Dr. Aidun joined the Woodruff School as a Professor in 2003 after completion of a two-year period as program director at the National Science Foundation. He began at Tech in 1988 as an Assistant Professor at the Institute of Paper Science and Technology. Prior, he was a research Scientist at Battelle Research Laboratories, Postdoctoral Associate at Cornell University and Senior Research Consultant at the National Science Foundation's Supercomputer Center at Cornell. 

Dr. Aidun's research is at the intersection between fundamentals of the physics of complex fluids/thermal transport and applications to engineering and biotransport. He has a diverse research portfolio in fluid mechanics, bioengineering, renewable bioproducts and decarbonization of industrial processes. 

A major focus has been to understand the physics of blood cell transport and interaction with glycoproteins (e.g., vWF) with applications to cardiovascular diseases.

Saad Bhamla studies biomechanics across species to engineer knowledge and tools that inspire curiosity.

Saad Bhamla is an assistant professor of biomolecular engineering at Georgia Tech. A self-proclaimed "tinkerer," his lab is a trove of discoveries and inventions that span biology, physics and engineering. His current projects include studying the hydrodynamics of insect urine, worm blob locomotion and ultra-low-cost devices for global health. His work has appeared in the New York Times, the Economist, CNN, Wired, NPR, the Wall Street Journal and more.

Saad is a prolific inventor and his most notable inventions includes a 20-cent paper centrifuge, a 23-cent electroporator, and the 96-cent hearing aid. Saad's work is recognised by numerous awards including a NIH R35 Outstanding Investigator Award, NSF CAREER Award, CTL/BP Junior Faculty Teaching Excellence Award, and INDEX: Design to Improve Life Award. Saad is also a National Geographic Explorer and a TED speaker. Newsweek recognized Saad as 1 of 10 Innovators disrupting healthcare.

Saad is a co-founder of Piezo Therapeutics.

Outside of the lab, Saad loves to go hiking with his partner and two dogs (Ollie and Bella).

The Curtis lab is primarily focused on the physics of cell-cell and cell-extracellular matrix interactions, in particular within the context of glycobiology and immunobiology. Our newest projects focus on questions of collective and single cell migration in vitro and in vivo; immunophage therapy "an immunoengineering approach - that uses combined defense of immune cells plus viruses (phage) to overcome bacterial infections"; and the study of the molecular biophysics and biomaterials applications of the incredible enzyme, hyaluronan synthase. A few common scientific themes emerge frequently in our projects: biophysics at interfaces, the use of quantitative modeling, collective interactions of cells and/or molecules, cell mechanics, cell motility and adhesion, and in many cases, the role of bulky sugars in facilitating cell integration and rearrangements in tissues.

Vinny is an Assistant Professor at Georgia Tech with joint appointments at the School of Chemistry and Biochemistry and School of Biological Sciences.

A majority of antibiotics and drugs that we use in the clinic are derived or inspired from small organic molecules called Natural Products that are produced by living organisms such as bacteria and plants. Natural Products are at the forefront of fighting the global epidemic of antibiotic resistant pathogens, and keeping the inventory of clinically applicable pharmaceuticals stocked up. Some Natural Products are also potent human toxins and pollutants, and we need to understand how these toxins are produced to minimize our and the environmental exposure to them.

We as biochemists ask some simple questions- how and why are Natural Products produced in Nature, what we can learn from Natural Product biosynthetic processes, and how we can exploit Nature's synthetic capabilities for interesting applications?

Broadly, we are interested in questions involving (meta)genomics, biochemistry, structural and mechanistic enzymology, mass spectrometry, analytical chemistry, and how natural product chemistry dictates biology.

Craig Forest is a Professor and Woodruff Faculty Fellow in the George W. Woodruff School of Mechanical Engineering at Georgia Tech where he also holds program faculty positions in Bioengineering and Biomedical Engineering. He conducts research on miniaturized, high-throughput robotic instrumentation to advance neuroscience and genetic science, working at the intersection of bioMEMS, precision machine design, optics, and microfabrication. Prior to Georgia Tech, he was a research fellow in Genetics at Harvard Medical School. He obtained a Ph.D. in Mechanical Engineering from MIT in June 2007, M.S. in Mechanical Engineering from MIT in 2003, and B.S. in Mechanical Engineering from Georgia Tech in 2001. He is cofounder/organizer of one of the largest undergraduate invention competitions in the US—The InVenture Prize, and founder/organizer of one of the largest student-run makerspaces in the US—The Invention Studio. He was a recently a Fellow in residence at the Allen Insitutte for Brain Science in Seattle WA; he was awarded the Georgia Tech Institute for BioEngineering and BioSciences Junior Faculty Award (2010) and was named Engineer of the Year in Education for the state of Georgia (2013). He is one of the inaugural recipients of the NIH BRAIN Initiative Grants, a national effort to invent the next generation of neuroscience and neuroengineering tools. In 2007, he was a finalist on the ABC reality TV show "American Inventor.”

Itamar Kolvin received his B.Sc. (2007) in Physics and Mathematics and his M.Sc. (2009) from the Hebrew University in Jerusalem. In 2017, he completed his Ph.D. in Physics under Prof. Jay Fineberg in the Hebrew University. He was a HFSP cross-disciplinary postdoctoral fellow in the Physics Department, University of California, Santa Barbara with Pro. Zvonimir Dogic. His research interests are in the fundamentals of soft matter out-of-equilibrium: assembly, deformation, flow and fracture. Current efforts make use of model systems that are assembled of protein machineries to investigate active and adaptive material mechanics. 

Peter Kasson is an international leader in the study of biological membrane structure, dynamics, and fusion, with particular application to how viruses gain entry to cells. His group performs both high-level experimental and computational work – a powerful combination that is critical to advancing our understanding of this important problem. His publications describe inventive approaches to the measurement of viral fusion rates and characterization of fusion mechanisms, and to the modeling of large-scale biomolecular and lipid assemblies. He has applied these insights to the prediction of pandemic outbreaks and drug resistance, with particular attention to Zika, SARS-CoV-2, and influenza pathogens in recent years. See https://kassonlab.org/ for more information.

Dr. Aditya Kumar is an Assistant Professor in the School of Civil and Environmental Engineering at the Georgia Institute of Technology. Previously, he was a Postdoctoral Researcher in Aerospace Engineering at the University of Illinois at Urbana-Champaign. He received his bachelor’s degree from the Indian Institute of Technology, Delhi, and his doctorate from Illinois.

Dr. Kumar’s main area of research is mechanics and physics of soft materials. Specifically, his research group develops mathematical theories and their computational implementation to study fundamental problems in materials like elastomers, adhesives, and biological tissues. Recent work includes the development of a fracture theory for elastomers that has been able to explain experimental observations that had puzzled scientists for decades. This work has also provided a unifying perspective on fracture in all brittle solids, soft or hard, and has led to an ongoing search for a complete theory of nucleation and propagation of fracture for all solids. Currently, his group is also working on the nonlinear mechanics of material evolution (remodeling) in biological tissues and the multi-physics modeling of 3D printing in polymers. 
 

Michelle’s research is themed around designing and characterizing the surface chemical properties of synthetic and natural polymer systems. They will be used to develop multifunctional biomaterial substrates for regenerative medicine, cancer treatment, and personal care products. The goals of the Gaines Lab are achieved by marrying Polymer Synthesis, Materials Science, Cell Biology & Spectroscopy.

Jay Patel, Ph.D., is an Assistant Professor in the Department of Orthopaedics at Emory and a Health Science Specialist at the Atlanta VA. Patel joined the faculty at Emory in September 2020, and his program focuses on the repair and regeneration of musculoskeletal tissues (e.g., cartilage, meniscus), with an emphasis on using micro-scale findings to drive macro-scale therapies. His lab uses a combination of biomechanics, biomaterials, mechano-biology, in vitro systems, and functional in vivo models to motivate, design, develop, and evaluate novel treatments and therapeutics for orthopaedic injuries. He received his Bachelor’s in Bioengineering from Rice University and his Ph.D. in Biomedical Engineering from Rutgers University. He then pursued his postdoctoral training at the University of Pennsylvania in the Department of Orthopaedic Surgery, working on a variety of cartilage tissue engineering and mechano-biology projects. Patel has published over 20 manuscripts, has presented at numerous international conference meetings, and won several prestigious awards, including the Excellence in Research Award (2018) from the American Orthopaedic Society for Sports Medicine. Moreover, both his graduate and postdoctoral work resulted in pending patent applications, and the formation of startup companies with active small-business funding, demonstrating his ultimate goal of translating these approaches to the clinic.