School of Medicine
Showing 101-120 of 121 Results
Harminder Singh, M.D.
Clinical Associate Professor, Neurosurgery
Current Research and Scholarly Interests Minimally Invasive Cranial and Spinal Surgery, Endoscopic Keyhole Surgery
Associate Professor of Neurosurgery at the Stanford University Medical Center
Current Research and Scholarly Interests My research focuses on screening strategies to identify and characterize cancer stem cells (CSCs) in human gliomas. We are pursuing this in several ways: 1) a novel colony-forming antibody live cell array to identify distinct CSC surface phenotypes, 2) RNAi screens to identify kinases critical for CSC tumorigenicity, 3) high throughput small molecule and chemical screens to identify compounds that selectively kill or target CSCs, and 4) identifying CSCs using the tumor specific EGFRvIII
James R. Doty Professor of Neurosurgery and Neurosciences
Bio Ivan Soltesz received his doctorate in Budapest and conducted postdoctoral research at universities at Oxford, London, Stanford and Dallas. He established his laboratory at the University of California, Irvine, in 1995. He became full Professor in 2003, and served as department Chair from 2006 to July 2015. He returned to Stanford in 2015 as the James R. Doty Professor of Neurosurgery and Neurosciences at Stanford University School of Medicine. His major research interest is focused on neuronal microcircuits, network oscillations, cannabinoid signaling and the mechanistic bases of circuit dysfunction in epilepsy.
His laboratory employs a combination of closely integrated experimental and theoretical techniques, including closed-loop in vivo optogenetics, paired patch clamp recordings, in vivo electrophysiological recordings from identified interneurons in awake mice, 2-photon imaging, machine learning-aided 3D video analysis of behavior, video-EEG recordings, behavioral approaches, and large-scale computational modeling methods using supercomputers. He is the author of a book on GABAergic microcircuits (Diversity in the Neuronal Machine, Oxford University Press), and editor of a book on Computational Neuroscience in Epilepsy (Academic Press/Elsevier). He co-founded the first Gordon Research Conference on the Mechanisms of neuronal synchronization and epilepsy, and taught for five years in the Ion Channels Course at Cold Springs Harbor. He has over 30 years of research experience, with over 20 years as a faculty involved in the training of graduate students (total of 16, 6 of them MD/PhDs) and postdoctoral fellows (20), many of whom received fellowship awards, K99 grants, joined prestigious residency programs and became independent faculty.
Scott G. Soltys, MD
Associate Professor of Radiation Oncology (Radiation Therapy) and, by courtesy, of Neurosurgery at the Stanford University Medical Center
Current Research and Scholarly Interests My clinical and research interests focus on the development of new radiation techniques involving stereotactic radiosurgery and radiotherapy for the treatment of malignant and benign tumors of the brain and spine, as well as functional disorders such as trigeminal neuralgia.
Gary K. Steinberg, MD, PhD
Bernard and Ronni Lacroute-William Randolph Hearst Professor in Neurosurgery and Neurosciences and Professor, by courtesy, of Neurology
Current Research and Scholarly Interests Our laboratory investigates the pathophysiology and treatment of cerebral ischemia, and methods to restore neurologic function after stroke. Treatment strategies include brain hypothermia, stem cell transplantation and optogenetic stimulation. Our clinical research develops innovative surgical, endovascular and radiosurgical approaches for treating difficult intracranial aneurysms, complex vascular malformations and occlusive disease, including Moyamoya disease, as well as stem cell transplant.
Professor of Neurosurgery
Bio Dr. Peter Tass investigates and develops neuromodulation techniques for understanding and treating neurologic conditions such as Parkinson?s disease, epilepsy, dysfunction following stroke and tinnitus. He creates invasive and non-invasive therapeutic procedures by means of comprehensive computational neuroscience studies and advanced data analysis techniques. The computational neuroscience studies guide experiments that use clinical electrophysiology measures, such as high density EEG recordings and MRI imaging, and various outcome measures. He has pioneered a neuromodulation approach based on thorough computational modelling that employs dynamic self-organization, plasticity and other neuromodulation principles to produce sustained effects after stimulation. To investigate stimulation effects and disease-related brain activity, he focuses on the development of stimulation methods that cause a sustained neural desynchronization by an unlearning of abnormal synaptic interactions. He also performs and contributes to pre-clinical and clinical research in related areas.
Assistant Professor of Neurosurgery at the Stanford University Medical Center
Current Research and Scholarly Interests The long-term goal of my research is the repair of damaged corticospinal circuitry. Therapeutic regeneration strategies will be informed by an understanding both of corticospinal motor neuron (CSMN) development and of events occurring in CSMN in the setting of spinal cord injury. MicroRNAs are small, non-coding RNAs that regulate the expression of ?suites? of genes. The work in my lab seeks to identify microRNA controls over CSMN development and over the CSMN response to spinal cord injury.
Zachary David Threlkeld
Clinical Assistant Professor, Neurology & Neurological Sciences
Bio Dr. Threlkeld cares for critically ill patients with acute neurologic illness, including traumatic brain injury, stroke, intracerebral hemorrhage, and epilepsy. He completed his residency training in neurology at the University of California, San Francisco, and joined the Stanford Neurocritical Care program after completing fellowship training in neurocritical care at Massachusetts General Hospital and Brigham and Women?s Hospital in Boston. He has a particular clinical and research interest in traumatic brain injury. His research uses advanced imaging modalities like functional magnetic resonance imaging (fMRI) to better understand disorders of consciousness.
Assistant Professor of Neurosurgery and, by courtesy, of Orthopaedic Surgery at the Stanford University Medical Center
Current Research and Scholarly Interests The focus of my laboratory is to utilize precision medicine techniques to improve the diagnosis and treatment of neurologic conditions. From traumatic brain injury to spinal scoliosis, the ability to capture detailed data regarding clinical symptoms and treatment outcomes has empowered us to do better for patients. Utilize data to do better for patients, that?s what we do.
Stanford Neurosurgical Ai and Machine Learning Lab
Hannes Vogel MD
Professor of Pathology and of Pediatrics (Pediatric Genetics) and, by courtesy, of Neurosurgery and of Comparative Medicine at the Stanford University Medical Center
Current Research and Scholarly Interests My research interests include nerve and muscle pathology, mitochondrial diseases, pediatric neurooncology, and transgenic mouse pathology.
Associate Professor of Neurosurgery
Current Research and Scholarly Interests Mechanisms underlying mitochondrial dynamics and function, and their implications in neurological disorders.
Thomas J. Wilson
Clinical Assistant Professor, Neurosurgery
Bio Dr. Thomas J. Wilson was born in Omaha, Nebraska. He attended the University of Nebraska College of Medicine, earning his MD with highest distinction. While a medical student, he was awarded a Howard Hughes Medical Institute Research Training Fellowship and spent a year in the lab of Dr. Rakesh Singh at the University of Nebraska. He was also elected to the prestigious Alpha Omega Alpha Honor Medical Society. He completed his residency training in neurological surgery at the University of Michigan and was mentored by Dr. Lynda Yang and Dr. John McGillicuddy in peripheral nerve surgery. Following his residency, he completed a fellowship in peripheral nerve surgery at the Mayo Clinic in Rochester, Minnesota, working with Dr. Robert Spinner. He is now Clinical Assistant Professor and Co-Director of the Center for Peripheral Nerve Surgery at Stanford University. He is also currently endeavoring to earn a Master of Public Health (MPH) degree from the Bloomberg School of Public Health at Johns Hopkins University. His research interests include peripheral nerve outcomes research using large data sets and multi-institutional registries, clinical trials advancing options for patients with peripheral nerve pathologies, and translational research focused on deriving methods for data-driven intraoperative decision-making using intraoperative electrophysiology, advanced imaging techniques, and genetic expression information. His wife, Dr. Monique Wilson, is a practicing dermatologist in the Bay Area.
Professor of Radiology (Neuroimaging and Neurointervention) and, by courtesy, of Neurology, of Neurosurgery and of Psychiatry and Behavioral Sciences at the Stanford University Medical Center
Current Research and Scholarly Interests Stroke, cerebrovascular diseases, cardiovascular diseases, carotid arteries, coronary arteries
Stroke diagnosis, stroke triage, stroke treatment
Traumatic brain injury
Traumatic brain injury diagnosis and prognosis
Psychiatric disorders, including depression and post-traumatic stress disorders
Movement disorders, including essential tremor and Parkinson?s tremor
Image-guided clinical trials
CT, multidetector-row CT, perfusion-CT, CT angiography
MRI, diffusion-weighted MRI, perfusion-weighted MRI, diffusion tensor imaging, functional MRI
Brain perfusion imaging techniques
Post-processing techniques of medical images, signal and image processing
MR-guided focused ultrasound
Albert J. Wong, M.D.
Professor of Neurosurgery
Current Research and Scholarly Interests Our goal is to define targets for cancer therapeutics by identifying alterations in signal transduction proteins. We first identified a naturally occurring mutant EGF receptor (EGFRvIII) and then delineated its unique signal transduction pathway. This work led to the identification of Gab1 followed by the discovery that JNK is constitutively active in tumors. We intiated using altered proteins as the target for vaccination, where an EGFRvIII based vaccine appears to be highly effective.
Professor (Research) of Neurosurgery
Current Research and Scholarly Interests My lab is focused on developing novel therapeutic methods against stroke using rodent models. We study protective effect of postconditioning, preconditioning and mild hypothermia. The rationale for studying three means of neuroprotection is that we may discover mechanisms that these treatments have in common. Conversely, if they have differing mechanisms, we will be able to offer more than one treatment for stroke and increase a patient’s chance for recovery.
J. Bradley Zuchero
Assistant Professor of Neurosurgery
Current Research and Scholarly Interests Glia are a frontier of neuroscience, and overwhelming evidence from the last decade shows that they are essential regulators of all aspects of the nervous system. The Zuchero Lab aims to uncover how glial cells regulate neural development and how their dysfunction contributes to diseases like multiple sclerosis (MS) and in injuries like stroke.
Although glia represent more than half of the cells in the human brain, fundamental questions remain to be answered. How do glia develop their highly specialized morphologies and interact with neurons to powerfully control form and function of the nervous system? How is this disrupted in neurodegenerative diseases and after injury? By bringing cutting-edge cell biology techniques to the study of glia, we aim to uncover how glia help sculpt and regulate the nervous system and test their potential as novel, untapped therapeutic targets for disease and injury.
We are particularly interested in myelin, the insulating sheath around neuronal axons that is lost in diseases like MS. How do oligodendrocytes- the glial cell that produces myelin in the central nervous system- form and remodel myelin, and why do they fail to regenerate myelin in disease? Our current projects aim to use cell biology and neuroscience approaches to answer these fundamental questions. Ultimately we hope our work will lead to much-needed therapies to promote remyelination in patients.