BIOMAT Database Logo BIOMAT Database Logo

Influence of striate lesions on visually evoked activity in tree shrew temporal cortex. 1979

P G Kaufmann, and P S Blum, and G G Somjen

UI MeSH Term Description Entries
D008297 Male Males
D009474 Neurons The basic cellular units of nervous tissue. Each neuron consists of a body, an axon, and dendrites. Their purpose is to receive, conduct, and transmit impulses in the NERVOUS SYSTEM. Nerve Cells,Cell, Nerve,Cells, Nerve,Nerve Cell,Neuron
D010775 Photic Stimulation Investigative technique commonly used during ELECTROENCEPHALOGRAPHY in which a series of bright light flashes or visual patterns are used to elicit brain activity. Stimulation, Photic,Visual Stimulation,Photic Stimulations,Stimulation, Visual,Stimulations, Photic,Stimulations, Visual,Visual Stimulations
D012160 Retina The ten-layered nervous tissue membrane of the eye. It is continuous with the OPTIC NERVE and receives images of external objects and transmits visual impulses to the brain. Its outer surface is in contact with the CHOROID and the inner surface with the VITREOUS BODY. The outer-most layer is pigmented, whereas the inner nine layers are transparent. Ora Serrata
D004292 Dominance, Cerebral Dominance of one cerebral hemisphere over the other in cerebral functions. Cerebral Dominance,Hemispheric Specialization,Dominances, Cerebral,Specialization, Hemispheric
D005071 Evoked Potentials Electrical responses recorded from nerve, muscle, SENSORY RECEPTOR, or area of the CENTRAL NERVOUS SYSTEM following stimulation. They range from less than a microvolt to several microvolts. The evoked potential can be auditory (EVOKED POTENTIALS, AUDITORY), somatosensory (EVOKED POTENTIALS, SOMATOSENSORY), visual (EVOKED POTENTIALS, VISUAL), or motor (EVOKED POTENTIALS, MOTOR), or other modalities that have been reported. Event Related Potential,Event-Related Potentials,Evoked Potential,N100 Evoked Potential,P50 Evoked Potential,N1 Wave,N100 Evoked Potentials,N2 Wave,N200 Evoked Potentials,N3 Wave,N300 Evoked Potentials,N4 Wave,N400 Evoked Potentials,P2 Wave,P200 Evoked Potentials,P50 Evoked Potentials,P50 Wave,P600 Evoked Potentials,Potentials, Event-Related,Event Related Potentials,Event-Related Potential,Evoked Potential, N100,Evoked Potential, N200,Evoked Potential, N300,Evoked Potential, N400,Evoked Potential, P200,Evoked Potential, P50,Evoked Potential, P600,Evoked Potentials, N100,Evoked Potentials, N200,Evoked Potentials, N300,Evoked Potentials, N400,Evoked Potentials, P200,Evoked Potentials, P50,Evoked Potentials, P600,N1 Waves,N2 Waves,N200 Evoked Potential,N3 Waves,N300 Evoked Potential,N4 Waves,N400 Evoked Potential,P2 Waves,P200 Evoked Potential,P50 Waves,P600 Evoked Potential,Potential, Event Related,Potential, Event-Related,Potential, Evoked,Potentials, Event Related,Potentials, Evoked,Potentials, N400 Evoked,Related Potential, Event,Related Potentials, Event,Wave, N1,Wave, N2,Wave, N3,Wave, N4,Wave, P2,Wave, P50,Waves, N1,Waves, N2,Waves, N3,Waves, N4,Waves, P2,Waves, P50
D005260 Female Females
D000818 Animals Unicellular or multicellular, heterotrophic organisms, that have sensation and the power of voluntary movement. Under the older five kingdom paradigm, Animalia was one of the kingdoms. Under the modern three domain model, Animalia represents one of the many groups in the domain EUKARYOTA. Animal,Metazoa,Animalia
D013702 Temporal Lobe Lower lateral part of the cerebral hemisphere responsible for auditory, olfactory, and semantic processing. It is located inferior to the lateral fissure and anterior to the OCCIPITAL LOBE. Anterior Temporal Lobe,Brodmann Area 20,Brodmann Area 21,Brodmann Area 22,Brodmann Area 37,Brodmann Area 38,Brodmann Area 52,Brodmann's Area 20,Brodmann's Area 21,Brodmann's Area 22,Brodmann's Area 37,Brodmann's Area 38,Brodmann's Area 52,Inferior Temporal Gyrus,Middle Temporal Gyrus,Parainsular Area,Fusiform Gyrus,Gyrus Fusiformis,Gyrus Temporalis Superior,Inferior Horn of Lateral Ventricle,Inferior Horn of the Lateral Ventricle,Lateral Occipito-Temporal Gyrus,Lateral Occipitotemporal Gyrus,Occipitotemporal Gyrus,Planum Polare,Superior Temporal Gyrus,Temporal Cortex,Temporal Gyrus,Temporal Horn,Temporal Horn of the Lateral Ventricle,Temporal Operculum,Temporal Region,Temporal Sulcus,Anterior Temporal Lobes,Area 20, Brodmann,Area 20, Brodmann's,Area 21, Brodmann,Area 21, Brodmann's,Area 22, Brodmann,Area 22, Brodmann's,Area 37, Brodmann,Area 37, Brodmann's,Area 38, Brodmann,Area 38, Brodmann's,Area 52, Brodmann,Area 52, Brodmann's,Area, Parainsular,Areas, Parainsular,Brodmanns Area 20,Brodmanns Area 21,Brodmanns Area 22,Brodmanns Area 37,Brodmanns Area 38,Brodmanns Area 52,Cortex, Temporal,Gyrus, Fusiform,Gyrus, Inferior Temporal,Gyrus, Lateral Occipito-Temporal,Gyrus, Lateral Occipitotemporal,Gyrus, Middle Temporal,Gyrus, Occipitotemporal,Gyrus, Superior Temporal,Gyrus, Temporal,Horn, Temporal,Lateral Occipito Temporal Gyrus,Lobe, Anterior Temporal,Lobe, Temporal,Occipito-Temporal Gyrus, Lateral,Occipitotemporal Gyrus, Lateral,Operculum, Temporal,Parainsular Areas,Region, Temporal,Sulcus, Temporal,Temporal Cortices,Temporal Gyrus, Inferior,Temporal Gyrus, Middle,Temporal Gyrus, Superior,Temporal Horns,Temporal Lobe, Anterior,Temporal Lobes,Temporal Lobes, Anterior,Temporal Regions
D014418 Tupaiidae The only family of the order SCANDENTIA, variously included in the order Insectivora or in the order Primates, and often in the order Microscelidea, consisting of five genera. They are TUPAIA, Ananthana (Indian tree shrew), Dendrogale (small smooth-tailed tree shrew), Urogale (Mindanao tree shrew), and Ptilocercus (pen-tailed tree shrew). The tree shrews inhabit the forest areas of eastern Asia from India and southwestern China to Borneo and the Philippines. Ptilocercus,Shrews, Tree,Tree Shrews,Tupaiinae,Treeshrews,Shrew, Tree,Tree Shrew,Treeshrew

Related Publications

P G Kaufmann, and P S Blum, and G G Somjen
Function of striate and temporal cortex in the tree shrew.
January 1971, Journal of comparative and physiological psychology,
P G Kaufmann, and P S Blum, and G G Somjen
Organization of ocular dominance in tree shrew striate cortex.
October 1977, Brain research,
P G Kaufmann, and P S Blum, and G G Somjen
Functional specificity of callosal connections in tree shrew striate cortex.
March 2000, The Journal of neuroscience : the official journal of the Society for Neuroscience,
P G Kaufmann, and P S Blum, and G G Somjen
Visually evoked calcium action potentials in cat striate cortex.
December 1995, Nature,
P G Kaufmann, and P S Blum, and G G Somjen
Ultrastructure of geniculocortical synaptic connections in the tree shrew striate cortex.
April 2016, The Journal of comparative neurology,
P G Kaufmann, and P S Blum, and G G Somjen
Visually evoked responses in extrastriate area MT after lesions of striate cortex in early life.
July 2013, The Journal of neuroscience : the official journal of the Society for Neuroscience,
P G Kaufmann, and P S Blum, and G G Somjen
The morphological basis for binocular and ON/OFF convergence in tree shrew striate cortex.
April 1992, The Journal of neuroscience : the official journal of the Society for Neuroscience,
P G Kaufmann, and P S Blum, and G G Somjen
Further studies of the striate and extrastriate visual cortex in the tree shrew.
October 1972, Journal of comparative and physiological psychology,
P G Kaufmann, and P S Blum, and G G Somjen
Orientation selectivity and the arrangement of horizontal connections in tree shrew striate cortex.
March 1997, The Journal of neuroscience : the official journal of the Society for Neuroscience,
P G Kaufmann, and P S Blum, and G G Somjen
On the postnatal development of the striate cortex (V1) in the tree shrew (Tupaia belangeri).
July 2006, The European journal of neuroscience,
Copied contents to your clipboard!