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Neuromagnetic studies of the lip area of primary somatosensory cortex in humans: evidence for an oscillotopic organization (1994)

Mogilner, A. ; Nomura, M. ; Ribary, U. ; [et al.]

Springer

Experimental brain research 99 (1994), S. 137-147

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ISSN: 1432-1106

Keywords: Magnetoencephalography ; Somatosensory cortex ; Trigeminal nerve ; Lip ; Frequency discrimination ; Human

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Magnetic trigeminal somatosensory responses from human subjects were recorded using a 14-channel magnetoencephalographic system. Sensory stimuli comprising a 15-ms vibration at frequencies of 50 Hz, 150 Hz and 250 Hz were given at randomized interstimulus intervals. Using a single dipole model, the neuronal sources of the evoked responses were determined, and mapped onto magnetic resonance images of each subject. Source localization analysis was based on the main peak of the averaged signal (M55). All of the sources were located deep in the anterior bank of the postcentral gyrus, corresponding to area 3b of somatosensory cortex SI. In all cases, the source for the upper lip was significantly higher in the vertical axis (0.6–1.1 cm) than for the lower lip, while the lower lip stimulation produced a larger response than the upper lip. Furthermore, statistically significant differences were found between the locations of the dipoles evoked by different frequency stimulation. The location of the response shifted with change in stimulation frequency, showing a trend among all subjects with a medial shift between 150 and 250 Hz for both upper and lower lip. The accuracy of source localization calculated from magnetic fields ranged between ±0.9 and ±3.0 mm (SEM). These results demonstrate (1) that a large area of the somatosensory cortex is utilized for lip representation and (2) that the spatial displacement of the trigeminal somatosensory response may be related to the discrimination of frequency.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00241418

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Functional organization of the vestibular afferents to the cerebellar cortex of frog and cat (1969)

Precht, W. ; Llinás, R.

Springer

Experimental brain research 9 (1969), S. 30-52

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ISSN: 1432-1106

Keywords: Climbing fibers ; Mossy fibers ; Vestibulo-cerebellar input ; Cat ; Frog ; Golgi cell inhibition

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary 1. Field and unitary potentials evoked in the vestibulo-cerebellum of frog and cat following vestibular nerve stimulation were recorded with microelectrodes and correlated with their site of origin in the various layers of the cerebellar cortex. 2. In the frog, primary vestibular fibers project both as mossy and as climbing fibers onto the cerebellar auricular lobe. Secondary vestibulo-cerebellar fibers seem to end exclusively as mossy fibers in the auriculum. As a consequence of this dual projection, extra- and intracellular recordings from Purkinje cells in the auricular lobe show two kinds of responses to vestibular nerve stimulation: a) graded, repetitive firing mediated through mossy fiber-granule cell-parallel fiber pathways, and b) all-or-none burst responses caused by monosynaptic impingement of vestibular climbing fibers on Purkinje cells. 3. The field and unitary potentials evoked in the cat nodulus, flocculus and uvula following vestibular nerve stimulation are shown to be generated by mossy fibers exclusively. Considerable convergence of the two labyrinthine mossy fiber inputs to a given cerebellar area was found. 4. Interaction of contralateral and ipsilateral mossy fiber input at the level of the flocculus suggests that Golgi cell inhibition might operate not only as a simple inhibitory feedback loop, but also as a complex gating operator at the granule layer. 5. No short latency climbing fiber activation of Purkinje cells was observed following VIIIth nerve stimulation. Stimulation of the contralateral inferior olive evoked short latency climbing fiber EPSPs in Purkinje cells of the vestibulo-cerebellum. Suggestions are made as to the possible role of mossy and climbing fiber inputs to this area of the cerebellum.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00235450

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Cerebellar Purkinje cell responses to physiological stimulation of the vestibular system in the frog (1971)

Llinás, R. ; Precht, W. ; Clarke, M.

Springer

Experimental brain research 13 (1971), S. 408-431

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ISSN: 1432-1106

Keywords: Vestibulo-cerebellar input ; Purkinje cells ; Mossy fibers ; Climbing fiber ; Responses to rotation ; Frog cerebellum

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The electrical activity of single Purkinje cells was studied in the auricular lobe and in the vestibular cerebellum of Rana catesbeiana during horizontal angular acceleration. This form of physiological stimulation allowed the Purkinje cells to be categorized into four main classes, depending on the general properties of their responses. 1. Type I Purkinje cells responded to ipsilateral horizontal acceleration. Their discharge was blocked during contralateral rotation. Within this group, individual Purkinje cell responses to a protracted acceleration varied from purely phasic to purely tonic discharge. 2. Type II Purkinje cells were characterized by their activation following contralateral horizontal acceleration and by lack of response to the ipsilateral rotation. Both type I and II Purkinje cells were encountered mainly in the auricular lobe. 3. Type III, the most common form of Purkinje cell response, was activated by rotation in either ipsi- or contralateral direction. Their response, as that of type I, could vary from a purely phasic to a purely tonic discharge. The study of field potentials and unitary responses evoked by electrical stimulation of the vestibular nerve demonstrated that type III Purkinje cell response was evoked via a polysynaptic pathway different from that which activated Purkinje cells in the auricular lobe. 4. Type IV Purkinje cells were characterized by the reduction of spontaneous firing during acceleration in either ipsi- or contralateral directions. 5. A comparison of the responses evoked by type III Purkinje cells in the cerebellar cortex demonstrated that neighboring Purkinje cells may respond in different fashions to the same vestibular input. Furthermore, the tonic or phasic character of a given Purkinje cell was very similar for ipsi- and contralateral rotation, suggesting that the subtle differences between responses in neighboring Purkinje cells may be related to differences in their dynamic properties rather than differences in the types of afferents received. 6. Climbing fiber activation of Purkinje cells during horizontal rotation was clearly demonstrated in five cells. These responses are considerred to be mediated through the saccular or utricular systems rather than through the semi-circular canals. The conclusion is derived that the semi-circular canal input to the cerebellum is subserved mainly by mossy fiber input. 7. The possible functional meaning of the different types of Purkinje cell response is discussed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00234339

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Cerebellar modulatory action on the vestibulo-trochlear pathway in the cat (1972)

Baker, R. ; Precht, W. ; Llinás, R.

Springer

Experimental brain research 15 (1972), S. 364-385

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ISSN: 1432-1106

Keywords: Vestibulo-trochlear reflex ; Reverberation ; Floccular inhibition ; Commissural inhibition ; Cerebellar influence

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Field and intracellular potentials were recorded at the level of the trochlear nucleus (TN) following stimulation of the ipsi- or contralateral vestibular nerve (Vi, Vc) or the cerebellar flocculus (Floc). Vi and Vc stimulation produced clear presynaptic field potentials in the TN as the vestibulo-trochlear volleys ascending from the vestibular nucleus reached the trochlear motoneurons (TMns). Paired Vi-Vi or Vc-Vc stimulation at different intervals demonstrated a clear depression of the second of the two presynaptic potentials in the TN. A similar finding was obtained intracellularly from TMns. These results indicate a marked reduction in the excitability of the vestibular neurons following the conditioning stimulus. This period of subnormality may last for as long as 40 msec. Electrical stimulation of Vi and Vc generated an IPSP and EPSP respectively in TMns. In most instances these synaptic potentials occurred in a repetitive fashion after a single stimulation to either nerve. This reverberatory-like tendency of the vestibulo-trochlear pathways was absent in decerebellate animals, implying a cerebellar modulatory mechanism on vestibulo-trochlear transmission. Floccular stimulation produced a strong monosynaptic depression of the field and intracellular potentials evoked in the TN by Vi activation. In chronic experiments where the vestibular nerve had been transected, Floc stimulation generated a disinhibition of TMns through its suppression of the ipsilateral inhibitory vestibular neurons which project to the TN. Contralateral Floc stimulation produced a clear disfacilitation of TMns by the inhibition of contralateral excitatory vestibular neurons. Direct evidence was obtained for commissural inhibition acting on both the inhibitory and excitatory vestibular neurons projecting to the TN. The functional implications of the interaction between ipsi- and contralateral vestibular nuclei and the cerebellum and vestibular nuclei are considered in the Discussion.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00234124

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