{"result":[{"lastName":"de Lecea","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor,Psychiatry & Behavioral Science - Sleep Center"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Associate Professor,Psychiatry & Behavioral Science - Sleep Center","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=7308&type=small&showNoImage","displayName":"Luis de Lecea","firstName":"Luis","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Luis_de Lecea","researchInterest":"Our group initially identified the hypocretins, two hypothalamic neuropeptides that have a key role in maintaining the states of vigilance. We also discovered cortistatin, a peptide that modulates cortical excitability. My lab uses molecular, pharmacological, anatomical and behavioral methods to identify new roles for these transmitters. We are also interested in the cellular and molecular mechanisms by which neuronal systems integrate homeostatic information and regulate complex behaviors."},{"lastName":"Huguenard","clinicalFocus":[],"appointments":[{"appointment":"Professor,Neurology & Neurological Sciences"},{"appointment":"Professor (By courtesy),Molecular & Cellular Physiology"},{"appointment":"Member,Bio-X"}],"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/neuroscience/researcher/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":"Zeitzer","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor,Psychiatry & Behavioral Science - VA & Geriatric"}],"primaryAppointment":"Assistant Professor,Psychiatry & Behavioral Science - VA & Geriatric","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=7863&type=small&showNoImage","displayName":"Jamie Zeitzer","firstName":"Jamie","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Jamie_Zeitzer","researchInterest":"Dr. Zeitzer's research concerns examination of human and primate circadian rhythms and sleep; notably, the neural mechanisms that underlie wakefulness and circadian photoreception.  He is also involved in collaborative efforts in examining the role of sleep disruption in medical pathologies such as Alzheimer's disease, spinal cord injury, and breast cancer."},{"lastName":"Tsien","clinicalFocus":[],"appointments":[{"appointment":"Professor,Molecular & Cellular Physiology"}],"primaryAppointment":"Professor,Molecular & Cellular Physiology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4189&type=small&showNoImage","displayName":"Richard Tsien","firstName":"Richard","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Richard_Tsien","researchInterest":"We study synaptic communication between brain cells with the goal of understanding neuronal computations and memory mechanisms. Main areas of focus include: presynaptic calcium channels, mechanisms of vesicular fusion and recycling. Modulation of synaptic strength through changes in postsynaptic receptors and dendritic morphology. Signaling that links synaptic activity to nuclear transcription and local protein translation. Techniques include imaging, electrophysiology, molecular biology."},{"lastName":"Malenka","clinicalFocus":[],"appointments":[{"appointment":"Professor,Psychiatry & Behavioral Science - Psychiatry/Neuroscience/MSLS"}],"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/neuroscience/researcher/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":"Sapolsky","clinicalFocus":[],"appointments":[{"appointment":"Professor,Biology (School of Humanities and Sciences)"},{"appointment":"Professor,Neurology & Neurological Sciences"},{"appointment":"Professor,Neurosurgery"}],"primaryAppointment":"Professor,Biology (School of Humanities and Sciences)","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=6114&type=small&showNoImage","displayName":"Robert Sapolsky","firstName":"Robert","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Robert_Sapolsky","researchInterest":""},{"lastName":"Dement","clinicalFocus":[],"appointments":[{"appointment":"Professor,Psychiatry & Behavioral Science - Sleep Center"},{"appointment":"Professor (By courtesy),Psychology"}],"primaryAppointment":"Professor,Psychiatry & Behavioral Science - Sleep Center","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4532&type=small&showNoImage","displayName":"William C. Dement","firstName":"William","href":"http://med.stanford.edu/profiles/neuroscience/researcher/William_Dement","researchInterest":"Sleep Medicine education and awareness."},{"lastName":"Garner","clinicalFocus":[],"appointments":[{"appointment":"Professor,Psychiatry & Behavioral Science - Psychiatry/Neuroscience/MSLS"},{"appointment":"Professor (By courtesy),Neurology & Neurological Sciences"}],"primaryAppointment":"Professor,Psychiatry & Behavioral Science - Psychiatry/Neuroscience/MSLS","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=3890&type=small&showNoImage","displayName":"Craig C. Garner","firstName":"Craig","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Craig_Garner","researchInterest":"Our laboratory is studying synapse formation, stability and elimination at a variety of levels, e.g. from molecules to behavior.  A primary focus of the lab is to understanding the role that individual molecules play in the assembly and function of synaptic junctions.  In addition we evaluating a variety of potential treatments for cognitive impairment in Down syndrome in part by assessing the impact specific drugs on cognitive function in mouse models of Down syndrome."},{"lastName":"Prince","clinicalFocus":[],"appointments":[{"appointment":"Professor,Neurology & Neurological Sciences"}],"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/neuroscience/researcher/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":"Deisseroth","clinicalFocus":[{"focus":"Psychiatry"}],"appointments":[{"appointment":"Assistant Professor,Bioengineering"},{"appointment":"Associate Professor,Bioengineering"},{"appointment":"Associate Professor,Psychiatry & Behavioral Science"},{"appointment":"Member,Bio-X"}],"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/neuroscience/researcher/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":"MacIver","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor (Research),Anesthesia"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Associate 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/neuroscience/researcher/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":"Pang","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Neurosciences Institute"}],"primaryAppointment":"Postdoctoral Research fellow, Neurosciences Institute","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=9396&type=small&showNoImage","displayName":"Zhiping Pang","firstName":"Zhiping","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Zhiping_Pang","researchInterest":""},{"lastName":"Goddard","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Neurobiology"}],"primaryAppointment":"Postdoctoral Research fellow, Neurobiology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=8925&type=small&showNoImage","displayName":"Carson Goddard","firstName":"Carson","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Carson_Goddard","researchInterest":""},{"lastName":"Sudhof","clinicalFocus":[],"appointments":[{"appointment":"Professor,Molecular & Cellular Physiology"},{"appointment":"Professor (By courtesy),Neurology & Neurological Sciences"},{"appointment":"Professor (By courtesy),Psychiatry & Behavioral Science"}],"primaryAppointment":"Professor,Molecular & Cellular Physiology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=8533&type=small&showNoImage","displayName":"Thomas Sudhof","firstName":"Thomas","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Thomas_Sudhof","researchInterest":"Information transfer at synapses mediates information processing in brain, and is impaired in many brain diseases. Thomas Südhof is interested in how synapses are formed, how presynaptic terminals release neurotransmitters at synapses, and how synapses become dysfunctional in diseases such as autism or Alzheimer's disease. To address these questions, Südhof's laboratory employs approaches ranging from biophysical studies to the electrophysiological and behavioral analyses of mutant mice."},{"lastName":"Madison","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor,Molecular & Cellular Physiology"}],"primaryAppointment":"Associate Professor,Molecular & Cellular Physiology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4321&type=small&showNoImage","displayName":"Daniel V. Madison","firstName":"Vernon","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Vernon_Madison","researchInterest":"Our laboratory uses electrophysiological techniques to study the mechanisms of synaptic transmission and plasticity in the mammalian hippocampus. One of the main focuses in the lab is in the study of synaptic long-term potentiation (LTP). LTP is the persistent increase in synaptic strength that occurs after a period of heavy activity in a synaptic connection. It is the most widely studied and compelling model for mechanisms underlying memory formation in the mammalian central nervous system."},{"lastName":"Cheng","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Biology (School of Humanities and Sciences)"}],"primaryAppointment":"Postdoctoral Research fellow, Biology (School of Humanities and Sciences)","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=8752&type=small&showNoImage","displayName":"Michelle Cheng","firstName":"Michelle","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Michelle_Cheng","researchInterest":""},{"lastName":"Palmer","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor,Neurosurgery"},{"appointment":"Member,Bio-X"},{"appointment":"Member,Cancer Center"}],"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/neuroscience/researcher/Theo_Palmer","researchInterest":"For most areas of the mammalian brain, neurogenesis concludes at birth but there are exceptions to the rule. In rodents and humans, some areas of the brain continue to make new neurons throughout life. This process is mediated by neural stem cells and our research goals are to understand how stem cell activity is regulated and whether the nascent potential of resident stem cells can be harnessed for brain repair."},{"lastName":"Sohal","clinicalFocus":[{"focus":"Psychiatry"}],"appointments":[{"appointment":"Instructor,Psychiatry & Behavioral Science - Psychopharmacology"}],"primaryAppointment":"Instructor,Psychiatry & Behavioral Science - Psychopharmacology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=10396&type=small&showNoImage","displayName":"Vikaas Sohal","firstName":"Vikaas","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Vikaas_Sohal","researchInterest":""},{"lastName":"Dhabhar","clinicalFocus":[],"appointments":[{"appointment":"Associate Professor,Psychiatry & Behavioral Science - Psychosocial"}],"primaryAppointment":"Associate Professor,Psychiatry & Behavioral Science - Psychosocial","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=7313&type=small&showNoImage","displayName":"Firdaus Dhabhar","firstName":"Firdaus","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Firdaus_Dhabhar","researchInterest":"Although stress has a \"bad reputation,\" a physiological stress is response is nature's fundamental survival system. We are interested in identifying mechanisms that mediate and differentiate the recently appreciated immunoenhancing effects of short-term stress from the long-known immunosuppressive effects of chronic stress. We examine stress effects on leukocyte trafficking, innate/adaptive immunity, and cytokine gene/protein expression using models of skin immunity, surgery, and cancer."},{"lastName":"Barres","clinicalFocus":[],"appointments":[{"appointment":"Professor,Neurobiology"},{"appointment":"Professor,Neurology & Neurological Sciences"},{"appointment":"Professor (By courtesy),Ophthalmology"},{"appointment":"Member,Bio-X"},{"appointment":"Professor,Developmental Biology"}],"primaryAppointment":"Professor,Neurobiology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4239&type=small&showNoImage","displayName":"Ben Barres","firstName":"Ben","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Ben_Barres","researchInterest":"Our lab is interested in the neuronal-glial interactions that underlie the development and function of the mammlian central nervous system."},{"lastName":"Dolmetsch","clinicalFocus":[],"appointments":[{"appointment":"Assistant Professor,Neurobiology"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Assistant Professor,Neurobiology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4040&type=small&showNoImage","displayName":"Ricardo Dolmetsch","firstName":"Ricardo","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Ricardo_Dolmetsch","researchInterest":"Our lab studies the underlying neurobiology of autism and other neuro-developmental disorders.  We are particularly interested in understanding how electrical activity and calcium signals control the development of the brain and how this is altered in children with autism spectrum disorders. We are also developing new tools to study and repair the developing brain."},{"lastName":"Schwartz","clinicalFocus":[{"focus":"Neurology"}],"appointments":[{"appointment":"Clinical Assistant Professor,Neurology & Neurological Sciences"}],"primaryAppointment":"Clinical Assistant Professor,Neurology & Neurological Sciences","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=6749&type=small&showNoImage","displayName":"Neil Schwartz","firstName":"Neil","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Neil_Schwartz","researchInterest":"My clinical interests involve inpatient and outpatient care of patients with neurovascular diseases, mostly ischemic and hemorrhagic stroke. I have a particular interest in cervical artery dissection and stroke in the young. My research interests include novel imaging techniques for assessing patients with stroke and subarachnoid hemorrhage."},{"lastName":"Clark","clinicalFocus":[],"appointments":[{"appointment":"Postdoctoral Research fellow, Neurobiology"}],"primaryAppointment":"Postdoctoral Research fellow, Neurobiology","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=8632&type=small&showNoImage","displayName":"Damon Clark","firstName":"Damon","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Damon_Clark","researchInterest":""},{"lastName":"Nishino","clinicalFocus":[],"appointments":[{"appointment":"Professor (Research),Psychiatry & Behavioral Science - Sleep Center"}],"primaryAppointment":"Professor (Research),Psychiatry & Behavioral Science - Sleep Center","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4029&type=small&showNoImage","displayName":"Seiji Nishino","firstName":"Seiji","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Seiji_Nishino","researchInterest":"The research focus of the Sleep and Circadian Neurobiology (SCN) Laboratory is the study of the sleep and circadian physiology using various animal models. A portion of the research is carried out using rodent models of narcolepsy and circadian rhythm sleep disorders. The laboratory also carries out pharmacological studies aiming to develop new treatments for these sleep disorders."},{"lastName":"Giffard","clinicalFocus":[],"appointments":[{"appointment":"Professor,Anesthesia"},{"appointment":"Member,Bio-X"}],"primaryAppointment":"Professor,Anesthesia","imageUrl":"http://med.stanford.edu/profiles/viewImage?facultyId=4657&type=small&showNoImage","displayName":"Rona Giffard","firstName":"Rona","href":"http://med.stanford.edu/profiles/neuroscience/researcher/Rona_Giffard","researchInterest":"The cellular and molecular basis for brain cell injury in stroke is our focus.  Astrocytes and neurons interact, and have unique vulnerabilities to injury based on their patterns of gene expression and their functional roles.  We study gene therapy with heat shock proteins, changes in mitochondrial function, oxidative stress and inflammation during ischemia. We also model cell death pathways and the effects of Hsp70."}]}