George Pins
The overall objective of my research is to create bioengineered scaffolds to enhance the regeneration of damaged tissues and organs. Specifically, my laboratory uses biomimetic design strategies and novel fabrication processes to develop three-dimensional constructs that emulate native tissue architecture and cellular microenvironments. We use these scaffolds to characterize the roles of extracellular matrix (ECM) cues and topographic features in modulating cellular functions, including adhesion, migration, proliferation, differentiation, and tissue remodeling. For example, we are investigating the design of microfabricated basement membrane structures to direct keratinocyte function and enhance the performance of bioengineered skin substitutes. We are also designing novel biopolymer microthreads that are being used to deliver stem cells and to facilitate myocardial or skeletal muscle regeneration. These scaffolds have been used, as well, to develop in vitro model systems to predict cellular and tissue responses to implantable biomaterials for the repair of soft tissues including tendon and ligament.
In the classroom, I enjoy teaching students about the fundamentals of biomaterials science and cell-biomaterial interactions to design implantable biomaterials that promote functional tissue restoration. I particularly enjoying working with teams of students on capstone design projects to develop biomaterials scaffolds and benchtop assays to characterize cell-biomaterial interactions that can be used to solve clinical problems related to wound healing and tissue regeneration. At the graduate level, I enjoy mentoring master’s and doctoral students; helping them develop into independent scientists and engineers who will contribute to solutions of various healthcare problems.
George Pins
The overall objective of my research is to create bioengineered scaffolds to enhance the regeneration of damaged tissues and organs. Specifically, my laboratory uses biomimetic design strategies and novel fabrication processes to develop three-dimensional constructs that emulate native tissue architecture and cellular microenvironments. We use these scaffolds to characterize the roles of extracellular matrix (ECM) cues and topographic features in modulating cellular functions, including adhesion, migration, proliferation, differentiation, and tissue remodeling. For example, we are investigating the design of microfabricated basement membrane structures to direct keratinocyte function and enhance the performance of bioengineered skin substitutes. We are also designing novel biopolymer microthreads that are being used to deliver stem cells and to facilitate myocardial or skeletal muscle regeneration. These scaffolds have been used, as well, to develop in vitro model systems to predict cellular and tissue responses to implantable biomaterials for the repair of soft tissues including tendon and ligament.
In the classroom, I enjoy teaching students about the fundamentals of biomaterials science and cell-biomaterial interactions to design implantable biomaterials that promote functional tissue restoration. I particularly enjoying working with teams of students on capstone design projects to develop biomaterials scaffolds and benchtop assays to characterize cell-biomaterial interactions that can be used to solve clinical problems related to wound healing and tissue regeneration. At the graduate level, I enjoy mentoring master’s and doctoral students; helping them develop into independent scientists and engineers who will contribute to solutions of various healthcare problems.
Scholarly Work
Microfabrication of an analog of the basal lamina: biocompatible membranes with complex topographies. Pins GD, Toner M, Morgan JR. FASEB J. 2000 Mar;14(3):593-602. PMID: 10698975
Preparation and use of fibrin glue in surgery. Silver FH, Wang MC, Pins GD. Biomaterials. 1995 Aug;16(12):891-903. Review. PMID: 8562777
Preparation of fibrin glue: a study of chemical and physical methods. Silver FH, Wang MC, Pins GD. J Appl Biomater. 1995 Fall;6(3):175-83. PMID: 7492808
Cell growth on collagen: a review of tissue engineering using scaffolds containing extracellular matrix. Silver FH, Pins G. J Long Term Eff Med Implants. 1992;2(1):67-80. Review. PMID: 10171194
Patents