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, including electroretinography (ERG), fundus photography and optical coherence tomography (OCT). • Assist in experimental design, data interpretation, and integration of multi-omics datasets. Dissemination
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experimental approaches for structural biology (e.g., cryo-electron microscopy/tomography, X-ray crystallography) is a significant plus. Experience with antibody engineering (e.g., expression, stability, binding
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for neuroimaging methodology, including: Designing, adapting, and overseeing multimodal MRI acquisition protocols (structural, diffusion, functional MRI), with attention to pediatric constraints Ensuring
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of mechanosensation in the eye and its role in glaucoma and other ocular pathologies. Questions we are interested in studying include: 1) What are the ion channels that mediate pressure sensing in the eye? 2) What
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, molecular profiling, and transgenesis, and is passionate about learning systems neuroscience and all-optical physiological approaches to the study of brain-body interactions. Our mentorship goal
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performing neuro-behavioral and/or neuro-physiological experiments, including visual stimulus design, eye tracking, MRI or large-scale electrophysiology techniques (ideally Neuropixels). Additionally
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techniques including inductively coupled plasma mass spectrometry (ICP-MS), inductively coupled plasma optical emissions spectroscopy (ICP-OES), graphite furnace atomic absorption spectrometry (GFAAS), x-ray
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will have a strong background in engineering—biomedical, electrical, or mechanical—with expertise in optics, imaging systems, or device development. Our research focuses on advancing molecular and
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., diffusion transformers, multimodal representation learning) for modeling high-dimensional biological images. Develop computational methods to reconstruct and simulate 3D tissue architecture and dynamics