Abstract
Invention Summary: The evolution of in vitro-engineered scaffold-free tissues for tissue modeling and regenerative medicine has been driven by the need to recapitulate the cellular organization of endogenous tissues and to avoid undesired scaffold-related side effects upon implantation. Methods to produce scaffold-free tissue or cell assemblies have been recently explored with the use of membrane modifications, spheroid-based 3D bio-printing and thermo-responsive polymers. However, cell assemblies or tissue generated by these methods lack proper spatial control, mechanical robustness and are limited to a few specific cell types. Rutgers scientists have developed a new method of arranging scaffold-free cell/protein assemblies for tissue modeling and regeneration. This path-breaking invention facilitates the in vitro generation of cell/protein assemblies that recapitulate endogenous tissues. Such assemblies can be readily implanted at the site of disease or tissue injuries; the absence of scaffold allows these in vivo applications with reduced side effects. In a proof-of-concept study, it has been demonstrated that a scaffold-free cell assembly created by this method leads to precision wound modeling and accelerated skin wound healing in a diabetic animal model. Advantages: Scaffold-free cell and protein assemblies for cell replacement therapy and in vitro modeling of tissue function and response to therapeutics Market Applications: Large-scale 3D cell assembly Precision multi-cellular patterning Tissue-like high cell density High robustness for long-term maintenance Applicable for unlimited cell types Scaffold-free (no side-effects from biomaterials) Excellent for in vitro laboratory research and cell transplantation into humans Intellectual Property & Development Status: Patent pending. Available for licensing and/or collaboration.
Original language | American English |
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State | Published - Aug 2019 |
Externally published | Yes |