{"result":[{"lastName":"Chen","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor,Psychiatry & Behavioral Science - Center for Interdisciplinary Brain Sciences Research"}],"primaryAppointment":"Associate Professor,Psychiatry & Behavioral Science - Center for Interdisciplinary Brain Sciences Research","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=20934&type=small&showNoImage","displayName":"Lu Chen","firstName":"Lu","href":"http://med.stanford.edu/profiles/Lu_Chen","researchInterest":"What distinguishes us humans from other animals is our ability to undergo complex behavior. The synapses are the structural connection between neurons that mediates the communication between neurons, which underlies our various cognitive function. My research program aims to understand the cellular and molecular mechanisms that underlie synapse function during behavior in the developing and mature brain, and how synapse function is altered during mental retardation."},{"lastName":"Ricci","clinicalFocus":[],"appointments":[{"appointment":"Professor,Otolaryngology (Head and Neck Surgery)"},{"appointment":"Member,Child Health Research Institute"},{"appointment":"Member,Bio-X"},{"appointment":"Professor (By courtesy),Molecular & Cellular Physiology"}],"primaryAppointment":"Professor,Otolaryngology (Head and Neck Surgery)","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=7527&type=small&showNoImage","displayName":"Anthony Ricci","firstName":"Anthony","href":"http://med.stanford.edu/profiles/Anthony_Ricci","researchInterest":"The auditory sensory cell, the hair cell, detects mechanical stimulation at the atomic level and conveys information regarding frequency and intensity to the brain with high fidelity. Our interests are in identifying specializations associated with mechanotransduction and synaptic transmission leading to the amazing sensitivities of the auditory system. We are also interested in the developmental process, particularly in how development gives insight into repair and regenerative mechanisms."},{"lastName":"Ding","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor,Neurology & Neurological Sciences"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Assistant Professor,Neurology & Neurological Sciences","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=32293&type=small&showNoImage","displayName":"Jun Ding","firstName":"Jun","href":"http://med.stanford.edu/profiles/Jun_Ding","researchInterest":"Neural circuits of movement control in health and movement disorders"},{"lastName":"Lee","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Bioengineering"}],"primaryAppointment":"Postdoctoral Research fellow, Bioengineering","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=23467&type=small&showNoImage","displayName":"Soo Yeun Lee","firstName":"Soo Yeun","href":"http://med.stanford.edu/profiles/Soo Yeun_Lee","researchInterest":""},{"lastName":"Aoto","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Neurosciences Institute"}],"primaryAppointment":"Postdoctoral Research fellow, Neurosciences Institute","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=14864&type=small&showNoImage","displayName":"Jason Aoto","firstName":"Jason","href":"http://med.stanford.edu/profiles/Jason_Aoto","researchInterest":""},{"lastName":"MacIver","clinicalFocus":[],"appointments":[{"appointment":"Professor (Research),Anesthesia"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Professor (Research),Anesthesia","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4009&type=small&showNoImage","displayName":"M Bruce MacIver","firstName":"M","href":"http://med.stanford.edu/profiles/M_MacIver","researchInterest":"We study drug effects on the nervous system. Cellular, synaptic and molecular drug actions are investigated using electrophysiological and pharmacological tools in cortical/hippocampal brain slice preparations. We are also interested in mechanisms of neuronal integration and synchronization, especially related to patterns of EEG activity seen in vivo and in brain slices."},{"lastName":"Palmer","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor,Neurosurgery"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Stanford Cancer Institute"}],"primaryAppointment":"Associate Professor,Neurosurgery","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=5930&type=small&showNoImage","displayName":"Theo Palmer","firstName":"Theo","href":"http://med.stanford.edu/profiles/Theo_Palmer","researchInterest":"For most areas of the mammalian brain, the production of new nerve cells or neurons is restricted to fetal development. However, there are exceptions to the rule. Some areas of the brain continue to make new neurons throughout life. This neurogenesis is mediated by neural stem cells and our research goals are to understand how stem cell activity and fate are controlled. Ultimately, we hope to harness the nascent potential of stem cells to treat neurological injury and disease."},{"lastName":"McConnell","clinicalFocus":[],"appointments":[{"appointment":"Professor,Biology (School of Humanities and Sciences)"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Professor,Biology (School of Humanities and Sciences)","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=5928&type=small&showNoImage","displayName":"Susan K. McConnell","firstName":"Susan","href":"http://med.stanford.edu/profiles/Susan_McConnell","researchInterest":"The McConnell Lab studies the cellular and molecular mechanisms that underlie the development of the mammalian cerebral cortex.  Our work focuses on the earliest events that pattern the developing forebrain, enable neural progenitors to divide asymmetrically to generate young neurons, propel the migration of postmitotic neurons outward into their final positions, and sculpt the fates and phenotypes of the neurons as they differentiate."},{"lastName":"Giocomo","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor,Neurobiology"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Assistant Professor,Neurobiology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=35065&type=small&showNoImage","displayName":"Lisa Giocomo","firstName":"Lisa","href":"http://med.stanford.edu/profiles/Lisa_Giocomo","researchInterest":"My laboratory studies the cellular and molecular mechanisms underlying the organization of cortical circuits important for spatial navigation and memory. We are particularly focused on medial entorhinal cortex, where many neurons fire in spatially specific patterns and thus offer a measurable output for molecular manipulations. We combine electrophysiology, genetic approaches and behavioral paradigms to unravel the mechanisms and behavioral relevance of non-sensory cortical organization. Our fi"},{"lastName":"Kerchner","clinicalFocus":[{"focus":"Alzheimer's Disease"},{"focus":"Mild Cognitive Impairment"},{"focus":"Dementia"},{"focus":"Behavioral Neurology"},{"focus":"Neurodegenerative Disease"},{"focus":"Neuropsychology"},{"focus":"Neurology"}],"appointments":[{"appointment":"Assistant Professor - Med Center Line,Neurology & Neurological Sciences"}],"primaryAppointment":"Assistant Professor - Med Center Line,Neurology & Neurological Sciences","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=15338&type=small&showNoImage","displayName":"Geoffrey Kerchner","firstName":"Geoffrey","href":"http://med.stanford.edu/profiles/Geoffrey_Kerchner","researchInterest":"Dr. Kerchner is a behavioral neurologist who cares for patients with Alzheimer's disease and other age-related neurodegenerative illnesses. He studies the use of ultra-high field MRI and other advanced neuroimaging technologies to reveal how these diseases affect the microscopic structure and circuitry of the brain, with the intent of creating new strategies for early diagnosis. Dr. Kerchner also supervises the participation of patients in clinical trials for Alzheimer\u0092s disease."},{"lastName":"Hestrin","clinicalFocus":[],"appointments":[{"appointment":"Professor,Comparative Medicine"}],"primaryAppointment":"Professor,Comparative Medicine","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4343&type=small&showNoImage","displayName":"Shaul Hestrin","firstName":"Shaul","href":"http://med.stanford.edu/profiles/Shaul_Hestrin","researchInterest":"The main interest of my lab is to understand how the properties of neocortical neurons and the circuits they form give rise to cortical activity and function. Our approach includes recordings from multiple cells, calcium imaging, two-photon imaging and viral-based optogenetic methods to activate  cortical neurons as well as cortical afferents."},{"lastName":"Huguenard","clinicalFocus":[],"appointments":[{"appointment":"Professor,Neurology & Neurological Sciences"},{"appointment":"Member,Child Health Research Institute"},{"appointment":"Member,Bio-X"},{"appointment":"Professor (By courtesy),Molecular & Cellular Physiology"}],"primaryAppointment":"Professor,Neurology & Neurological Sciences","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4124&type=small&showNoImage","displayName":"John Huguenard","firstName":"John","href":"http://med.stanford.edu/profiles/John_Huguenard","researchInterest":"We are interested in the neuronal mechanisms that underlie synchronous oscillatory activity in the thalamus, cortex and the massively interconnected thalamocortical system. Such oscillations are related to cognitive processes, normal sleep activities and certain forms of epilepsy. Our approach is an analysis of the discrete components (cells, synapses, microcircuits) that make up thalamic and cortical circuits, and reconstitution of components into in silico computational networks."},{"lastName":"Prince","clinicalFocus":[],"appointments":[{"appointment":"Professor,Neurology & Neurological Sciences"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Professor,Neurology & Neurological Sciences","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4531&type=small&showNoImage","displayName":"David Prince","firstName":"David","href":"http://med.stanford.edu/profiles/David_Prince","researchInterest":"Experiments examine \r\n1)intrinsic properties of neuronal membranes; actions of neurotransmitters that regulate neocortical and thalamic excitability\r\n2) chronic epileptogenesis following cortical injury; changes in intracortical connectivity and receptors; \r\n3) effects of early injury and activity on cortical development/maldevelopment Electrophysiological, anatomical and pharmacological techniques employed.\r\n4. prophylaxis of postraumatic epilepsy\r\n5. Neocortical interneuronal function/modulation"},{"lastName":"Malenka","clinicalFocus":[],"appointments":[{"appointment":"Professor,Psychiatry & Behavioral Science - Psychiatry/Neuroscience/MSLS"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Professor,Psychiatry & Behavioral Science - Psychiatry/Neuroscience/MSLS","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4670&type=small&showNoImage","displayName":"Robert Malenka","firstName":"Robert","href":"http://med.stanford.edu/profiles/Robert_Malenka","researchInterest":"Long-lasting changes in synaptic strength are important for the modification of neural circuits by experience. A major goal of my laboratory is to elucidate the molecular events that trigger various forms of synaptic plasticity and the modifications in synaptic proteins that are responsible for the changes in synaptic efficacy."},{"lastName":"Li","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Molecular & Cellular Physiology"}],"primaryAppointment":"Postdoctoral Research fellow, Molecular & Cellular Physiology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=35683&type=small&showNoImage","displayName":"Dong Li","firstName":"Dong","href":"http://med.stanford.edu/profiles/Dong_Li","researchInterest":""},{"lastName":"Leone-Haditsch","clinicalFocus":[],"appointments":[{"appointment":"Instructor,Neurosurgery"}],"primaryAppointment":"Instructor,Neurosurgery","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=23617&type=small&showNoImage","displayName":"Ursula Haditsch","firstName":"Ursula","href":"http://med.stanford.edu/profiles/Ursula_Leone-Haditsch","researchInterest":""},{"lastName":"Lindley","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor - Med Center Line,Psychiatry & Behavioral Science - Stanford/VA Aging Clinical Research Center"}],"primaryAppointment":"Assistant Professor - Med Center Line,Psychiatry & Behavioral Science - Stanford/VA Aging Clinical Research Center","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=6056&type=small&showNoImage","displayName":"Steven Lindley","firstName":"Steven","href":"http://med.stanford.edu/profiles/Steven_Lindley","researchInterest":"Maximizing the use of evidence-based practices and reducing unnecessary medical burden of psychiatric treatments for stress-related disorders."},{"lastName":"Bergen","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Bioengineering"}],"primaryAppointment":"Postdoctoral Research fellow, Bioengineering","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=29500&type=small&showNoImage","displayName":"Jamie Bergen","firstName":"Jamie","href":"http://med.stanford.edu/profiles/Jamie_Bergen","researchInterest":"The knottin family offers a diverse array of molecular scaffolds that can be engineered to guide imaging agents and drugs to sites of disease.  My research focuses on using knottins as a platform to design targeted drug therapies, and I am studying the delivery characteristics of engineered knottin-drug conjugates in relevant disease models."},{"lastName":"Deisseroth","clinicalFocus":[{"focus":"Psychiatry"}],"appointments":[{"appointment":"Assistant Professor,Bioengineering"},{"appointment":"Professor,Bioengineering"},{"appointment":"Member,Bio-X"},{"appointment":"Professor,Psychiatry & Behavioral Science"}],"primaryAppointment":"Assistant Professor,Bioengineering","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=6080&type=small&showNoImage","displayName":"Karl Deisseroth","firstName":"Karl","href":"http://med.stanford.edu/profiles/Karl_Deisseroth","researchInterest":"Research in Dr. Deisseroth's laboratory focuses on developing optical, molecular and cellular tools to observe, perturb, and re-engineer brain circuits. His laboratory is based in the James H. Clark Center at Stanford and has developed optogenetic and tissue engineering methods, employing techniques spanning electrophysiology, molecular biology, optics, neural activity imaging, animal behavior, and computational neural network modeling."},{"lastName":"Carson","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Psychiatry & Behavioral Science"}],"primaryAppointment":"Postdoctoral Research fellow, Psychiatry & Behavioral Science","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=24009&type=small&showNoImage","displayName":"Dean S. Carson","firstName":"Dean","href":"http://med.stanford.edu/profiles/Dean_Carson","researchInterest":"The neuropeptide oxytocin has been implicated in a wide range of social behaviors including attachment bonds, emotion recognition, eye gaze to social cues, and memory for social information. My research aims to determine the underlying biological mechanisms of oxytocin's action on both brain and behavior and to determine the effectiveness of its use in treating autism. My research is conducted using translational methodology including both preclinical animal models and clinical treatment trials."},{"lastName":"Chen","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Neurosciences Institute"}],"primaryAppointment":"Postdoctoral Research fellow, Neurosciences Institute","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=20866&type=small&showNoImage","displayName":"Lulu Chen","firstName":"Lulu","href":"http://med.stanford.edu/profiles/Lulu_Chen","researchInterest":""},{"lastName":"Meyer","clinicalFocus":[],"appointments":[{"appointment":"Professor,Chemical and Systems Biology"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Professor,Chemical and Systems Biology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4007&type=small&showNoImage","displayName":"Tobias Meyer","firstName":"Tobias","href":"http://med.stanford.edu/profiles/Tobias_Meyer","researchInterest":"CELLULAR INFORMATION PROCESSING  The main problem in signal transduction is to understand how different receptor-stimuli specifically control diverse cell functions. We are using automated microscopy, live-cell fluorescent biosensors and perturbations of predicted signaling proteins to systematically dissect signaling networks.  This allows us to identify signaling modules and to elucidate and ultimately model the flow of cellular information."},{"lastName":"Graber","clinicalFocus":[{"focus":"Neurology"}],"appointments":[{"appointment":"Clinical Associate Professor,Neurology & Neurological Sciences"}],"primaryAppointment":"Clinical Associate Professor,Neurology & Neurological Sciences","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=6061&type=small&showNoImage","displayName":"Kevin Graber, M.D.","firstName":"Kevin","href":"http://med.stanford.edu/profiles/Kevin_Graber","researchInterest":""}]}