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1

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Coerulospinal cells containing neuropeptide Y in the cat

Fung, S.J. ; Zhuo, H. ; Manzoni, D. ; [et al.]

Amsterdam : Elsevier

Peptides 12 (1991), S. 739-743

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ISSN: 0196-9781

Keywords: Coerulospinal ; Descending ; Horseradish peroxidase ; Immunocytochemistry ; Kolliker-Fuse nucleus ; Laterodorsal tegmental nucleus ; Locus coeruleus ; Neuropeptide Y ; Spinal cord ; Subcoeruleus

Source: Elsevier Journal Backfiles on ScienceDirect 1907 - 2002

Topics: Chemistry and Pharmacology

Type of Medium: Electronic Resource

URL: http://linkinghub.elsevier.com/retrieve/pii/0196-9781(91)90126-A

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2

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Temporal response properties of lumbar-projecting vestibulospinal neurons to roll tilt in decerebrate cats (1993)

Manzoni, D. ; Pompeiano, O. ; Marchand, A. R.

Springer

Pflügers Archiv 423 (1993), S. 121-132

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ISSN: 1432-2013

Keywords: Decerebrate cats ; Vestibulospinal neurons ; Response dynamics ; Otolith afferents ; Semicircular canal afferents

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract In decerebrate cats, rotation about the longitudinal axis of the animal, leading to sinusoidal stimulation of labyrinth receptors, produces a tonic contraction of limb extensors during side-down tilt (α responses) and of dorsal neck extensors during side-up tilt (β responses). These changes in posture are mediated, at least in part, by lateral vestibular nucleus (LVN) neurons, with response characteristics to stimulation of macular and/or canal receptors that have so far been evaluated at the level of either unidentified vestibulospinal (VS) neurons or vestibulo-collic neurons projecting to the upper cervical cord. In the present study we investigated the dynamics of the responses of VS neurons projecting to the lumbosacral segments of the spinal cord to increasing frequencies of tilt (from 0.026 to 0.32 Hz, ±10°). All the recorded units showed an average phase lead with respect to position of +25.6±5.5° (SE) at the tilt frequency of 0.026 Hz. Most of these neurons (n=32) were particularly activated during side-down tilt (α responses) and showed either a stable phase or an increase in phase lead of the responses with increasing frequency of tilt. At the tilt frequency of 0.026 Hz, the smaller the phase lead of the responses, the larger was the response gain. Moreover, the smaller the phase lead of the responses at that frequency of tilt, the smaller the increase in gain but the larger was the increase in lead of the responses obtained by increasing the stimulation frequency up to 0.32 Hz. Through this set of finely organized changes in unit response characteristics, the overall output of this population of neurons increased, while the phase angle of the responses reached the mean value of +64.9±2.6° (SE), thus becoming more related to the velocity than to the positional signal. The remaining units (n=7), which were mainly activated during side-up tilt (β responses), displayed an increase in phase lag of the responses to increasing frequency of stimulation, which reached the mean value of-118.9±14.5° (SE) at 0.32 Hz. The differences in the dynamic properties of these VS neurons projecting to the lumbosacral cord, with respect to those of previously recorded populations of VS neurons, are discussed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00374969

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3

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Convergence and interaction of neck and macular vestibular inputs on locus coeruleus and subcoeruleus neurons (1989)

Manzoni, D. ; Pompeiano, O. ; Barnes, C. D. ; [et al.]

Springer

Pflügers Archiv 413 (1989), S. 580-598

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ISSN: 1432-2013

Keywords: Neck-macular vestibular inputs ; Locus coeruleus ; Subcoeruleus ; Renshaw cells ; Extensor muscles ; Motoneurons

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Extracellular recordings were obtained in precollicular decerebrate cats from 90 neurons located in the noradrenergic area of the dorsal pontine tegmentum, namely in the dorsal (LCd,n=24) and the ventral part (LCα,n=40) of the locus coeruleus (LC) as well as in the locus subcoeruleus (SC,n=26). Among these units of the LC complex, 13 were coerulospinal (CS) neurons antidromically identified following stimulation of the spinal cord at T12-L1. Some of these neurons showed the main physiological characteristics of the norepinephrine (NE)-containing LC neurons, i.e., a slow and regular resting discharge and a typical biphasic response to fore- and hindpaw compression consisting of a short burst of excitation followed by a period of quiescence, due, in part at least, to recurrent and/or lateral inhibition. Unit firing rate was analyzed under separate stimulation of macular vestibular, neck, or combined receptors by using sinusoidal rotation about the longitudinal axis at 0.15 Hz, ±10° peak amplitude. Among the 90 LC-complex neurons, 60 (66.7%) responded with a periodic modulation of their firing rate to roll tilt of the animal and 67 (74.4%) responded to neck rotation. Convergence of macular and neck inputs was found in 52/90 (57.8%) LC-complex neurons; in these units, the gain and the sensitivity of the first harmonic of the response corresponded on the average to 0.34±0.45, SD, impulsed·s−1·deg−1 and 3.55±2.82, SD, %/deg for the neck responses and to 0.23±0.29, SD, impulses·s−1·deg−1 and 3.13±3.04, SD, %/deg for the macular responses. In addition to these convergent units, 8/90 (8.9%) and 15/90 (16.7%) LC-complex units responded to selective stimulation either of macular or of neck receptors only. These units displayed a significantly lower response gain and sensitivity to animal tilt and neck rotation with respect to those obtained from convergent units. Most of the convergent LC-complex units were maximally excited by the direction of stimulus orientation, the first harmonic of responses showing an average phase lead of about +31.0° with respect to neck position and +17.6° with respect to animal position. Two populations of convergent neurons were observed. The first group of units (43/52, i.e., 82.7%) showed reciprocal (“out of phase”) responses to the two inputs; moreover, most of these units were excited during side-down neck rotation, but inhibited during side-down animal tilt. The second group of units (9/52, i.e., 17.3%) showed parallel (“in phase”) responses to the two inputs and they were excited by side-down or side-up neck rotation and animal tilt. The response characteristics of LC-complex neurons to combined neck and macular inputs, elicited during head rotation, corresponded to those predicted by a vectorial summation of the individual neck and macular responses. In particular, “out of phase” units displayed small amplitudes and large phase shifts of their responses with respect to those obtained during individual neck or macular stimulation. In contrast, “in phase” units displayed large responses during head rotation. Some nonlinearities of the responses to combined stimulation of neck and macular receptors, however, were observed. The possibility that the CS neurons contributed, with the vestibulospinal (VS) neurons, to the postural adjustments of the limb musculature during labyrinth and neck reflexes was discussed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00581807

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4

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Effects of stimulation of vestibular and neck receptors on Deiters neurons projecting to the lumbosacral cord (1987)

Marchand, A. R. ; Manzoni, D. ; Pompeiano, O. ; [et al.]

Springer

Pflügers Archiv 409 (1987), S. 13-23

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ISSN: 1432-2013

Keywords: Vestibulospinal neurons ; Response characteristics ; Macular vestibular input ; Neck input

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract 1. The activity of lateral vestibular nucleus (LVN) neurons, antidromically identified by stimulation of the spinal cord at T12 and L1, thus projecting to the lumbosacral segments of the spinal cord (lVS neurons), was recorded in precollicular decerebrate cats during rotation about the longitudinal axis either of the whole animal (labyrinth input) or of the body only while the head was kept stationary (neck input). 2. Among the lVS neurons tested for vestibular stimulation, 76 of 129 units (i.e. 58.9%) responded to roll tilt of the animal at the standard parameters of 0.026 Hz, ±10°. The gain and the sensitivity of the first harmonic responses corresponded on the average to 0.47±0.44, SD, impulses·s−1·deg−1 and 3.24±3.15, SD, %/deg, respectively. As to the response patterns, 51 of 76 units (i.e. 67.1%) were excited during side-down and depressed during side-up tilt, whereas 15 (i.e. 19.7%) showed the opposite behavior. In both instances the peak of the responses occurred with an average phase lead of about +21.0±27.2., SD, deg with respect to the extreme side-down or side-up position of the animal. Moreover, the former group of units showed almost a twofold larger gain with respect to the latter group (t-test,p〈0.05). 3. Among the lVS neurons tested for neck stimulation, 75 of 109 units (68.8%) responded to neck rotation at the standard parameters. The gain and the sensitivity of the first harmonic responses corresponded on the average to 0.49±0.40, SD, impulses·s−1·deg−1 and 3.30±3.42, SD, %/deg, respectively, thus being similar to the values obtained for the labyrinth responses. However, 59 of 75 units (i.e. 78.6%) were excited during side-up neck rotation and depressed during side-down neck rotation, while 8 of 75 units (i.e. 10.7%) showed the opposite pattern. In both instances the peak of the responses occurred with an average phase lead of +52.0±18.3, SD, deg for the extreme side-up or side-down neck displacements. Further, the former group of units showed a larger gain than the latter group. 4. Histological controls indicated that 102 of 129 (i.e. 79.0%) lVS neurons tested for labyrinth stimulation and 86 of 109 (i.e. 78.9%) lVS neurons tested for neck stimulation were located in the dorsocaudal part of LVN, the remaining lVS neurons being located in the rostroventral part of LVN. 5. The observation that the predominant response pattern of the lVS neurons to roll tilt was just opposite to that of lVS neurons to neck rotation indicates that the motoneurons innervating ipsilateral hindlimb extensors were excited by an increased discharge of vestibulospinal neurons during side-down tilt but they were disfacilitated by the reduced discharge of vestibulospinal neurons during side-down neck rotation; the opposite would occur during side-up animal tilt or neck rotation. These findings were compared with those of previously recorded LVN neurons, whose descending axons were not identified as projecting to upper or lower segments of the spinal cord. It was then possible to evaluate the role that the LVN exerts not only in the control of the limb but also of the neck extensor musculature.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00584745

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5

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Adaptive modification of the cat's vestibulospinal reflex during sustained vestibular and neck stimulation (1993)

Andre, P. ; d'Ascanio, P. ; Manzoni, D. ; [et al.]

Springer

Pflügers Archiv 425 (1993), S. 469-481

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ISSN: 1432-2013

Keywords: Vestibulospinal reflex ; Adaptation ; Neck input ; Decerebrate cats

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract In decerebrate cats, rotation about the longitudinal axis of the whole animal at 0.15 Hz,±10° produced an increased electromyogram (EMG) activity of the triceps brachii during side-down tilt and a decreased activity during side-up tilt. This vestibulospinal reflex (VSR) was tested before, during and after a sustained (3-h) period of roll tilt of the head at the parameters indicated above, associated with a synchronous roll tilt of the body at 0.15 Hz, but at the peak amplitude of either 12.5° or 7.5°. This additional stimulus led to 2.5° of neck rotation, which was respectively out of phase (condition A) or in-phase (condition B) with head rotation. In a few instances the peak amplitude of neck rotation was increased to 5°. In the first experimental condition A, the gain of the VSR (tested every 10–15 min) progressively increased, starting from the first hour of out of phase neck-vestibular stimulation to reach, on average, 241% of the control value at the end of the third hour of stimulation. On the other hand, in the second experimental condition B, the mean gain of the VSR first decreased to 82% during the first hour of in-phase neck-vestibular stimulation, but then increased to 165% of the corresponding control during the last hour of recording. In other experiments an adaptive increase in gain of the pure VSR occurred during a sustained (3-h) period of selective roll tilt of the whole animal, but it was less consistent and, on average, smaller in amplitude than that obtained during out of phase neck-vestibular stimulation. The adaptive changes in gain of the VSR described above were not associated with changes in the phase angle of the responses, and were also observed during the post-adaptation period. Further experiments indicated that the gain of the N-VSR, i. e. of the EMG responses to combined neck-vestibular stimulation, displayed a prominent adaptive increase during the sustained out of phase stimulation, but not during the inphase stimulation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00374874

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6

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Responses of Purkinje cells in the cerebellar anterior vermis to off-vertical axis rotation (1995)

Manzoni, D. ; Andre, P. ; Pompeiano, O.

Springer

Pflügers Archiv 431 (1995), S. 141-154

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ISSN: 1432-2013

Keywords: Cerebellar vermis ; Purkinje cells ; Otolith input ; Head tilt direction ; Population code

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Responses of 67 Purkinje cells (P-cells) and 44 unidentified neurons (U-cells) located in the cerebellar anterior vermis were recorded in decerebrate cats during off-vertical axis rotation (OVAR). This stimulus consisted of a slow constant velocity (9.4°/s) rotation in the clockwise (CW) and counterclockwise (CCW) directions around an axis inclined by 5° with respect to the vertical. OVAR imposes on the animal head a 5° tilt, whose direction changes continuously over the horizontal plane, thus eliciting a selective stimulation of macular receptors. A total of 27/67 P-cells (40%) and 24/44 U-cells (55%) responded to both CW and CCW rotations. For these bidirectional units, the direction of maximum sensitivity to tilt (Smax) could be identified. Smax directions were distributed over the whole horizontal plane of stimulation. Among bidirectional neurons, 48% of the P-cells and 33% of the U-cells displayed an equal amplitude of modulation during CW and CCW rotations, indicating a cosinetuned behaviour. In these instances, the temporal phase of the unit response to a given direction of tilt remained constant, while the sensitivity was maximal along the Smax direction and declined with the cosine of the angle between Smax and the tilt direction. The remaining bidirectional units displayed unequal amplitudes of modulation during CW and CCW rotations. For these neurons, a nonzero sensitivity along the null direction was expected and the response phase varied as a function of stimulus direction. Finally, 31% and 23% of P-cells and U-cells, respectively, responded during OVAR in one direction only (unidirectional units). This behaviour predicts equal sensitivities along any tilt direction in the horizontal plane and a response phase that changes linearly with the stimulus direction. The possibility that the tested neurons formed a population which coded the direction of head tilt in space was also investigated. The data from the whole population of cells were analysed using a modified version of vectorial analysis. This model assumes that for a particular tilt each cell makes vectorial contributions; the vectorial sum of these contributions represent the outcome of the population code and points in the direction of head tilt in space. Thus, a dynamic head tilt along four representative directions was simulated. For each of the four directions, 12 population vectors were calculated at regular time intervals so as to cover an entire cycle of head tilt. The results indicate that for each selected time in the cycle the direction of the population vector closely corresponded to that of the head tilt, while its amplitude was related to the amount of head tilt. These data were particularly obtained for the P-cells. In view of their efferent connections, the cerebellar anterior vermis may provide a framework for the spatial organization of vestibulospinal reflexes induced by stimulation of otolith receptors.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00410185

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Relation between cell size and response characteristics of medullary reticulospinal neurons to labyrinth and neck inputs (1983)

Pompeiano, O. ; Manzoni, D. ; Srivastava, U. C. ; [et al.]

Springer

Pflügers Archiv 398 (1983), S. 298-309

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ISSN: 1432-2013

Keywords: Reticulospinal neurons ; Cell size ; Macular vestibular input ; Neck input

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract 1. The activity of presumably inhibitory reticulospinal neurons with cell bodies located in the medial aspects of the medullary reticular formation and axons projecting to lumbosacral cord has been recorded in decerebrate cats and their response characteristics to sinusoidal stimulation of labyrinth receptors (134 neurons) and neck receptors (110 neurons) have been related to cell size inferred from the conduction velocity of the corresponding axons. 2. No significant correlation was found between resting discharge and conduction velocity of the axons. 3. Among the recorded reticulospinal neurons, 64/134 (i.e. 47.8%) units responded to roll tilt, while 66/110 (i.e. 60.0%) units responded to neck rotation (0.026 Hz, ±10°). A positive correlation was found between gain (imp./s/deg) of the labyrinth and neck responses and conduction velocity of the axons. Thus, due to absence of correlation between resting discharge and conduction velocity of the axons, larger neurons exhibited a greater percentage modulation (sensitivity) to the labyrinth and the neck input than smaller neurons. These findings are attributed to an overall increase in density or efficacy of the synaptic contacts made by the vestibular and neck afferent pathways on reticulospinal neurons of increasing size. 4. Units receiving neck-macular vestibular convergence showed on the average an higher gain of the neck (G N) response with respect to the labyrinth (G L) response (G N/G:L: 1.95±1.49, S.D.;n=43); however, due to a parallel increase in gain of the reticulospinal neurons to both neck and labyrinth inputs, the relative effectiveness of the two inputs did not vary in different units as a function of cell size. 5. The reticulospinal neurons were mainly excited by the direction of animal orientation and/or neck displacement. In particular, most of these positional sensitive units were excited by side-up animal tilt (37/58, i.e. 63.8%) and by sidedown neck rotation (47/60, i.e. 78.3%). These predominant response patterns were particularly found between large size neurons, whereas small size neurons tended to show also other response patterns. 6. The evidence indicates that in addition to intrinsic neuronal properties related to cell size, the quantitative and qualitative organization of synaptic inputs represents the critical factor controlling the responsiveness of reticulospinal neurons to vestibular and neck stimulation.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00657239

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Modelling of the turbulent thermal boundary layer implemented in CFD code N3S and application to flows in heated and cooled rooms (1995)

Delenne, B. ; Manzoni, D. ; Pot, G.

Chichester : Wiley-Blackwell

International Journal for Numerical Methods in Fluids 20 (1995), S. 469-492

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ISSN: 0271-2091

Keywords: boundary layer ; heat transfer ; turbulence ; CFD ; finite elements ; Engineering ; Engineering General

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Mechanical Engineering, Materials Science, Production Engineering, Mining and Metallurgy, Traffic Engineering, Precision Mechanics

Notes: This paper presents an efficient finite element method for solving the unsteady Navier-Stokes equations for turbulent incompressible flow coupled with thermal problems. This method has been implemented in the N3S code, developed at Electricité de France. The time discretization is first described. We precise then the Chorin and the ‘projected Uzawa’ algorithms used for the Stokes problem. Recent improvements concerning the optimization of finite element calculations are also detailed. The second part deals with the modelling of the thermal boundary layer used to simulate walls with fixed temperature in turbulent flows. The differences with other modelling suggested in the literature are discussed. The last part presents some applications. EDF is involved in the conception of heating or cooling systems and numerical methods constitute a very useful tool to study the movements of air in habitations. The calculations are validated by comparisons with measurements.

Additional Material: 14 Ill.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/fld.1650200605

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