PhD Studentship: Dynamic Colon Model – An In Vitro Approach To Drug Delivery And Treatment For The Large Intestine.
Health and Medical,Pharmacology, Toxicology and Pharmacy,Engineering and Technology,Chemical Engineering
Short info about job
Company: University of Birmingham
Department: School of Chemical Engineering
Hours: Full Time
Type / Role: PhD
Phone: +44-1252 7880462
Fax: +44-1343 1276306
E-mail: N\A
Site: N\A
Detail information about job PhD Studentship: Dynamic Colon Model – An In Vitro Approach To Drug Delivery And Treatment For The Large Intestine.. Terms and conditions vacancy
Supervisors: Prof Mark Simmons [Chemical Engineering], Dr Hannah Batchelor [Pharmacy], University of Birmingham, Dr Kostas Stamatopoulos [Simcyp Ltd-Certara].
Industrial Partners: AstraZeneca, Pfizer
Funding: EPSRC stipend and H/EU fees paid plus industry contribution
There is a pressing need for physiologically relevant gastrointestinal models which can inform disease treatment and clinical practice in humans. This PhD project will explore the use of a recently developed in vitro model of the colon to obtain phenomenological understanding of drug delivery. This work has generated both scientific and media interest, with invited talks at UKPharmSci in Hertfordshire [2014]; Pharmaceutical World Meeting in Glasgow [2016] and an interview on the BBC Radio 4 “Inside Science” programme [http://www.bbc.co.uk/programmes/b0713p30]. Reproduction of observed motility measurements in the human colon will increase our understanding of the physiology and pathophysiology of the gastrointestinal tract; thus providing a foundation for the generation of innovative drug formulations that target and treat digestive diseases.
The work will involve both fluid mechanical and concentration based measurements to understand the delivery of different dosage forms for a range of colon motility patterns. The project is multidisciplinary with input from both Chemical Engineering [Simmons] and Pharmacy [Batchelor] as well as industry, with the ultimate aim of producing in vitro models which can aid the design of drug dosage forms and ultimately improve clinical practice and treatments. This model will act as a bridge to an in silico platform and Physiological Based Pharmacokinetic [PBPK] models, enabling the testing and predicting of novel drug delivery systems for topical and systemic treatment, as well as having applications in research and teaching for physiologists, medical practitioners and pharmaceutical scientists.
This project would be available to a UK/EU applicant with a degree in chemical engineering or pharmacy, or a related discipline 2i or above. Informal enquiries can be made to Professor Mark Simmons [email protected].