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All Outputs (3)

Bacterial Attachment to Polymeric Materials Correlates with Molecular Flexibility and Hydrophilicity (2014)
Journal Article
Sanni, O., Chang, C., Anderson, D. G., Langer, R., Davies, M. C., Williams, P. M., …Hook, A. L. (2015). Bacterial Attachment to Polymeric Materials Correlates with Molecular Flexibility and Hydrophilicity. Advanced Healthcare Materials, 4(5), 695-701. https://doi.org/10.1002/adhm.201400648

A new class of material resistant to bacterial attachment has been discovered that is formed from polyacrylates with hydrocarbon pendant groups. In this study, the relationship between the nature of the hydrocarbon moiety and resistance to bacteria i... Read More about Bacterial Attachment to Polymeric Materials Correlates with Molecular Flexibility and Hydrophilicity.

High throughput screening for biomaterials discovery (2014)
Journal Article
Algahtani, M. S., Alexander, M., Scurr, D. J., Hook, A. L., Anderson, D. G., Langer, R. S., …Davies, M. C. (2014). High throughput screening for biomaterials discovery. Journal of Controlled Release, 190, 115-126. https://doi.org/10.1016/j.jconrel.2014.06.045

Using microarray technologies thousands of biomedical materials can be screened in a rapid, parallel and cost effective fashion to identify the optimum candidate that fulfils a specific biomedical application. High throughput surface characterization... Read More about High throughput screening for biomaterials discovery.

Thermally Switchable Polymers Achieve Controlled Escherichia coli Detachment (2014)
Journal Article
Hook, A. L., Chang, C., Scurr, D. J., Langer, R., Anderson, D. G., Williams, P., …Alexander, M. R. (2014). Thermally Switchable Polymers Achieve Controlled Escherichia coli Detachment. Advanced Healthcare Materials, 3(7), 1020-1025. https://doi.org/10.1002/adhm.201300518

The thermally triggered release of up to 96% of attached uropathogenic E. coli is achieved on two polymers with opposite changes in surface wettability upon reduction in temperature. This demonstrates that the bacterial attachment to a surface cannot... Read More about Thermally Switchable Polymers Achieve Controlled Escherichia coli Detachment.