Dr. Choi's research focuses on the role of RNA-binding proteins in the regulation of alternative splicing and how mutations in these factors contribute to cancer. He uses a combination of genetically-engineered models and high-throughput approaches to better understand how alternative splicing influences cellular function and to identify potential opportunities for therapeutic intervention.
Dr. Takano's research focuses on basic epilepsy and related neuroscience research centered on advanced optical imaging techniques such as fluorescence lifetime imaging and two-photon microscopy; and application of micro- and nanotechnology like graphene transparent electrode to functional cellular imaging.
Dr. Gonzalez-Alegre's long-range research goal is to advance the application of precision medicine in the neurology clinic. His research focus revolves around genetic disorders that affect the brain, spanning from the diagnosis of novel genetic disease in the clinic to the identification of novel molecular targets using disease models and the design of early-phase human clinical trials.
Dr. French came to CHOP in 2008 to establish the Human Pluripotent Stem Cell Core in the Center for Cellular and Molecular Therapeutics. She is an internationally recognized researcher involved in multi-investigator teams that utilize pluripotent stem cells for modeling human disease to study mechanism, development, and establish new therapeutic modalities.
Dr. Song works to elucidate the cellular and molecular basis governing the formation, maintenance, and function of neural circuits under physiological and pathological conditions, using both Drosophila and mammalian models.
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. Pacifici's biomedical research spans three decades and has explored mechanisms of skeletal development and growth in fetal and postnatal life. Specifically, his focus has been on identifying the cellular and molecular mechanisms that regulate the differentiation of progenitor cells and permit assembly of distinct skeletal structures, and on aberrations of these mechanisms in pediatric skeletal disorders.
Dr. Marsh's research program focuses on understanding how changes in brain development lead to epilepsy, intellectual disability, and autism. He combines molecular and physiological tools in mouse models to ask questions about the interaction of normal development with single gene mutations to determine how the brain responds to perturbations in development.
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.