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Dr. Madison holds a Bachelor of Science from the University of California at Irvine (UCI), and a Ph.D. in Neurosciences from the University of California at San Francisco (UCSF). He completed postdoctoral fellowships at UCSF with Dr. Roger Nicoll, M.D. and at Yale University School of Medicine with Dr. Richard W. Tsien, DPhil. He joined the faculty of Stanford University School of Medicine in 1989.
Marine Biological Laboratory, Woods Hole, MA
Graduate Students and Postdoctoral Fellows
Our laboratory is interested in the basic function, plasticity and modulation of Central Nervous System synapses, including studies of the detailed structure and protein content of synapses in different plastic states. We also have a strong interest in the pathophysiology in Azheimer’s disease as related to the functions of endocannabinoids and of the plasticity and myelation of parvalbumin-containing cortical interneurons. We use primarily electrophysiogical techniques along with high-resolution imaging array tomographic imaging to dissect the function of synapses undergoing changes due either to external stimuli, disease states or internal modulation, with an eye to understanding how those changes may affect behavior and memory. Recently, we have also added the approach of single-cell RNA-seq from neurons that we have recorded from.Recent projects in the laboratory include a study of the development and function of myelination in parvalbumin+ interneurons and the nature of their synaptic connection to individual target neurons. We have also studied the role of the amyloid peptide A-beta in modulating synaptic inhibition through an action on the endogenous cannabinoid system of the hippocampus; the role of the Fragile X mental retardation protein in the formation of neural circuits, an array tomographic study on the influence of synaptic plasticity on the number of synapses made in neural microcircuits, and on the localization of AMPA receptor subunits in different states of plasticity.Studies in the lab are carried out using a full range of electrophysiological techniques including extracellular field potential recording, intracellular recording,whole cell and single channel recording in hippocampal slices and cultured neurons. In addition we utilize high resolution imaging of synaptically connected pairs of neurons using array tomography techniques. We are just beginning to study the gene expression properties of the same individual neurons we record from and develop array tomographic reconstructions from.