Dr. Ackermann studies diabetes (types 1 and 2) and congenital hyperinsulinism using mouse models, cell lines, and primary human tissue. She aims to identify novel pathways regulating beta cell insulin secretion, leading to innovative therapeutic strategies for these disorders. Current studies include in vivo mouse physiology, ex vivo human islet physiology, CRISPR-Cas9 gene editing, epigenetic modification, and single-cell functional genomics.
Dr. Tong investigates cytokine receptor signaling in normal and neoplastic hematopoietic development. She uses integrated approaches encompassing biochemistry, molecular biology, mouse models, and primary human samples to understand signaling events emanating from cytokine receptors that regulate the development of hematopoietic stem/progenitor cells.
Dr. De Raedt researches pediatric high grade glioma development and aims to understand the involvement of crucial pathways. He investigates pathway interaction, and explores ways to develop therapies through analyzing human tumors, performing cellular studies, and developing accurate mouse models. This allows Dr. De Raedt and his team to perform novel pre-clinical studies that can lead to clinical trials.
Dr. Falk is a Clinical Geneticist who serves as executive director of the Mitochondrial Medicine Frontier Program. Her translational research lab investigates the causes and global metabolic consequences of mitochondrial disease, as well as targeted therapies, in C. elegans, zebrafish, mouse, and human tissue models of genetic-based respiratory chain dysfunction.
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. De Leon-Crutchlow’s translational research program focuses on examining the pathophysiology of disorders of insulin regulation, identifying novel therapeutic targets, and developing new therapies for these conditions. The program approach includes patient-oriented research and bench research employing mouse models and primary islet cultures.
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. 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. Silverman studies the fundamental aspects of early-life commensal microbes that influence immune system development and function. He discovered that the MHC-II E molecule prevents type 1 diabetes by shaping the intestinal microbiota early in life.