Matthew Baker,
Assistant Professor, MERLN Institute,
Maastricht University
Matt Baker's research interests include the synthesis and characterization of novel and dynamic materials to mimic the cellular environment and to create advanced soft materials. Of particular interest is the use of reversible supramolecular interactions (e.g. host-guest, supramolecular polymers, hydrogen bonding) to build these materials and the use of mechanochemistry to influence a material’s properties and living systems. Matt received his B.S. in chemistry (2006) at Clemson University in the United States and worked shortly for Tetramer Technologies, LLC, a start-up company commercializing novel fluoropolymers developed at Clemson University. He obtained his PhD in 2012 in Physical Organic Chemistry under the guidance of Ronald K. Castellano at the University of Florida and then moved to Eindhoven University of Technology to design and characterize water soluble supramolecular polymers under guidance of Prof. E. W. Meijer. In 2015, Matt joined the MERLN institute as a researcher, while also starting a group to explore the utility of dynamic interactions in biomaterials. In 2017, he was promoted to Assistant Professor, founding a group to rationally design, synthesize, and characterize biomaterials based around stimuli-responsive and dynamic interactions. Currently, he serves as the group’s biggest fan, and aims to train scientists at the interface of Chemistry and Bioengineering. The work of the group has been recognized by the American Chemical Society with our lab being named a 2021 PMSE Young Investigator.
Development of New Polymers for Biofabrication: Hydrogels For 3D Printing and Resins for DLP
Friday, 8 June 2018 at 14:00
Add to Calendar ▼2018-06-08 14:00:002018-06-08 15:00:00Europe/LondonDevelopment of New Polymers for Biofabrication: Hydrogels For 3D Printing and Resins for DLPBioprinting and 3D-Printing in the Life Sciences EU 2018 in Rotterdam, The NetherlandsRotterdam, The NetherlandsSELECTBIOenquiries@selectbiosciences.com
Biofabrication methods provide great potential to go beyond 2D tissue engineering towards 3D functional tissues and organs for application in regenerative medicine strategies. However, despite this promise, the library of materials suitable for fabrication strategies remains relatively small and poorly customizable. Towards expanding the materials and strategies for biofabrication, two examples of customized polymers will be presented. Firstly, in order to facilitate 3D bioprinting of cell laden constructs, we have recently developed a synthetically modified alginate based “bioink” that can support cell growth, proliferation, and the extrusion based fabrication of 3D structures via light activated thiol-ene conjugations. This hydrogel’s material properties can be rationally tuned and can support the creation of constructs with multifunctional bioactive cues. Secondly, a simple example of customized resins for digital light processing (DLP) of culture environments and biofabricated objects will be presented. These poly(ester)urethane acrylate resins provide control over the mechanical properties and cell adhesion of the fabricated construct, while allowing high-fidelity feature production. Both platforms presented are developed towards the future creation of dynamic and stimuli-responsive 3D constructs aimed at investigating the effect of material and construct dynamics on engineered tissues.
Add to Calendar ▼2018-06-07 00:00:002018-06-08 00:00:00Europe/LondonBioprinting and 3D-Printing in the Life Sciences EU 2018Bioprinting and 3D-Printing in the Life Sciences EU 2018 in Rotterdam, The NetherlandsRotterdam, The NetherlandsSELECTBIOenquiries@selectbiosciences.com
Add to Calendar ▼2018-06-08 14:00:002018-06-08 15:00:00Europe/LondonDevelopment of New Polymers for Biofabrication: Hydrogels For 3D Printing and Resins for DLPBioprinting and 3D-Printing in the Life Sciences EU 2018 in Rotterdam, The NetherlandsRotterdam, The NetherlandsSELECTBIOenquiries@selectbiosciences.com
