Stanford University
Showing 81-90 of 416 Results
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Robert Fisher, MD, PhD
The Maslah Saul, MD, Professor and Professor, by courtesy, of Neurosurgery
Current Research and Scholarly InterestsDr. Fisher is interested in clincal, laboratory and translational aspects of epilepsy research. Prior work has included: electrical deep brain stimulation for epilepsy, studied in laboratory models and clinical trials; drug delivery to a seizure focus; mechanisms of absence epilepsy studied with in vitro slices of brain thalamus; hyperthermic seizures; diagnosis and treatment of non-epileptic seizures, the post-ictal state; driving and epilepsy; new antiepileptic drugs; surgery for epilepsy.
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Nicole Francisco
HR Support 2, Neurology & Neurological Sciences
BioPronouns: she/her/hers
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Kristin Galetta, MD
Clinical Assistant Professor, Adult Neurology
BioDr. Galetta is a board-certified neurologist within the Neurohospitalist and Neuroimmunology divisions. She completed a multiple sclerosis (MS) fellowship at Brigham and Women’s Hospital.
She has extensive experience diagnosing and treating patients with autoimmune neurologic conditions including multiple sclerosis, optic neuritis, autoimmune encephalitis and transverse myelitis. Her research interests are focused on understanding best treatment strategies for patients with multiple sclerosis and more rare autoimmune neurologic conditions. She also has an interest in medical education improvement.
She has published in numerous peer-reviewed journals, including the Journal of Neurological Sciences and Multiple Sclerosis and Related Disorders. She is a peer reviewer for multiple prestigious journals, including Neurology and Frontiers in Neurology. -
Yiming Gan
Postdoctoral Scholar, Neurology and Neurological Sciences
BioDr. Yiming Gan is a postdoctoral scholar in the Department of Neurology. He earned his B.S. degree in Modern Mechanics from the University of Science and Technology of China (USTC) in 2019 and his Ph.D. in Mechanical Engineering from the University of Rochester in 2024, where his research focused on the experimental measurement and computational modeling of cerebrospinal fluid flow and the glymphatic system. After graduation, he joined Stanford University as a postdoctoral scholar in the Pediatric Neurostimulation Laboratory (Baumer Lab) and the Wu Tsai Neuroscience Institute. His research interests span biomarkers for epilepsy (functional connectivity), cerebral drug delivery, and Laser Interstitial Thermal Therapy.
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Paul George, MD, PhD
Associate Professor of Neurology and Neurological Sciences (Adult Neurology) and, by courtesy, of Neurosurgery
Current Research and Scholarly InterestsCONDUCTIVE POLYMER SCAFFOLDS FOR STEM CELL-ENHANCED STROKE RECOVERY:
We focus on developing conductive polymers for stem cell applications. We have created a microfabricated, polymeric system that can continuously interact with its biological environment. This interactive polymer platform allows modifications of the recovery environment to determine essential repair mechanisms. Recent work studies the effect of electrical stimulation on neural stem cells seeded on the conductive scaffold and the pathways by which it enhances stroke recovery Further understanding the combined effect of electrical stimulation and stem cells in augmenting neural repair for clinical translational is a major focus of this research going forward.
BIOPOLYMER SYSTEMS FOR NEURAL RECOVERY AND STEM CELL MODULATION:
The George lab develops biomaterials to improve neural recovery in the peripheral and central nervous systems. By controlled release of drugs and molecules through biomaterials we can study the temporal effect of these neurotrophic factors on neural recovery and engineer drug delivery systems to enhance regenerative effects. By identifying the critical mechanisms for stroke and neural recovery, we are able to develop polymeric technologies for clinical translation in nerve regeneration and stroke recovery. Recent work utilizing these novel conductive polymers to differentiate stem cells for therapeutic and drug discovery applications.
APPLYING ENGINEERING TECHNIQUES TO DETERMINE BIOMARKERS FOR STROKE DIAGNOSTICS:
The ability to create diagnostic assays and techniques enables us to understand biological systems more completely and improve clinical management. Previous work utilized mass spectroscopy proteomics to find a simple serum biomarker for TIAs (a warning sign of stroke). Our study discovered a novel candidate marker, platelet basic protein. Current studies are underway to identify further candidate biomarkers using transcriptome analysis. More accurate diagnosis will allow for aggressive therapies to prevent subsequent strokes.
