Find a Research Lab

Research Lab Results

Results per page:

  • Andrew Lane Lab

    The Lane laboratory is focused on understanding molecular mechanisms underlying chronic rhinosinusitis, particularly the pathogenesis of nasal polyps, as well as inflammation on the olfactory epithelium. Diverse techniques in molecular biology, immunology, and physiology are utilized to study epithelial cell innate immunity, olfactory loss, and response to viral infection. Ongoing work explores how epithelial cells of the sinuses and olfactory mucosa participate in the immune response and contribute to chronic inflammation. The lab creates and employs transgenic mouse models of chronic nasal/sinus inflammation to support research in this area. Collaborations are in place with the School of Public Health to explore mechanisms of anti-viral immunity in influenza and COVID-19.
  • King-Wai Yau Laboratory

    The King-Wai Yau Laboratory is interested in the area of sensory transduction. Specifically, we study visual and olfactory transductions, which are the processes by which the senses of vision and olfaction are initiated. Rods and cones are the retinal photoreceptors that absorb light for initiating image vision. We are studying the cellular and molecular details underlying rod and cone phototransduction.
    Lab Website

    Principal Investigator

    King Yau, PhD

    Department

    Neuroscience

  • Christopher Potter Lab

    The Christopher Potter Lab functions at an intersection between systems and cellular neuroscience. We are interested in how neurons and circuits function in the brain to achieve a common goal (olfaction), but we also develop, utilize and build tools (molecular and genetic) that allow us to directly alter neuronal functions in a living organism. The specific focus of my laboratory is to understand how the insect brain receives, interprets, and responds to odors. Insects rely on their sense of smell for all major life choices, from foraging to mating, from choosing where to lay eggs to avoiding predators and dangers. We are interested in understanding at the neuronal level how odors regulate these behaviors. Our long-term aim is to apply this knowledge to better control insects that pose a threat to human health. Our general approach towards achieving this goal is to develop and employ new genetic methods that enable unprecedented control over neural circuits in both the model organism Drosophila melanogaster and human malaria vector Anopheles gambiae.
    Lab Website

    Principal Investigator

    Chris John Potter, PhD

    Department

    Neuroscience