-
information and control behavior in mice and songbirds. We place particular emphasis on advanced optical approaches, including multiphoton microscopy, Bessel-beam imaging, and closed-loop patterned stimulation
-
time, requiring agile adaptation to the specific requirements. We particularly encourage individuals with an interest in annotating 3D or 4D microscopy images or recorded animal behavior to apply
-
modulation and imaging techniques to achieve research goals. What we provide: A supportive and interactive work environment to strengthen your skills as a scientist. Joining the vibrant University
-
body in Drosophila and bumblebees as model systems. Our research integrates genetic tools, high-throughput behavioral analysis, EM connectomics, expansion microscopy, mass spectrometry, calcium imaging
-
methods such as: Behavioral training and motion capture Two-photon imaging (head-fixed, with interest in free-moving applications) Electrophysiology in both head-fixed and freely moving animals High-speed
-
sample prep, sectioning and imaging. Optimizing and writing up lab protocols. Shipping and cataloguing of reagents. Lab fridge and freezer maintenance. General lab upkeep alongside other members
-
they continue to investigate. Approaches include genetics, spatial genomics, single-molecule biophysics, super-resolution imaging, computational modeling, and structural studies including X-ray
-
microscopes, and cryo grids preparation equipment. The main function of the facility is 1) high-throughput, high-quality data collection on user-provided ready-to-image cryo grids utilizing either single
-
, at Harvard Medical School studies the molecular basis of sensory transduction, using cryo-electron microscopy (cryo-EM), electrophysiology, calcium imaging, computational modeling, and behavioral experiments
-
at the interface of established fields. Candidates with experience in molecular biology, neuronal manipulations and imaging, immunology, metabolic phenotyping (e.g. metabolomics), and electrophysiology