residues. We therefore hypothesised that UV cross-linking would not compromise collagen cell reactivity. Here, highly porous (~99 %) isotropic, collagen-based scaffolds were produced via ice-templating. A series of scaffolds (pore diameters ranging from 130–260 μm) with ascending stability in water was made from gelatin, two different sources of collagen I, or blends of these materials. Glucose, known to aid UV crosslinking of collagen, was added to some lower-stability formulations. These scaffolds were exposed to different doses of UV irradiation, and the scaffold morphology, dissolution stability in water, resistance to compression and cell reactivity was assessed. Stabilisation in aqueous media varied with both the nature of the collagen-based material employed and the UV intensity. Scaffolds made from the most stable materials showed the greatest stability after irradiation, although the levels of cross-linking in all cases were relatively low. Scaffolds made from pure collagen from the two different sources showed different optimum levels of irradiation, suggesting altered balance between stabilisation from cross-linking and destabilisation from denaturation. The introduction of glucose into the scaffold enhanced the efficacy of UV cross-linking. Finally, as hypothesized, cell attachment, spreading and proliferation on collagen materials were unaffected by UV cross-linking. UV irradiation may therefore be used to provide relatively low level cross-linking of collagen without loss of biological functionality. Electronic supplementary material The online version of this article (doi:10.1007/s10856-015-5627-8) contains supplementary material, which is available to authorized users.

53. Characterization of Endothelial Progenitor Cell Interactions with Human Tropoelastin.

Author

Young Yu, Steven G Wise, Praveesuda L Michael, Daniel V Bax, Gloria S C Yuen, Matti A Hiob, Giselle C Yeo, Elysse C Filipe, Louise L Dunn, Kim H Chan, Hamid Hajian, David S Celermajer, Anthony S Weiss, and Martin K C Ng

Subjects

Medicine, Science

Abstract

The deployment of endovascular implants such as stents in the treatment of cardiovascular disease damages the vascular endothelium, increasing the risk of thrombosis and promoting neointimal hyperplasia. The rapid restoration of a functional endothelium is known to reduce these complications. Circulating endothelial progenitor cells (EPCs) are increasingly recognized as important contributors to device re-endothelialization. Extracellular matrix proteins prominent in the vessel wall may enhance EPC-directed re-endothelialization. We examined attachment, spreading and proliferation on recombinant human tropoelastin (rhTE) and investigated the mechanism and site of interaction. EPCs attached and spread on rhTE in a dose dependent manner, reaching a maximal level of 56±3% and 54±3%, respectively. EPC proliferation on rhTE was comparable to vitronectin, fibronectin and collagen. EDTA, but not heparan sulfate or lactose, reduced EPC attachment by 81±3%, while full attachment was recovered after add-back of manganese, inferring a classical integrin-mediated interaction. Integrin αVβ3 blocking antibodies decreased EPC adhesion and spreading on rhTE by 39±3% and 56±10% respectively, demonstrating a large contribution from this specific integrin. Attachment of EPCs on N-terminal rhTE constructs N25 and N18 accounted for most of this interaction, accompanied by comparable spreading. In contrast, attachment and spreading on N10 was negligible. αVβ3 blocking antibodies reduced EPC spreading on both N25 and N18 by 45±4% and 42±14%, respectively. In conclusion, rhTE supports EPC binding via an integrin mechanism involving αVβ3. N25 and N18, but not N10 constructs of rhTE contribute to EPC binding. The regulation of EPC activity by rhTE may have implications for modulation of the vascular biocompatibility of endovascular implants.

Published

2015