I gained a BSc (Hons) degree in Applied Zoology at the University of Leeds in 1987 and MSc (Biomolecular Organization; 1990) and PhD (Medicine/Pathology; 1996) degrees at the University of London. Prior to moving to Nottingham in 2003, I was based largely at the former Royal Postgraduate Medical School, now part of Imperial College London working with late Professor Dame Julia Polak. My PhD focussed on investigating the distributions and possible functions of nitric oxide/nitric oxide synthases in the physiology and pathology of a variety of tissues and organs and I was fortunate enough to publish some of the first papers on the involvement of these molecules in human diseases, notably in the cardiovascular system.
My first postdoctoral position was held jointly between Imperial College and the Royal London Hospital School of Medicine and Dentistry looking at the roles of the nitric oxide and prostaglandin pathways in bone biology, specifically the osteoblast.
I returned full time to Imperial College in 1999 to take up a lectureship in cell biology and tissue engineering and was also actively involved in establishing the Tissue Engineering Centre. From 1999 onwards my research has been focused primarily on osteoblast biology and approaches to tissue engineer and repair damaged bones. At this time I also began working with mouse and human embryonic stem cells resulting in the publication of some of the first papers describing the osteogenic differentiation of mouse ES and human cells in vitro and in vivo.
In 2003 I moved to the University Nottingham and the School of Pharmacy. I am also affiliated with the Wolfson Centre for Stem Cells, Tissue Engineering and Modelling (STEM), which is also part of the Centre for Biomolecular Sciences. My research continues to focus on stem cells and osteoblasts and in particular 3D cell culture models and microenvironments. I work on various biochemical and biophysical approaches to investigate and control cell-cell, cell-scaffold interactions.
Teaching Director of Undergraduate Admissions/ Admissions Tutor. (Previously senior tutor and member of Teaching Committee)
MPharm - Basic cell biology and pharmaceutical microbiology (Essential Skills for Pharmacists; Bacterial and Fungal Infections, Future Medicines modules)
MSci Pharmaceutical Sciences - Basic cell biology (Cardiovascular and Haematology module)
Co-ordinator (Nottingham) of EPSRC/MRC CDT in Regenerative Medicine http://www.dtcregen-med.com/
Histology, immunocytochemistry, general cell biology, 2D and 3D cell culture (including embryonic stem cell, mesenchymal stem cells and primary tissue-derived cells), holographic optical tweezers (for cell biology)
I teach on the Master of Pharmacy (MPharm) and Master of Science Pharmaceutical Sciences course. I cover mainly cell biology and physiology.
Year 1. Essential Skills for Pharmacists, Being a Pharmacist, Bacterial and Fungal Infections
Year 3. Research Project
Year 4 Future Medicines
Modules MSci Pharm Sci:
Year 1. Cardiovascular and Haematology
Basic cell biology (structure and organization of the cell and biological macromolecules)
Pharmaceutical microbiology -bacterial pathogens, pathogenesis of bacterial infections, infection control and management
Stem cell biology - basics of stem cell sources/origins, self-renewal and differentiation
Tissue engineering and regenerative medicine
I am also UG Admissions Tutor to the School of Pharmacy and coordinate recruitment activities and selection of candidates
My research interests focus mainly on stem cells (embryonic, 'adult' and fetal origins) and their applications in tissue engineering, particularly the osteoblast and bone tissue. I am involved in a… read more
MORRIS, S.A., GREWAL, S., BARRIOS, F., PATANKAR, S.N., STRAUSS, B., BUTTERY, L., ALEXANDER, M., SHAKESHEFF, K.M. and ZERNICKA-GOETZ, M., 2012. Dynamics of anterior-posterior axis formation in the developing mouse embryo Nature Communications. 3, 673 PASCUT, F.C., GOH, H.T., WELCH, N., BUTTERY, L.D., DENNING, C. and NOTINGHER, I., 2011. Noninvasive detection and imaging of molecular markers in live cardiomyocytes derived from human embryonic stem cells Biophysical Journal. 100(1), 251-259 LANNIEL, M., LU, B., CHEN, Y., ALLEN, S., BUTTERY, L., WILLIAMS, P., HUQ, E. and ALEXANDER, M., 2011. Patterning the mechanical properties of hydrogen silsesquioxane films using electron beam irradiation for application in mechano cell guidance THIN SOLID FILMS. VOL 519(NUMBER 6), 2003-2010
MAHLSTEDT, M.M., ANDERSON, D., SHARP, J.S., MCGILVRAY, R., MUÑOZ, M.D., BUTTERY, L.D., ALEXANDER, M.R., ROSE, F.R.A.J. and DENNING, C., 2010. Maintenance of pluripotency in human embryonic stem cells cultured on a synthetic substrate in conditioned medium Biotechnology and Bioengineering. 105(1), 130-140
My research interests focus mainly on stem cells (embryonic, 'adult' and fetal origins) and their applications in tissue engineering, particularly the osteoblast and bone tissue. I am involved in a number of projects to investigate the influence of 3-D cell-cell, cell-scaffold/matrix interactions and angiogenesis / vasoreactivity on the induction and control of stem cell differentiation.
I also work with optical tweezers to precisely position stem cells to simulate/recreate the stem cell niche and probe the role of cell-cell, cell-cytokine and cell-scaffold interactions in controlling stem cell potency and differentiation.
Other projects and interests include tissue engineering of human bronchiolar tissue
Notable collaborations/collaborators include;
Professor Morgan Alexander (Nottingham) - cell-materials interactions
Professor Amir Ghaemmaghami (Nottingham) - osteoblast-macrophage interactions
Professor Miles Padgett (University of Glasgow) - optical tweezers
Professor Magda Zernicka-Goetz (Cambridge University) - early embryo development
Professor Matthew Dalby (University of Glasgow) - osteoblasts and cell mechanics/signalizing
Worked for 11 years at the Royal Postgraduate Medical School/Imperial College in cell pathology and in particular investigation of the contribution of nitric oxide and nitric oxide synthases to disease processes including human atherosclerosis, sepsis and more latterly bone damage/turnover.
3D in vitro model of bone fracture callus - focus on osteoblast-macrophage interactions
Building 3D microenvironments to study early embryogenesis