prof jonathan knowles
- UCL Eastman Dental Institute
- 256 Grays Inn Road
- WC1X 8LD
- Professor of Biomaterials Science
- Biomaterials & Tissue Eng
- Eastman Dental Institute
My academic strengths lie in my research. This is reflected in my ranking of 473/3936 (as of 11/05/12) in the scientist rankings for Materials Science. This also places me as the highest ranked Materials Scientist in UCL with over 4500 citations and an H-index of 37. I have for the past 15 years pursued the development of novel materials for hard and soft tissue regeneration.
A significant proportion of my work focusses on soluble glasses and is proving very successful and has attracted a significant amount of sponsorship from the research councils (BBSRC and EPSRC and MRC) and also industrially. The work has made some significant contributions to the understanding of the materials and in particular the degradation processes where the current view in the literature has been shown to incompletely model the degradation process occurring. This has important consequences if the material is to be used in vivo. The work has also developed the materials as novel antibacterial agents using copper and silver as potential antibacterial ions. The work has shown that whilst very high levels of the ions may be released, the bacteria which form colonies are able to form sacrificial layers to inhibit ion release. Recent work funded with two large grants by the EPSRC and collaboration with the Universities of Kent and Warwick has seen further developments of the glasses in sol-gel form and also applied a largoe portfolio of high end techniques such as NMR and neutron diffraction. This work has had an unprecedented output with almost 50 papers in three years and this includes some of the highest impact factor papers, including Advanced Materials and Advanced Functional Materials.
- Craniofacial development and muscle regeneration
- Development of new injectable adhesive composites for bone repair
- Materials for hard and soft tissue regneration
- The effect of different implant-abutment connection geometry and abutment alloy on corrosion product release and cell response
Biospectroscopy of Nanodiamond-Induced Alterations in Conformation of Intra- and Extracellular Proteins: A Nanoscale IR Study.
Novel poly(3-hydroxybutyrate) composite films containing bioactive glass nanoparticles for wound healing applications
Development of dental composites with reactive fillers that promote precipitation of antibacterial-hydroxyapatite layers
Titanium phosphate glass microcarriers induce enhanced osteogenic cell proliferation and human mesenchymal stem cell protein expression.
Sol-gel synthesis of quaternary (P2O5)(55)-(CaO)(25)-(Na2O)((20-x))-(TiO2)(x) bioresorbable glasses for bone tissue engineering applications (x=0, 5, 10, or 15)
Enabling Consistency in Pluripotent Stern Cell-Derived Products for Research and Development and Clinical Applications Through Material Standards
Feasibility of silica-hybridized collagen hydrogels as three-dimensional cell matrices for hard tissue engineering
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- Atomic force microscopy
- Cell culture
- Craniofacial disease
- Glass melting
- Image analysis
- Materials science
- Thermal analysis
- X-ray diffraction
- degradable materials
- dr dave spratt
- dr peter brett
- prof anne young
- dr lambis petridis
- prof nigel hunt
- prof jawwad darr
- Juha-Pekka Nuutinen