Her primary areas of investigation include Cerebral cortex, Neuroscience, Serotonin, Somatosensory system and Monoamine oxidase A. Her Cerebral cortex research includes themes of Neocortex, Anatomy, Ganglionic eminence, Cortex and Cell biology. Tania Vitalis combines subjects such as Corticogenesis, P chlorophenylalanine and Interneuron with her study of Ganglionic eminence.
Her studies link Postsynaptic potential with Neuroscience. Her work deals with themes such as Endocrinology, Sensory system and Clorgyline, which intersect with Monoamine oxidase A. Her work on Neuroglia as part of general Endocrinology research is often related to Immunostaining, thus linking different fields of science.
Her primary areas of study are Neuroscience, Cerebral cortex, Ganglionic eminence, Cortex and Cell biology. Her Neuroscience study often links to related topics such as Serotonin. Her Cerebral cortex research includes elements of Glutamatergic, Cerebrum and Sensory system.
While the research belongs to areas of Ganglionic eminence, she spends her time largely on the problem of Biocytin, intersecting her research to questions surrounding Parvalbumin. Her work in Cortex addresses subjects such as Anatomy, which are connected to disciplines such as Forebrain and Diencephalon. Her studies in Cell biology integrate themes in fields like Reelin, Gene expression and Immunology.
The scientist’s investigation covers issues in Neuroscience, Endocannabinoid system, Hippocampus, Orphan receptor and Phenotype. Her Neuroscience study frequently draws connections to adjacent fields such as Glutamatergic. Her Endocannabinoid system study integrates concerns from other disciplines, such as Synaptic plasticity, Long-term potentiation, Cannabinoid and Hippocampal formation.
Her Cerebral cortex research is multidisciplinary, relying on both Primate, Neuroprotection and Serotonin. The concepts of her Neocortex study are interwoven with issues in Endocrinology, Electrophysiology, Anatomy, GABAergic and Interneuron. Her Interneuron migration research is under the purview of Ganglionic eminence.
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Lack of Barrels in the Somatosensory Cortex of Monoamine Oxidase A-Deficient Mice: Role of a Serotonin Excess during the Critical Period
Olivier Cases;Tania Vitalis;Isabelle Seif;Edward De Maeyer.
Control of cortical interneuron migration by neurotrophins and PI3-kinase signaling.
Franck Polleux;Kristin L. Whitford;Paul A. Dijkhuizen;Tania Vitalis.
PLC-β1, activated via mGluRs, mediates activity-dependent differentiation in cerebral cortex
Anthony J. Hannan;Colin Blakemore;Alla Katsnelson;Tania Vitalis.
Nature Neuroscience (2001)
Plasma Membrane Transporters of Serotonin, Dopamine, and Norepinephrine Mediate Serotonin Accumulation in Atypical Locations in the Developing Brain of Monoamine Oxidase A Knock-Outs
Olivier Cases;Cecile Lebrand;Bruno Giros;Tania Vitalis.
The Journal of Neuroscience (1998)
The role of serotonin in early cortical development.
Tania Vitalis;John G. Parnavelas.
Developmental Neuroscience (2003)
Embryonic depletion of serotonin affects cortical development
Tania Vitalis;Tania Vitalis;Olivier Cases;Sandrine Passemard;Jacques Callebert.
European Journal of Neuroscience (2007)
Effects of monoamine oxidase A inhibition on barrel formation in the mouse somatosensory cortex: determination of a sensitive developmental period.
Tania Vitalis;Olivier Cases;Olivier Cases;Olivier Cases;Jacques Callebert;Jean-Marie Launay.
The Journal of Comparative Neurology (1998)
Serotonin 3A Receptor Subtype as an Early and Protracted Marker of Cortical Interneuron Subpopulations
Ksenija Vucurovic;Thierry Gallopin;Isabelle Ferezou;Armelle Rancillac.
Cerebral Cortex (2010)
A role for Pax6 in the normal development of dorsal thalamus and its cortical connections.
Thomas Pratt;T Vitalis;N Warren;J M Edgar.
Defects of Tyrosine Hydroxylase-Immunoreactive Neurons in the Brains of Mice Lacking the Transcription Factor Pax6
Tania Vitalis;Olivier Cases;Dieter Engelkamp;Catherine Verney.
The Journal of Neuroscience (2000)
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