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Your search keyword '"Cameron, Ruth E."' showing total 429 results
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429 results on '"Cameron, Ruth E."'

1. A technique for improving dispersion within polymer-glass composites using polymer precipitation

Author

Oosterbeek, Reece N., Zhang, Xiang C., Best, Serena M., and Cameron, Ruth E.

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Materials Science
Abstract

Particulate reinforcement of polymeric matrices is a powerful technique for tailoring the mechanical and degradation properties of bioresorbable implant materials. Dispersion of inorganic particles is critical to achieving optimal properties, however established techniques such as twin-screw extrusion or solvent casting can have significant drawbacks including excessive thermal degradation or particle agglomeration. We present a facile method for production of polymer-inorganic composites that reduces the time at elevated temperature and the time available for particle agglomeration. Glass slurry was added to a dissolved PLLA solution, and ethanol was added to precipitate polymer onto the glass particles. Characterisation of parts formed by subsequent micro-injection moulding of composite precipitate revealed a significant reduction in agglomeration, with d0.9 reduced from 170 to 43 {\mu}m. This drastically improved the ductility ({\epsilon}B) from 7% to 120%, without loss of strength or stiffness. The method is versatile and applicable to a wide range of polymer and filler materials.

Published
2021
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2. The evolution of the structure and mechanical properties of fully bioresorbable polymer-glass composites during degradation

Author

Oosterbeek, Reece N., Zhang, Xiang C., Best, Serena M., and Cameron, Ruth E.

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Materials Science
Abstract

Fully bioresorbable polymer matrix composites have long been considered as potential orthopaedic implant materials, however their combination of mechanical strength, stiffness, ductility and bioresorbability is also attractive for cardiac stent applications. This work investigated reinforcement of polylactide-based polymers with phosphate glasses, addressing key drawbacks of current polymer stents, and examined the often-neglected evolution of structure and mechanical properties during degradation. Incorporation of 15 - 30wt.% phosphate glass led to modulus increases of up to 80% under simulated body conditions, and 15wt.% glass composites retained comparable ductility to pure polymers, crucial for stent applications where ductility and stiffness are required. Two-stage degradation was observed, dominated by interfacial water absorption and glass dissolution. Polymer embrittlement mechanisms (crystallisation, enthalpy relaxation) were suppressed by glass addition, allowing composites to achieve a more controlled loss of mechanical properties during degradation, which could allow gradual transfer of loading to newly healed tissue. These results provide a valuable new system for understanding the structural and mechanical changes occurring during degradation of fully bioresorbable polymer matrix composites, providing important new data to underpin the design of effective cardiac stent materials.

Published
2021
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5. Tuning structural relaxations, mechanical properties, and degradation timescale of PLLA during hydrolytic degradation by blending with PLCL-PEG

Author

Oosterbeek, Reece N., Kwon, Kyung-Ah, Duffy, Patrick, McMahon, Sean, Zhang, Xiang C., Best, Serena M., and Cameron, Ruth E.

Subjects
Condensed Matter - Materials Science
Abstract

Poly-L-lactide (PLLA) is a popular choice for medical devices due to its bioresorbability and superior mechanical properties compared with other polymers. However, although PLLA has been investigated for use in bioresorbable cardiovascular stents, it presents application-specific limitations which hamper device therapies. These include low toughness and strength compared with metals used for this purpose, and slow degradation. Blending PLLA with novel polyethylene glycol functionalised poly(L-lactide-co-$\varepsilon$-caprolactone) (PLCL-PEG) materials has been investigated here to tailor the mechanical properties and degradation behaviour of PLLA. This exciting approach provides a foundation for a next generation of bioresorbable materials whose properties can be rapidly tuned. The degradation of PLLA was significantly accelerated by addition of PLCL-PEG. After 30 days of degradation, several structural changes were observed in the polymer blends, which were dependent on the level of PLCL-PEG addition. Blends with low PLCL-PEG content displayed enthalpy relaxation, resulting in embrittlement, while blends with high PLCL-PEG content displayed crystallisation, due to enhanced chain mobility brought on by chain scission, also causing embrittlement. Moderate PLCL-PEG additions (10% PLCL(70:30)-PEG and 20 - 30% PLCL(80:20)-PEG) stabilised the structure, reducing the extent of enthalpy relaxation and crystallisation and thus retaining ductility. Compositional optimisation identified a sweet spot for this blend strategy, whereby the ductility was enhanced while maintaining strength. Our results indicate that blending PLLA with PLCL-PEG provides an effective method of tuning the degradation timescale and mechanical properties of PLLA, and provides important new insight into the mechanisms of structural relaxations that occur during degradation, and strategies for regulating these., Comment: 17 pages, 11 figures

Published
2020
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6. Non-linear dissolution mechanisms of sodium calcium phosphate glasses as a function of pH in various aqueous media

Author

Oosterbeek, Reece N., Margaronis, Kalliope I., Zhang, Xiang C., Best, Serena M., and Cameron, Ruth E.

Subjects
Condensed Matter - Materials Science
Abstract

Phosphate glasses for bioresorbable implants display dissolution rates that vary significantly with composition, however currently their mechanisms of dissolution are not well understood. Based on this systematic study we present new insights into these mechanisms. Two-stage dissolution was observed, with time dependence initially parabolic and later linear, and a two-stage model was developed to describe this behaviour. Dissolution was accelerated by lower Ca concentration in the glass, and lower pH in the dissolution medium. A new dissolution mechanism is proposed, involving an initial stage where diffusion-controlled formation of a conversion layer occurs. Once the conversion layer is stabilised, layer dissolution reactions become rate-limiting. Under this mechanism the transition time is sensitive to the nature of the conversion layer and solution conditions. These results reveal the dependence of P$_{2}$O$_{5}$-CaO-Na$_{2}$O glass dissolution on solution pH, and provide new insight into the dissolution mechanisms, particularly regarding the transition between the two dissolution stages., Comment: 21 pages, 17 figures

Published
2020
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16. Structurally graduated collagen scaffolds applied to the ex vivo generation of platelets from human pluripotent stem cell-derived megakaryocytes: Enhancing production and purity

Author

Shepherd, Jennifer H., Howard, Daniel, Waller, Amie K., Foster, Holly Rebecca, Mueller, Annett, Moreau, Thomas, Evans, Amanda L., Arumugam, Meera, Bouët Chalon, Guénaëlle, Vriend, Eleonora, Davidenko, Natalia, Ghevaert, Cedric, Best, Serena M., and Cameron, Ruth E.

Published
2018
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22. Controlling the Architecture of Freeze-Dried Collagen Scaffolds with Ultrasound-Induced Nucleation.

Author

Song, Xinyuan, Philpott, Matthew A., Best, Serena M., and Cameron, Ruth E.

Subjects
BIOPOLYMERS, NUCLEATION, COLLAGEN, PORE size distribution, TISSUE engineering, ICE crystals
Abstract

Collagen is a naturally occurring polymer that can be freeze-dried to create 3D porous scaffold architectures for potential application in tissue engineering. The process comprises the freezing of water in an aqueous slurry followed by sublimation of the ice via a pre-determined temperature–pressure regime and these parameters determine the arrangement, shape and size of the ice crystals. However, ice nucleation is a stochastic process, and this has significant and inherent limitations on the ability to control scaffold structures both within and between the fabrication batches. In this paper, we demonstrate that it is possible to overcome the disadvantages of the stochastic process via the use of low-frequency ultrasound (40 kHz) to trigger nucleation, on-demand, in type I insoluble bovine collagen slurries. The application of ultrasound was found to define the nucleation temperature of collagen slurries, precisely tailoring the pore architecture and providing important new structural and mechanistic insights. The parameter space includes reduction in average pore size and narrowing of pore size distributions while maintaining the percolation diameter. A set of core principles are identified that highlight the huge potential of ultrasound to finely tune the scaffold architecture and revolutionise the reproducibility of the scaffold fabrication protocol. [ABSTRACT FROM AUTHOR]

Published
2024
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29. Evaluación In Vitro de Composites Basados en Quitosana e Hidroxiapatita

Author

Solís, Y., Davidenko, N., Carrodeguas, R. G., Cruz, J., Hernández, A., Cameron, Ruth E., Peniche, C., Folgueras Méndez, José, editor, Aznielle Rodríguez, Tania Y., editor, Calderón Marín, Carlos F., editor, Llanusa Ruiz, Susana Beatriz, editor, Castro Medina, Jorge, editor, Vega Vázquez, Haddid, editor, Carballo Barreda, Maylen, editor, and Rodríguez Rojas, Rafael, editor

Published
2013
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