Dr. John studies the malaria parasite, Plasmodium falciparum, to understand its basic molecular and cellular biology and functions of its specific metabolic pathways — what the parasite needs to make and why it needs to make it — to identify new antimalarial drug targets and develop new diagnostics.
Dr. Margaritis uses biochemical, molecular, and complex in vivo methodology within the field of coagulation to advance the understanding of molecular mechanisms involved in pro- and anti-coagulant reactions, and translate research for the treatment of coagulation defects.
Dr. Hamilton studies intestinal epithelial cells and how they help maintain human health. Although there is a great deal understood about how these cells function, little is known about how they behave during disease. Dr. Hamilton focuses on defining new mechanisms in regenerative medicine, inflammatory bowel disease, and colorectal cancer.
Dr. Resnick's research focuses on the cell signaling mechanisms of oncogenesis and tumor progression in brain tumors. He studies signaling cascades and alterations to elucidate the molecular and genetic underpinnings in order to develop targeted therapies. As co-director of the Center of Data-Driven Discovery in Biomedicine, he leads a multidisciplinary team building and supporting a scalable, patient-focused healthcare and educational discovery ecosystem.
Dr. Pei's research aims to understand the molecular underpinnings of cardiac remodeling associated with cardiomyopathy and heart failure. He is particularly interested in two areas of cardiac remodeling: metabolic reprogramming, and secretion of heart-derived hormones to communicate with other organs.
Dr. Weitzman's research program aims to understand host responses to virus infection, and the cellular environment encountered and manipulated by viruses. He studies multiple viruses in an integrated experimental approach that combines biochemistry, molecular biology, genetics, and cell biology.
Bone disorders exact a considerable toll on human health in both children and adults. Dr. Long seeks to understand the fundamental mechanisms underlying both normal skeletal development and the pathophysiology of bone diseases. His current research includes studies of skeletal stem cells and progenitors, metabolic regulation of bone cells, and the integration of bone and whole-body metabolism.
Dr. Kalish's research focuses on understanding the molecular and epigenetic mechanisms that contribute to the predisposition to cancer that is characteristic of pediatric patients with rare imprinted gene disorders, including the overgrowth disorder Beckwith-Wiedemann syndrome (BWS).