- J. Andrysek
- J. Audet
- B.L. Bardakjian
- E. Biddiss
- W. Chan
- T. Chau
- J.E. Davies
- A.C. Easty
- M. Eizenman
- R. Fernandez-Gonzalez
- G.R. Fernie
- P.M. Gilbert
- M.D. Grynpas
- R.A. Kandel
- D. Kilkenny
- O. Levi
- K. Masani
- A. McGuigan
- A. Mihailidis
- M.K. Nagai
- M.R. Popovic
- M. Radisic
- J. Rocheleau
- J.P. Santerre
- M.V. Sefton
- M.S. Shoichet
- C.A. Simmons
- E.D. Sone
- D.A. Steinman
- P. Trbovich
- K. Truong
- A. Wheeler
- W. Wong
- C.M. Yip
- P. Yoo
- L. You
- P. Zandstra
- J. Zariffa
- Institute of Biomaterials & Biomedical Engineering
- Associate Director, Research, Institute of Biomaterials & Biomedical Engineering
- Department of Chemical Engineering & Applied Chemistry
- Department of Chemistry
- Faculty of Medicine, Program in Neuroscience
- Canada Research Chair in Tissue Engineering
LAB: CCBR 5th Floor
ADDRESS: Department of Chemistry
Department of Chemical Engineering & Applied Chemistry,
University of Toronto
160 College Street
Toronto, Ontario, Canada M5S 3G9
Tel: (416) 978-1460
Fax: (416) 978-4317
Our research program requires a cross disciplinary approach where aspects of engineering, chemistry, and biology are applied to the field of Tissue Engineering. We are focussed on enhancing the cell-material interaction through controlled polymer chemistry and engineering. The defining characteristic of neurodegenerative diseases, such as spinal cord injury, is the inability of injured nerve cells to repair themselves or regrow. The consequences of spinal cord injury are devastating, resulting in dramatically reduced communication between the brain and the periphery. In bridging polymer science and neuroscience, we are designing a nerve regeneration system that combines polymer synthesis/processing, drug delivery and surface modification. Specifically, we are investigating different methods of enhancing and guiding nerve regeneration and incorporating these methods into devices for in vivo investigations.
Creation of Scaffolds: Polymeric hollow fiber membranes (i.e. porous tubes) have been synthesized using a novel technique that combines centrifugal forces with polymerization. The methodology allows us to create HFMs with the mechanical and transport properties required for implantation into either the peripheral or central nervous systems.
To enhance regeneration within the HFMs, we are investigating haptotactic and chemotactic cues of regeneration. Haptotactic cues involve polymer surface/bulk modification with cell adhesive peptides. Chemotactic cues involve guiding axons with concentration gradients of neurotrophic factors.
Polymer Synthesis: Many polymers used in medicine were originally designed for other applications. We are designing and synthesizing both biostable and biodegradable polymers. The latter are polycarbonates and are being investigated for drug delivery, scaffold synthesis and peptide modification.
Novel fluoropolymers are being synthesized, incorporating a pendant hydroxyl group for further modification and an ether group for enhanced solubility in organic solvents. This synthetic approach dramatically improves the solubility and workability of fluoropolymers which are currently difficult to handle. The composition, mechanical and structural properties of the fluoropolymers are being investigated for use in coatings applications.
Bone Tissue Engineering Three-dimensional biodegradable scaffolds have been prepared with a macroporous geometry that is conducive to bone cell distribution and tissue formation throughout the scaffold, both in vitro and in vivo. Current research is focussed at the cell-polymer interface (collaboration with JE Davies).
Kang CE, Baumann MD, Tator CH, Shoichet MS. Localized and sustained delivery of fibroblast growth factor-2 from a nanoparticle-hydrogel composite for treatment of spinal cord injury. Cells Tissues Organs. 2013. 197(1):55-63.
Wood MD, Gordon T, Kim H, Szynkaruk M, Phua P, Lafontaine C, Kemp SW, Shoichet MS, Borschel GH. Fibrin gels containing GDNF microspheres increase axonal regeneration after delayed peripheral nerve repair.Regen Med. 2013 Jan. 8(1):27-37.
Tam, R.Y., Cooke, M.J., and Shoichet, M.S. A covalently modified hydrogel blend of hyaluronan-methyl cellulose with peptides and growth factors influences neural stem/progenitor cell fate. Journal of Materials Chemistry, 22: 19402-11, 2012.
Owen, S.C., Doak, A.K., Wassam, P., Shoichet, M.S., and Shoichet, B.K. Colloidal aggregation affects the efficacy of anticancer drugs in cell culture. ACS Chemical Biology, 7: 1429-35, 2012.
Aizawa, Y. and Shoichet, M.S. The role of endothelial cells in the retinal stem and progenitor cell niche within a 3D engineered hydrogel matrix. Biomaterials, 33: 5198-205, 2012.
Vulic, K. and Shoichet, M.S. Tunable growth factor delivery from injectable hydrogels for tissue engineering. Journal of the American Chemical Society, 134: 882-85, 2012
Caicco MJ, Zahir T, Mothe AJ, Ballios BG, Kihm AJ, Tator CH, Shoichet MS. Characterization of hyaluronan-methylcellulose hydrogels for cell delivery to the injured spinal cord.
J Biomed Mater Res A. 2012 Nov 5.
Silva NA, Cooke MJ, Tam RY, Sousa N, Salgado AJ, Reis RL, Shoichet MS. The effects of peptide modified gellan gum and olfactory ensheathing glia cells on neural stem/progenitor cell fate. Biomaterials. 2012 Sep. 33(27):6345-54.
Stanwick JC, Baumann MD, Shoichet MS. Enhanced neurotrophin-3 bioactivity and release from a nanoparticle-loaded composite hydrogel J Control Release. 2012 Jun 28, 160(3):666-75.
Wylie, R.G., Ahsan, S., Aizawa, Y., Maxwell, K.L., Morshead, C.M., and Shoichet, M.S. Spatially controlled simultaneous patterning of multiple growth factors in three-dimensional hydrogels. Nature Materials, 10: 799-806, 2011.
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