Nanofibres in Drug Delivery
Gareth R. Williams, Bahijja T. Raimi-Abraham and C. J. Luo | September 2018
Open Access PDF
About the book
In recent years there has been an explosion of interest in the production of nanoscale fibres for drug delivery and tissue engineering. Nanofibres in Drug Delivery aims to outline to new researchers in the field the utility of nanofibres in drug delivery, and to explain to them how to prepare fibres in the laboratory.
The book begins with a brief discussion of the main concepts in pharmaceutical science. The authors then introduce the key techniques that can be used for fibre production and explain briefly the theory behind them. They discuss the experimental implementation of fibre production, starting with the simplest possible set-up and then moving on to consider more complex arrangements. As they do so, they offer advice from their own experience of fibre production, and use examples from current literature to show how each particular type of fibres can be applied to drug delivery. They also consider how fibre production could be moved beyond the research laboratory into industry, discussing regulatory and scale-up aspects.
About the author
Gareth R. Williams joined the UCL School of Pharmacy in 2012. His research group work on a range of topics in drug delivery and vaccine formulation, with a particular emphasis on the use of electrohydrodynamic approaches to develop solid dispersions. He was awarded Fellowship of the Royal Society of Chemistry in 2017.
Bahijja T. Raimi-Abraham graduated with a PhD in 2012 from the University of East Anglia School of Pharmacy and is a registered and practising pharmacist. She went on to undertake postdoctoral research funded by the Engineering and Physical Sciences Research Council at the UCL School of Pharmacy, before joining King’s College London as a lecturer in 2017.
C. J. Luo graduated from UCL in 2012 with a PhD in Biomedical Engineering. She took up a postdoctoral position at the University of Cambridge in 2013 before returning to UCL in 2016. Her current research is funded by the Engineering and Physical Sciences Research Council.