Spatial organization of visual messages of the rabbit's cerebellar flocculus. II. Complex and simple spike responses of Purkinje cells

Graf, Werner; Simpson, John I.; Leonard, Christopher

doi:10.1152/jn.1988.60.6.2091

Cited by 366 publications

(187 citation statements)

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“…Excitatory and inhibitory phases of the CFR modulation of a VA cell was defined relative to counterclockwise and clockwise motions of the turntable, with the beginning of each phase corresponding to the beginning of the motion in each direction. As found previously (Graf et al, 1988), the complex spike activity of all VA Purkinje cells increased for retinal image motion in the temporal to nasal direction referenced to the eye ipsilateral to the recorded flocculus. A contrast ratio characterizing the modulation was defined as the difference in the number of CFRs between excitatory and inhibitory phases divided by the total number of CFRs during visual stimulation.…”

Section: Methodssupporting

confidence: 86%

“…Similar measurements were also made for visual modulation of climbing fiber activity in floccular Purkinje cells that responded best to visual rotation about the vertical axis (VA) (Graf et al, 1988). Our goal was to examine the possibility that the number of spikes within the climbing fiber bursts carries a signal.…”

Section: Introductionmentioning

confidence: 89%

“…Single Purkinje cell activity was extracellularly identified by the presence of complex spikes. Purkinje cells in the flocculus that respond best to visual whole-field rotation about either the VA or the horizontal 45°-135°a xis were identified by slowly moving (ϳ1°/s) a large hand-held visual pattern (Graf et al, 1988). Penetration of a Purkinje cell by the microelectrode often resulted in a period of injury discharge, after which relatively large EPSPs attributable to the climbing fiber input could be recorded (Eccles et al, 1966;Armstrong and Rawson, 1979).…”

Section: Methodsmentioning

confidence: 99%

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Intraburst and Interburst Signaling by Climbing Fibers

Maruta

Hensbroek²,

Simpson³

2007

J. Neurosci.

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Although cerebellar Purkinje cell complex spikes occur at low frequency (ϳ1/s), each complex spike is often associated with a highfrequency burst (ϳ500/s) of climbing fiber spikes. We examined the possibility that signals are present within the climbing fiber bursts. By intracellularly recording from depolarized, nonspiking Purkinje cells in anesthetized pigmented rabbits, climbing fiber burst patterns were investigated by determining the number of components in the induced compound EPSPs during spontaneous activity and during visual stimulation. For our sample of 43 cells, Ͼ70% of all EPSPs were of the compound type composed of two or three EPSPs. During spontaneous activity, the number of components in each compound EPSP was not related to the latency to the succeeding compound EPSP. Conversely, the number of components in each compound EPSP was related to its latency after the preceding compound EPSP. This latency increased from 0.62 s for one-component EPSPs to 1.69 s for compound EPSPs with four or more components. The effect of visual stimulation on the climbing fiber activity was studied in 19 floccular Purkinje cells whose low-frequency interburst climbing fiber response was modulated by movement about the vertical axis. During sinusoidal oscillation (0.1 Hz, Ϯ10°), compound EPSPs with a larger number of components tended to be more prevalent during movement in the excitatory direction than in the inhibitory direction. Thus, climbing fibers can, in addition to modulation of their low interburst frequency, transmit signals in the form of the number of spikes within each high-frequency burst.

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Section: Methodssupporting

confidence: 86%

Section: Introductionmentioning

confidence: 89%

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

Intraburst and Interburst Signaling by Climbing Fibers

Maruta

Hensbroek²,

Simpson³

2007

J. Neurosci.

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“…The role of the climbing fiber input is still unclear (reviewed in Simpson et al 1996), but many assume that it functions to modify the efficacy of the synapse between mossy fibers and Purkinje cell. Moreover there is evidence that in rabbit (Frens et al 2001;Graf et al 1988) and monkey (Kahlon and Lisberger 2000;Stone and Lisberger 1990b) complex spike trains encode performance errors (i.e., retinal slip).…”

Section: Introductionmentioning

confidence: 99%

Brain Stem Pursuit Pathways: Dissociating Visual, Vestibular, and Proprioceptive Inputs During Combined Eye-Head Gaze Tracking

Roy

Cullen

2003

Journal of Neurophysiology

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. Brain stem pursuit pathways: dissociating visual, vestibular, and proprioceptive inputs during combined eye-head gaze tracking. J Neurophysiol 90: 271-290, 2003; 10.1152/jn.01074.2002 neurons within the medial vestibular nuclei are thought to be the primary input to the extraocular motoneurons during smooth pursuit: they receive direct projections from the cerebellar flocculus/ventral paraflocculus, and in turn, project to the abducens motor nucleus. Here, we recorded from EH neurons during head-restrained smooth pursuit and headunrestrained combined eye-head pursuit (gaze pursuit). During headrestrained smooth pursuit of sinusoidal and step-ramp target motion, each neuron's response was well described by a simple model that included resting discharge (bias), eye position, and velocity terms. Moreover, eye acceleration, as well as eye position, velocity, and acceleration error (error ϭ target movement Ϫ eye movement) signals played no role in shaping neuronal discharges. During head-unrestrained gaze pursuit, EH neuron responses reflected the summation of their head-movement sensitivity during passive whole-body rotation in the dark and gaze-movement sensitivity during smooth pursuit. Indeed, EH neuron responses were well predicted by their head-and gaze-movement sensitivity during these two paradigms across conditions (e.g., combined eye-head gaze pursuit, smooth pursuit, wholebody rotation in the dark, whole-body rotation while viewing a target moving with the head (i.e., cancellation), and passive rotation of the head-on-body). Thus our results imply that vestibular inputs, but not the activation of neck proprioceptors, influence EH neuron responses during head-on-body movements. This latter proposal was confirmed by demonstrating a complete absence of modulation in the same neurons during passive rotation of the monkey's body beneath its neck. Taken together our results show that during gaze pursuit EH neurons carry vestibular-as well as gaze-related information to extraocular motoneurons. We propose that this vestibular-related modulation is offset by inputs from other premotor inputs, and that the responses of vestibuloocular reflex interneurons (i.e., position-vestibular-pause neurons) are consistent with such a proposal. I N T R O D U C T I O NIn the head-restrained condition, primates generate smooth eye movements, termed smooth pursuit, to follow a slowly moving target. A number of parallel and interconnected pathways are involved in initiating and maintaining smooth-pursuit eye movements (for review, see Keller and Heinen 1991); however, particular importance has been assigned to the cortico-ponto-cerebellar pathway arising from the medial superior temporal sulcus (MST) of the extrastriate cortex. This pathway accesses the brain stem circuitry via inhibitory projections from the ipsilateral cerebellar flocculus and ventral paraflocculus, herein referred to as the floccular lobe (Balaban et al. 1981;Dow 1937;Gerrits and Voogd 1989;Langer et al. 1985). Under more natural conditions (i.e., when the hea...

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“…Since yaw movement stimulates primarily the horizontal semicircular canal pair (Curthoys, Markham and Blanks, 1975), this approach implied that other canal pairs also had their own independent connections to the appropriate eye muscles. The idea of a set of three sub-systems defined by the semicircular canals within the skull underlying the generation of the VOR around any axis received support from the spatial tuning of sensory responses in various parts of the brain known to be involved in the neural interpretation of the VOR Simpson, Graf and Leonard, 1981;Graf, Simpson and Leonard, 1988;Oyster, Takahashi and Collewijn, 1972). Furthermore the direction of pull of the oculomotor muscles themselves also seem to be arranged in planes roughly aligning with the orientation of the semicircular canal planes .…”

Section: A Post-modern Approachmentioning

confidence: 99%