BIOMAT Database Logo BIOMAT Database Logo

Transcerebellar inhibitory interaction between the bilateral vestibular nuclei and its modulation by cerebellocortical activity. 1976

N Furuya, and K Kawano, and H Shimazu

In decerebrate, unanesthetized cats, the brain stem was longitudinally cut at the midline from its dorsal to ventral surface with the cerebellum kept intact, eliminating neural interactions between the bilateral vestibular nuclei through the brain stem. Extracellular spike potentials of vestibular type I neurons identified by horizontal rotation were distinctly inhibited by contralateral vestibular nerve stimulation. This crossed inhibition was abolished by removal of the medial part of the cerebellum, indicating that the inhibition was mediated through the cerebellum. Neither aspiration of the flocculus on the recording side nor intravenous administration of picrotoxin eliminated transcerebellar crossed inhibition, suggesting that it is mediated through the cerebellar nuclei. When the fastigial, interposite and dentate nuclei were stimulated, inhibition of vestibular type I neurons was produced only from the contralateral fastigal nucleus. Cerebellocortical stimulation which inhibited fastigial type I neurons suppressed transcerebellar crossed inhibition. Effective sites for suppression of transcerebellar crossed inhibition were localized to lobules VI and VIIa in the vermal cortex on the side of labyrinthine stimulation. Intracellular recordings were made from type I neurons in the medial vestibular nucleus. Stimulation of the contralateral vestibular nerve and the contralateral fastigial nucleus produced IPSPs in these neurons with the shortest latency of 3.8 msec and 1.8 msec, respectively. The difference between these two latency values approximates the shortest latency of spike initiation of fastigial type I neurons in response to vestibular nerve stimulation. It is postulated that transcerebellar crossed inhibition is mediated through the fastigial nucleus on the side of labyrinthine stimulation.

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
D008564 Membrane Potentials The voltage differences across a membrane. For cellular membranes they are computed by subtracting the voltage measured outside the membrane from the voltage measured inside the membrane. They result from differences of inside versus outside concentration of potassium, sodium, chloride, and other ions across cells' or ORGANELLES membranes. For excitable cells, the resting membrane potentials range between -30 and -100 millivolts. Physical, chemical, or electrical stimuli can make a membrane potential more negative (hyperpolarization), or less negative (depolarization). Resting Potentials,Transmembrane Potentials,Delta Psi,Resting Membrane Potential,Transmembrane Electrical Potential Difference,Transmembrane Potential Difference,Difference, Transmembrane Potential,Differences, Transmembrane Potential,Membrane Potential,Membrane Potential, Resting,Membrane Potentials, Resting,Potential Difference, Transmembrane,Potential Differences, Transmembrane,Potential, Membrane,Potential, Resting,Potential, Transmembrane,Potentials, Membrane,Potentials, Resting,Potentials, Transmembrane,Resting Membrane Potentials,Resting Potential,Transmembrane Potential,Transmembrane Potential Differences
D009433 Neural Inhibition The function of opposing or restraining the excitation of neurons or their target excitable cells. Inhibition, Neural
D009434 Neural Pathways Neural tracts connecting one part of the nervous system with another. Neural Interconnections,Interconnection, Neural,Interconnections, Neural,Neural Interconnection,Neural Pathway,Pathway, Neural,Pathways, Neural
D010852 Picrotoxin A mixture of PICROTOXININ and PICROTIN that is a noncompetitive antagonist at GABA-A receptors acting as a convulsant. Picrotoxin blocks the GAMMA-AMINOBUTYRIC ACID-activated chloride ionophore. Although it is most often used as a research tool, it has been used as a CNS stimulant and an antidote in poisoning by CNS depressants, especially the barbiturates. 3,6-Methano-8H-1,5,7-trioxacyclopenta(ij)cycloprop(a)azulene-4,8(3H)-dione, hexahydro-2a-hydroxy-9-(1-hydroxy-1-methylethyl)-8b-methyl-, (1aR-(1aalpha,2abeta,3beta,6beta,6abeta,8aS*,8bbeta,9S*))-, compd. with (1aR-(1aalpha,2abeta,3beta,6beta,6abeta,8,Cocculin
D011930 Reaction Time The time from the onset of a stimulus until a response is observed. Response Latency,Response Speed,Response Time,Latency, Response,Reaction Times,Response Latencies,Response Times,Speed, Response,Speeds, Response
D001933 Brain Stem The part of the brain that connects the CEREBRAL HEMISPHERES with the SPINAL CORD. It consists of the MESENCEPHALON; PONS; and MEDULLA OBLONGATA. Brainstem,Truncus Cerebri,Brain Stems,Brainstems,Cerebri, Truncus,Cerebrus, Truncus,Truncus Cerebrus
D002525 Cerebellar Cortex The superficial GRAY MATTER of the CEREBELLUM. It consists of two main layers, the stratum moleculare and the stratum granulosum. Cortex Cerebelli,Cerebelli, Cortex,Cerebellus, Cortex,Cortex Cerebellus,Cortex, Cerebellar
D002529 Cerebellar Nuclei Four clusters of neurons located deep within the WHITE MATTER of the CEREBELLUM, which are the nucleus dentatus, nucleus emboliformis, nucleus globosus, and nucleus fastigii. Dentate Nucleus,Nucleus Dentatus,Nucleus Emboliformis,Nucleus Fastigii,Nucleus Globosus,Amiculum of the Dentate Nucleus,Anterior Interposed Nucleus,Anterior Interpositus Nucleus,Central Nuclei,Deep Cerebellar Nuclei,Dentate Cerebellar Nucleus,Fastigial Cerebellar Nucleus,Fastigial Nucleus,Intracerebellar Nuclei,Lateral Cerebellar Nucleus,Medial Cerebellar Nucleus,Central Nucleus,Cerebellar Nuclei, Deep,Cerebellar Nucleus,Cerebellar Nucleus, Deep,Cerebellar Nucleus, Dentate,Cerebellar Nucleus, Fastigial,Cerebellar Nucleus, Lateral,Cerebellar Nucleus, Medial,Deep Cerebellar Nucleus,Emboliformis, Nucleus,Fastigii, Nucleus,Globosus, Nucleus,Interposed Nucleus, Anterior,Interpositus Nucleus, Anterior,Intracerebellar Nucleus,Nuclei, Central,Nuclei, Cerebellar,Nuclei, Deep Cerebellar,Nuclei, Intracerebellar,Nucleus Fastigius,Nucleus, Anterior Interposed,Nucleus, Anterior Interpositus,Nucleus, Central,Nucleus, Cerebellar,Nucleus, Deep Cerebellar,Nucleus, Dentate,Nucleus, Dentate Cerebellar,Nucleus, Fastigial,Nucleus, Fastigial Cerebellar,Nucleus, Intracerebellar,Nucleus, Lateral Cerebellar,Nucleus, Medial Cerebellar
D002712 Chlorides Inorganic compounds derived from hydrochloric acid that contain the Cl- ion. Chloride,Chloride Ion Level,Ion Level, Chloride,Level, Chloride Ion

Related Publications

N Furuya, and K Kawano, and H Shimazu
Inhibitory commissural fibers interconnecting the bilateral vestibular nuclei.
May 1968, Brain research,
N Furuya, and K Kawano, and H Shimazu
Neuronal interaction between ipsilateral medial and lateral vestibular nuclei.
January 1981, Annals of the New York Academy of Sciences,
N Furuya, and K Kawano, and H Shimazu
Visual modulation of neuronal activity within the rat vestibular nuclei.
January 1983, Experimental brain research,
N Furuya, and K Kawano, and H Shimazu
Vestibular and somatosensory interaction in the cat vestibular nuclei.
October 1977, Pflugers Archiv : European journal of physiology,
N Furuya, and K Kawano, and H Shimazu
[Interaction of vestibular and cerebellar impulses in the vestibular nuclei].
April 1970, Shinkei kenkyu no shimpo. Advances in neurological sciences,
N Furuya, and K Kawano, and H Shimazu
Descending vestibular activity and its modulation by proprioceptive, cerebellar, and reticular influences.
August 1959, Experimental neurology,
N Furuya, and K Kawano, and H Shimazu
Oculomotor functions of the flocculus and the vestibular nuclei after bilateral vestibular neurectomy.
January 1989, Progress in brain research,
N Furuya, and K Kawano, and H Shimazu
Transcriptional activity of nuclei in multinucleated osteoclasts and its modulation by calcitonin.
May 2002, Endocrinology,
N Furuya, and K Kawano, and H Shimazu
The vestibular nuclei and spinal motor activity.
August 1971, Journal of psychiatric research,
N Furuya, and K Kawano, and H Shimazu
Vestibulospinal and neck reflexes: interaction in the vestibular nuclei.
January 1991, Archives italiennes de biologie,
Copied contents to your clipboard!