21 People Results for the Tag: Biomaterial
Huck Chair in Biomimetic Materials; Pearce Professor of Engineering
Prof. Dr. Melik Demirel holds a tenured professor position in engineering at Penn State, and has a decade of experience in biosensors and nanomaterials. Prof. Demirel’s achievements have been recognized, in part, through his receipt of a Young Investigator Award, an Alexander von Humboldt Fellowship, an Institute for Complex Adaptive Matter Junior Fellowship, the Pearce Development Professorship at Penn State, a Boeing Distinguished Speaker Award. Prof. Demirel received his Ph.D. from Carnegine Mellon University and B.S. and M.S. degrees from Bogazici University.
Director, Huck Institutes of the Life Sciences; Evan Pugh Professor of Biology and Entomology; Eberly Professor of Biotechnology
The ecology and evolutionary genetics of infectious disease.
Center for Infectious Disease Dynamics
Huck Chair in Regenerative Engineering; Professor of Biomedical Engineering
Development of new biodegradable polymers for use in engineering elastic tissues such as blood vessel, tendon, ligament, and cardiac tissue, and in other applications such as biological labeling, bioimaging and drug delivery.
Professor of Biochemistry and Molecular Biology
Structural and functional basis of cellulose synthesis. Using Physcomitrella patens and other organisms as model systems, we are learning how plants make cellulose for building new cell wall. The studies use methods of molecular biology and cryoEM to characterize the enzyme as a monomer, and when it assembles into its larger 'Cellulose Synthase Complex '(CSC for short). The aim is to understand cellulose synthesis to explain fundamentals of cell wall biology in plants, and to enable manipulation of its synthesis for applications in fields of bioenergy and materials.
Co-Director, Center for Biorenewables; Associate Professor of Biology
In vivo imaging of plant cell wall dynamics. Molecular genetic analysis of genes involved in cell growth. Cell wall biosynthesis in dividing cells. Cell wall engineering for sustainable bioenergy production.
Associate Professor of Bioengineering
Understanding the fundamental mechanisms by which biomaterial interfaces alter the proliferation, migration and differentiation of mesenchymal stem cells, and application of these principles in the intelligent design of biomaterial scaffolds that facilitate generation or regeneration of musculoskeletal tissues
Professor of Biomedical Engineering
Applying nature and biology as design guidelines to the creation of biomimetic and bioinspired materials at both the nanoscale and macroscale level for drug delivery, clinical diagnosis, and regenerative medicine.
Center for Infectious Disease Dynamics
Director, Center of Excellence in Industrial Biotechnology; Huck Chair in Nanotherapeutics and Regenerative Medicine; Professor of Biomedical Engineering
Biomaterials engineering for applications ranging from regenerative medicine to lab-on-a-chip technologies. An emphasis on nanomaterials, macromolecules and composite structures. Ongoing efforts include development of optically and magnetically modulated drug delivery systems, quasi 3D cell sheet culture systems, cell encapsulation and delivery materials and hybrid in situ polymerizing grafts/augments.
Associate Professor of Biomedical Engineering
Design of bio-inspired functional materials that serve as new tools in precision medicine. Understanding how peptides and proteins assemble at natural and non-natural interfaces to form organized structures with unique biochemical functions. The design of nano- and micro-scale biomaterials to develop new biosensing and therapeutic strategies to treat infectious disease, inflammation and cancer.
Assistant Professor of Bioengineering
Mechanobiology focusing on how mechanical stimuli influence tendon cell behavior in their native microenvironment with the ultimate goal of understanding tendon pathology and identifying novel therapeutic options.
Assistant Professor of Chemical Engineering
Micro- and nanoengineered soft materials for medicine and the environment; microfluidic-enabled biomaterials for tissue engineering and regeneration; living materials; next-generation bioadhesives, tissue sealants, and hemostatic agents; hydrogels for minimally invasive medical technologies; self-healing and adaptable soft materials; smart coatings; hairy nanocelluloses as an emerging family of advanced materials.
Associate Professor of Chemical Engineering and Biomedical Engineering
How the interplay of chemical and mechanical signals acts to control cell behavior and function and the progression of disease.