Simon J. Kew scite author profile

Carboxy-terminated polydiacetylene vesicles are known to undergo dramatic color transitions in response to exposure to external stimuli such as pH, temperature, and receptor-ligand binding. FTIR spectroscopy was used to identify the breakdown in the interfacial hydrogen-bonding interactions of the carboxylic acid headgroups of polymerized 10,12-tricosadiynoic acid (TRCDA) vesicles in aqueous solution during pH chromic transition. The headgroup structure was monitored as the chromic transition takes place and the dissociation dependence of the pKa was determined. Due to the attenuated acidity of the interfacially confined carboxy groups, which exhibit pKa values in the range 9.5-9.9, it was found that the deprotonation-triggered blue-red chromic transition occurred in the pH range 9.0-10.1 and that the mechanism of the transition required interaction with the surface carboxyl group, which is of importance in the design of a biochromic mechanism using PDA assemblies. Transmission electron microscopy and FTIR spectroscopy revealed that the surface ionization and the pH-induced chromogenic transition was also accompanied by a dramatic vesicle-planar morphological transition alongside subtle changes to the alkyl chain conformation and packing. A two-step mechanism was implicated as causing the chromic transition that first involves surface deprotonation and then specific cation binding, which can aid the design of sensitive surface-ligand chemistry for new PDA structures.

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Regeneration and repair of tendon and ligament tissue using collagen fibre biomaterials

Kew¹,

et al. 2011

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Crosslinking of phenylboronic acid receptors as a means of glucose selective holographic detection

Horgan

Marshall

Kew

et al. 2006

Biosensors and Bioelectronics

107

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Synthetic collagen fascicles for the regeneration of tendon tissue

Kew¹,

Gwynne

Enea

et al. 2012

Acta Biomaterialia

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The structure of an ideal scaffold for tendon regeneration must be designed to provide a mechanical, structural and chemotactic microenvironment for native cellular activity to synthesize functional (i.e. load bearing) tissue. Collagen fibre scaffolds for this application have shown some promise to date, although the microstructural control required to mimic the native tendon environment has yet to be achieved allowing for minimal control of critical in vivo properties such as degradation rate and mass transport. In this report we describe the fabrication of a novel multi-fibre collagen fascicle structure, based on type-I collagen with failure stress of 25-49 MPa, approximating the strength and structure of native tendon tissue. We demonstrate a microscopic fabrication process based on the automated assembly of type-I collagen fibres with the ability to produce a controllable fascicle-like, structural motif allowing variable numbers of fibres per fascicle. We have confirmed that the resulting post-fabrication type-I collagen structure retains the essential phase behaviour, alignment and spectral characteristics of aligned native type-I collagen. We have also shown that both ovine tendon fibroblasts and human white blood cells in whole blood readily infiltrate the matrix on a macroscopic scale and that these cells adhere to the fibre surface after seven days in culture. The study has indicated that the synthetic collagen fascicle system may be a suitable biomaterial scaffold to provide a rationally designed implantable matrix material to mediate tendon repair and regeneration.

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Evaluation of early-stage osteochondral defect repair using a biphasic scaffold based on a collagen–glycosaminoglycan biopolymer in a caprine model

Getgood

Kew²,

Brooks

et al. 2012

The Knee

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Simon J. Kew

pH Response of Carboxy-Terminated Colorimetric Polydiacetylene Vesicles

Regeneration and repair of tendon and ligament tissue using collagen fibre biomaterials

Crosslinking of phenylboronic acid receptors as a means of glucose selective holographic detection

Synthetic collagen fascicles for the regeneration of tendon tissue

Evaluation of early-stage osteochondral defect repair using a biphasic scaffold based on a collagen–glycosaminoglycan biopolymer in a caprine model

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