Research in the Kawsar Rasmy Talaat Lab focuses on international health and parasitology, with an emphasis on vaccines, avian influenza and pandemic influenza. Our team conducts clinical trials of vaccines for a range of diverse pathogens, including flu strains that have the potential to reach pandemic status. Our studies seek to evaluate the safety and immunogenicity of vaccine candidates. We also have a longstanding interest in tropical medicine.

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.

The Anna Durbin Lab evaluates experimental vaccines through human clinical trials. We have conducted both pediatric and adult clinical trials on vaccines for HIV, hepatitis C, HPV, influenza, malaria, dengue virus, rotavirus and other viruses. We also have a longstanding interest in better understanding the immunologic factors of dengue infection and disease. We’re working to identify the viral, host and immunologic factors that cause severe dengue illness.

The Laboratory for Integrated NanoDiagnostics (LIND) is developing innovative technologies for accurate, fast, compact, portable, manufacturable, low-cost diagnostics for a wide variety of applications. Our current focus is a large-scale collaboration with imec, a leading microelectronics company in Leuven, Belgium, where our silicon is designed and manufactured. With major funding from miDiagnostics we are inventing solutions that are opening new avenues.

The SIP Lab studies the mechanisms of normal and disordered swallowing. The team conducts research in the areas of swallowing rehabilitation after stroke, effects of aging on swallowing and measurement of swallowing physiology.

The Advanced Optics Lab uses innovative optical tools, including laser-based nanotechnologies, to understand cell motility and the regulation of cell shape. We pioneered laser-based nanotechnologies, including optical tweezers, nanotracking, and laser-tracking microrheology. Applications range from physics, pharmaceutical delivery by phagocytosis (cell and tissue engineering), bacterial pathogens important in human disease and cell division. Other projects in the lab are related to microscopy, specifically combining fluorescence and electron microscopy to view images of the subcellular structure around proteins.

The Agrawal Lab is focused on the medical and surgical treatment of otologic and neurotologic conditions. Research is focused on the vestibular system (the inner ear balance system), and how the function of the vestibular system changes with aging. Particular focus is given to study how age-related changes in vestibular function influence mobility disability and fall risk in older individuals.

The Brain Science Institute (BSi) brings together both basic and clinical neuroscientists from across the Johns Hopkins campuses. The BSi represents one of the largest and most diverse groups in the university. The BSi's mission is to solve fundamental questions about brain development and function and to use these insights to understand the mechanisms of brain disease. This new knowledge will provide the catalyst for the facilitation and development of effective therapies. The goals of our research are to foster new programs in basic neuroscience discovery; initiate a translational research program that will develop new treatments for brain-based diseases; and encourage collaboration, interdisciplinary teams, and new thinking that will have a global influence on research and treatment of the nervous system.

The Berger Lab's research is focused on understanding how multi-subunit assemblies use ATP for overcoming topological challenges within the chromosome and controlling the flow of genetic information. A long-term goal is to develop mechanistic models that explain in atomic level detail how macromolecular machines transduce chemical energy into force and motion, and to determine how cells exploit and control these complexes and their activities for initiating DNA replication, shaping chromosome superstructure and executing myriad other essential nucleic-acid transactions. Our principal approaches include a blend of structural (X-ray crystallography, single-particle EM, SAXS) and solution biochemical methods to define the architecture, function, evolution and regulation of biological complexes. We also have extensive interests in mechanistic enzymology and the study of small-molecule inhibitors of therapeutic potential, the development of chemical approaches to trapping weak protein/protein and protein/nucleic acid interactions, and in using microfluidics and single-molecule approaches for biochemical investigations of protein dynamics.

The Zanvyl Krieger Mind/Brain Institute is dedicated to the study of the neural mechanisms of higher brain functions using modern neurophysiological, anatomical and computational techniques. Our researchers use various approaches to understand information processing and its influence on perception, memory, abstract thought, complex behavior and consciousness. Systems and cognitive laboratories use neurophysiology, brain imaging and psychophysics to develop a quantitative, network-level understanding of cognitive information processing. Other researchers use analytical approaches such as system identification, dimensionality reduction, information theory and network modeling to understand information processing. Other areas of research in the Institute include the study of how visual and tactile information processing leads to perception and understanding of two- and three-dimensional objects. Another focus is on neural processing and recognition of speech and other complex sounds. Still other laboratories study neural mechanisms of attention, memory formation, motor learning, decision-making and executive control of behavior.