The Hey-Kyoung Lee Lab is interested in exploring the cellular and molecular changes that happen at synapses to allow memory storage. We use various techniques, including electrophysiological recording, biochemical and molecular analysis, and imaging, to understand the cellular and molecular changes that happen during synaptic plasticity. Currently, we are examining the molecular and cellular mechanisms of global homeostatic synaptic plasticity using sensory cortices as model systems. In particular, we found that loss of vision elicits global changes in excitatory synaptic transmission in the primary visual cortex. Vision loss also triggers specific synaptic changes in other primary sensory cortices, which we postulate underlies sensory compensation in the blind. One of our main research goals is to understand the mechanisms underlying such cross-modal synaptic plasticity. We are also interested in elucidating the events that occur in diseased brains. In collaboration with other researchers, we are analyzing various mouse models of Alzheimer's disease, especially focusing on the possible alterations in synaptic plasticity mechanisms.

The Johns Hopkins Head and Neck Cancer Tissue Bank enrolls patients and collects research specimens from Head and Neck Tumor patients, both cancerous and benign, with particular focus on Head and Neck Squamous Cell Cancer patients. It provides specimens to researchers both within the institution and outside.

Our work is focused on the translational human in vivo and ex vivo assessments of right ventricular (RV) function in the setting of pulmonary hypertension. Among patients with group I pulmonary arterial hypertension PAH, those with systemic-sclerosis-associated PAH (SSc-PAH) have a particularly poor prognosis and less optimal response to PAH-guided therapy. Using in vivo pressure-volume catheterization of the right ventricle, we have uncovered key deficiencies in resting and reserve RV function in the SSc-PAH group when compared to idiopathic PAH (IPAH) patients. These studies have uncovered key discoveries with regards to right ventricular-pulmonary arterial (RV-PA) coupling in PAH. In the lab, by studying myofilament function from RV endomyocardial biopsies from these same patients, we have uncovered corresponding deficiencies in myofilament contractility and calcium sensitivity as well. Ongoing work is directed towards determining the underlying mechanism of these findings, which will hopefully lead to therapeutic applications for RV failure in SSc-PAH. Further endeavors are directed towards studying RV failure in other populations, including exercise-induced PH, PH secondary to left-heart disease, and the left ventricular assist device population.

Work in the Hsin-Chieh Yeh Lab focuses on clinical trials and cohort studies of diabetes, obesity and behavioral intervention, cancer and hypertension. Recent investigations have focused on novel risk factors and complications related to obesity and type 2 diabetes, particularly lung function, smoking and cancer. We recently co-led a randomized clinical trial of tailored dietary advice for consumption of dietary supplements to lower blood pressure and improve cardiovascular disease risk factors in hypertensive urban African Americans.

Researchers in the Henry Michtalik Lab are interested in patient safety—particularly as it relates to patient census statistics and acute to primary care transitions—and quality improvement and systems management.

Research in the Ivor Berkowitz Lab targets pediatric critical care medicine. We are particularly interested in the pathophysiology behind the cerebrovascular dysfunction that occurs in bacterial meningitis as well as the anesthetic and perioperative complications of patients with dwarfing syndromes.

Complexity in signaling networks is often derived from co-opting one set of molecules for multiple operations. Understanding how cells achieve such sophisticated processing using a finite set of molecules within a confined space--what we call the ""signaling paradox""--is critical to biology and engineering as well as the emerging field of synthetic biology. In the Inoue Lab, we have recently developed a series of chemical-molecular tools that allow for inducible, quick-onset and specific perturbation of various signaling molecules. Using this novel technique in conjunction with fluorescence imaging, microfabricated devices, quantitative analysis and computational modeling, we are dissecting intricate signaling networks. In particular, we investigate positive-feedback mechanisms underlying the initiation of neutrophil chemotaxis (known as symmetry breaking), as well as spatio-temporally compartmentalized signaling of Ras and membrane lipids such as phosphoinositides. In parallel, we also try to understand how cell morphology affects biochemical pathways inside cells. Ultimately, we will generate completely orthogonal machinery in cells to achieve existing, as well as novel, cellular functions. Our synthetic, multidisciplinary approach will elucidate the signaling paradox created by nature.

The Maryam Jahromi Lab researches infectious diseases such as influenza, tuberculosis, endocarditis, viral hemorrhagic fevers, brucellosis, Clostridium difficile and Crimean-Congo hemorrhagic fever. We are particularly interested in the impact of the influenza vaccine on systemic inflammation. Recent areas of focus include the relationship between influenza vaccination and cardiovascular outcomes, the emergence of Crimean-Congo hemorrhagic fever in Iran, and prospects for vaccines and therapies for Crimean-Congo hemorrhagic fever.

Research in the Michael Melia Lab focuses primarily on nocardia infections, Lyme disease and hepatitis C. Our studies have included key topics such as risk factors for incident infections during hepatitis C treatment, racial differences in eligibility for hepatitis C treatment and misdiagnosis of Lyme arthritis using the Borrelia burgdorferi immunoblot testing method. We also have a longstanding interest in medical education and work on curriculum to improve the quality of education for medical students and interns.

The Michelle Eakin Lab conducts research on behavioral science and adherence and asthma outcomes in inner-city children. Our studies into behavioral science have included exploring the impact of medication adherence on lung health outcomes in patients with cystic fibrosis, disparities in anti-hypertensive medication adherence in adolescents and other key topics. We also investigate methods for improving asthma care and treatment as well as health disparities among various ethnicities, particularly in pediatric patients.