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. Levine has an active laboratory research program that complements and extends his clinical studies. He has identified the molecular basis of several inherited disorders of mineral metabolism. His research interests extend to the molecular basis for embryological development of the parathyroid glands.
Dr. Zemel's overall research program aims to improve the understanding of lifelong health and how it relates to childhood antecedents of physical growth and maturation, body composition, population ancestry/genetics, and lifestyle factors. Such insight has practical implications for disease prevention and lifelong wellness, as well as broader scientific implications for understanding human plasticity and evolution.
Dr. McCormack investigates the intersection of neuroendocrinology and metabolism. Her translational research program involves two areas. The first involves studying those with genetic disorders, including primary mitochondrial diseases and Friedreich's ataxia, with characterized risk for diabetes mellitus. Second, Dr. McCormack focuses on brain disorders associated with excess weight gain, including brain tumor-related hypothalamic obesity syndrome and idiopathic intracranial hypertension.
Dr. Mostoufi-Moab's clinical and research program is focused on endocrine late effects after childhood cancer therapy. She has unique dual training in pediatric endocrinology and oncology with a master's degree in clinical epidemiology. The goal of her research program is to pursue a mechanistic understanding of metabolic and endocrine disorders that occur due to cancer therapy.
Dr. Roizen's research program aims to understand non-calciometabolic effects of vitamin D and to use this understanding to design new therapeutic approaches to common diseases such as sarcopenia and obesity.