Enzyme Responsive Materials for Biology and Medicine
Lead Research Organisation:
University of Strathclyde
Department Name: Pure and Applied Chemistry
Abstract
This proposal is to develop new routes to rationally designed Enzyme Responsive Materials (ERMs) for biomedical applications. These materials can change properties, for example they can swell/collapse or change from a solution to a gel in response to biochemical reactions. These materials may have applications in the controlled release of drugs in response to disease specific enzymes. They may also be used in triggered assembly of matrixes for cell growth, with applications in tissue engineering. The outcomes of this project will be (i) the development and full characterisation of new interactive biomaterials, (ii) increased fundamental understanding of structure/function relationships in molecular hydrogels, (iii) proof of concept applications in enzyme triggered assembly of scaffolds for 3D cell culture and (iv) enzyme triggered drug delivery.
Organisations
People |
ORCID iD |
Rein Ulijn (Principal Investigator) |
Publications
Caponi P
(2011)
Phosphatase/temperature responsive poly(2-isopropyl-2-oxazoline)
in Polym. Chem.
Cousins B
(2009)
Enzyme-Activated Surfactants for Dispersion of Carbon Nanotubes
in Small
Das AK
(2009)
Evolving nanomaterials using enzyme-driven dynamic peptide libraries (eDPL).
in Faraday discussions
Hirst A
(2010)
Biocatalytic induction of supramolecular order
in Nature Chemistry
Hughes M
(2011)
Biocatalytic self-assembly of 2D peptide-based nanostructures
in Soft Matter
Javid N
(2011)
Supramolecular Structures of Enzyme Clusters.
in The journal of physical chemistry letters
Li Y
(2009)
A study of the dynamic interaction of surfactants with graphite and carbon nanotubes using Fmoc-amino acids as a model system.
in Langmuir : the ACS journal of surfaces and colloids
Thornton K
(2013)
Mechanistic insights into phosphatase triggered self-assembly including enhancement of biocatalytic conversion rate
in Soft Matter
Thornton K
(2009)
Controlling stiffness in nanostructured hydrogels produced by enzymatic dephosphorylation.
in Biochemical Society transactions
Description | - enzyme-responsive polymer hydrogels for controlled release of proteins. Developed methodology to match polymer functionality with protein payload. Developed two-photon microscopy to monitor controlled release. - demonstrated ability to control and direct supramolecular self-assembly under kinetic control using enzymatic reactions to direct the assembly. |
Exploitation Route | Our biocatalytic self-assembly approaches are now applied in development of new therapeutics where disease specific enzymes trigger release of therapeutics. |
Sectors | Chemicals |
URL | http://www.ulijnlab.com |