BIOMAT Database Logo BIOMAT Database Logo

Effect of head tilt on visual cortical cell function in the intact and labyrinthectomized cat. 1986

S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss

The area of the receptive field, its length and width, its position in the visual field, the peristimulus time (PST) histogram (i.e., the response to successive moving light-bar stimuli), the directional preference, the velocity gradient, and the intertrial (spontaneous) firing rate were studied electrophysiologically in complex cortical visual cells in Brodmann's area 18. These characteristics were explored after head tilt, in immobilized cats, both in intact and in bilaterally labyrinthectomized animals. In intact animals (in 64 cells), most of these characteristics changed after head tilts of 10, 20, 30, or 40 degrees to the right or to the left of the horizontal plane. There was always one specific head position in which the receptive field area was at its smallest. In labyrinthectomized animals (in 29 cells), the lengths, widths, and the areas of the receptive fields were only minimally altered during identical tilts. Similarly, in the labyrinthectomized cats, head tilts (40 degrees, to the right or left) caused no substantial changes in the shape and duration of the PST histogram, compared with those in intact cats. No two visual cortical cells responded to head tilts in exactly the same manner. Such uniqueness in response is probably of importance during visual image analysis; in particular, as it relates to cortical reconstruction of stable visual images during continuously changing head movements and positions.

UI MeSH Term Description Entries
D007758 Ear, Inner The essential part of the hearing organ consists of two labyrinthine compartments: the bony labyrinthine and the membranous labyrinth. The bony labyrinth is a complex of three interconnecting cavities or spaces (COCHLEA; VESTIBULAR LABYRINTH; and SEMICIRCULAR CANALS) in the TEMPORAL BONE. Within the bony labyrinth lies the membranous labyrinth which is a complex of sacs and tubules (COCHLEAR DUCT; SACCULE AND UTRICLE; and SEMICIRCULAR DUCTS) forming a continuous space enclosed by EPITHELIUM and connective tissue. These spaces are filled with LABYRINTHINE FLUIDS of various compositions. Labyrinth,Bony Labyrinth,Ear, Internal,Inner Ear,Membranous Labyrinth,Bony Labyrinths,Ears, Inner,Ears, Internal,Inner Ears,Internal Ear,Internal Ears,Labyrinth, Bony,Labyrinth, Membranous,Labyrinths,Labyrinths, Bony,Labyrinths, Membranous,Membranous Labyrinths
D011187 Posture The position or physical attitude of the body. Postures
D002415 Cats The domestic cat, Felis catus, of the carnivore family FELIDAE, comprising over 30 different breeds. The domestic cat is descended primarily from the wild cat of Africa and extreme southwestern Asia. Though probably present in towns in Palestine as long ago as 7000 years, actual domestication occurred in Egypt about 4000 years ago. (From Walker's Mammals of the World, 6th ed, p801) Felis catus,Felis domesticus,Domestic Cats,Felis domestica,Felis sylvestris catus,Cat,Cat, Domestic,Cats, Domestic,Domestic Cat
D004594 Electrophysiology The study of the generation and behavior of electrical charges in living organisms particularly the nervous system and the effects of electricity on living organisms.
D006257 Head The upper part of the human body, or the front or upper part of the body of an animal, typically separated from the rest of the body by a neck, and containing the brain, mouth, and sense organs. Heads
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
D013997 Time Factors Elements of limited time intervals, contributing to particular results or situations. Time Series,Factor, Time,Time Factor
D014793 Visual Cortex Area of the OCCIPITAL LOBE concerned with the processing of visual information relayed via VISUAL PATHWAYS. Area V2,Area V3,Area V4,Area V5,Associative Visual Cortex,Brodmann Area 18,Brodmann Area 19,Brodmann's Area 18,Brodmann's Area 19,Cortical Area V2,Cortical Area V3,Cortical Area V4,Cortical Area V5,Secondary Visual Cortex,Visual Cortex Secondary,Visual Cortex V2,Visual Cortex V3,Visual Cortex V3, V4, V5,Visual Cortex V4,Visual Cortex V5,Visual Cortex, Associative,Visual Motion Area,Extrastriate Cortex,Area 18, Brodmann,Area 18, Brodmann's,Area 19, Brodmann,Area 19, Brodmann's,Area V2, Cortical,Area V3, Cortical,Area V4, Cortical,Area V5, Cortical,Area, Visual Motion,Associative Visual Cortices,Brodmanns Area 18,Brodmanns Area 19,Cortex Secondary, Visual,Cortex V2, Visual,Cortex V3, Visual,Cortex, Associative Visual,Cortex, Extrastriate,Cortex, Secondary Visual,Cortex, Visual,Cortical Area V3s,Extrastriate Cortices,Secondary Visual Cortices,V3, Cortical Area,V3, Visual Cortex,V4, Area,V4, Cortical Area,V5, Area,V5, Cortical Area,V5, Visual Cortex,Visual Cortex Secondaries,Visual Cortex, Secondary,Visual Motion Areas
D014796 Visual Perception The selecting and organizing of visual stimuli based on the individual's past experience. Visual Processing,Perception, Visual,Processing, Visual

Related Publications

S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
Orientation specificity of visual cortical neurons after head tilt.
January 1972, Experimental brain research,
S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
Visual orientation as a function of head tilt.
October 1969, Perceptual and motor skills,
S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
Neural activity, alertness and visual orientation in intact and unilaterally labyrinthectomized rabbits.
January 1987, ORL; journal for oto-rhino-laryngology and its related specialties,
S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
The effect of body tilt on the directionality of units in cat visual cortex.
September 1972, Experimental neurology,
S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
The effect of monocular and binocular observation on visual orientation during head tilt.
September 1969, The American journal of psychology,
S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
[Effect of head-down tilt hypokinesia on human equilibrium function].
January 1981, Kosmicheskaia biologiia i aviakosmicheskaia meditsina,
S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
The effect of head-down tilt on brain potentials related to visual attention.
January 1995, Acta astronautica,
S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
Effect of forward head inclination on visual orientation during lateral body tilt.
November 1972, Journal of experimental psychology,
S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
Effect of passive 70 degrees head-up tilt on peripheral visual response time.
March 1973, Journal of applied physiology,
S Reinis, and J P Landolt, and K E Money, and R H Lahue, and D S Weiss
[Effect of chorionic gonadotropin on adrenal cortical function in intact and gonadectomized rats].
January 1973, Problemy endokrinologii,
Copied contents to your clipboard!