Olivo-cerebellar cluster-based universal control system

Kazantsev, Victor B.; Nekorkin, Vladimir I.; Makarenko, V. I.; Llinás, Rodolfó R.

doi:10.1073/pnas.1635110100

Cited by 48 publications

(26 citation statements)

References 20 publications

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“…Because spike threshold occurs mostly at the peak of a subthreshold oscillation, spike onset is determined by the subthreshold oscillation. Depending on the values of the control parameters, the model qualitatively reproduces the spontaneous and stimuli-induced oscillations observed in IO neurons (8,15). A mathematical model comprising a set of four nonlinear differential equations can describe these properties:…”

Section: Io Neuron Modelmentioning

confidence: 88%

“…We have developed a mathematical model that reproduces the key IO neuron electrophysiological properties (8,15) and the SPR effect. In particular, the model comprises two sets of functionally coupled equations where the oscillations of Abbreviations: IO, inferior olive; SPR, self-referential phase reset.…”

Section: Io Neuron Modelmentioning

confidence: 99%

“…During the short time IO neurons are electrically uncoupled, they may receive direct sensory feedback that can provide the desired cluster configuration. The olivocerebellar cluster-based universal control system (UCS) has been described in detail (8). SPR-induced synchronization as implemented with the UCS architecture is illustrated in Fig.…”

Section: Spr-induced Synchronizationmentioning

confidence: 99%

“…Recent experimental work indicates that such a temporal signal mechanism is provided by the sequence of oscillatory events in the olivo-cerebellar system (7). The possibility that a ''universal control system,'' based on olivo-cerebellar physiology, may be implemented in analog hardware electronic chips has been proposed (8).…”

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confidence: 99%

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Self-referential phase reset based on inferior olive oscillator dynamics

Kazantsev

Nekorkin

Makarenko

et al. 2004

Proc. Natl. Acad. Sci. U.S.A.

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The olivo-cerebellar network is a key neuronal circuit that provides high-level motor control in the vertebrate CNS. Functionally, its network dynamics is organized around the oscillatory membrane potential properties of inferior olive (IO) neurons and their electrotonic connectivity. Because IO action potentials are generated at the peaks of the quasisinusoidal membrane potential oscillations, their temporal firing properties are defined by the IO rhythmicity. Excitatory inputs to these neurons can produce oscillatory phase shifts without modifying the amplitude or frequency of the oscillations, allowing well defined time-shift modulation of action potential generation. Moreover, the resulting phase is defined only by the amplitude and duration of the reset stimulus and is independent of the original oscillatory phase when the stimulus was delivered. This reset property, henceforth referred to as selfreferential phase reset, results in the generation of organized clusters of electrically coupled cells that oscillate in phase and are controlled by inhibitory feedback loops through the cerebellar nuclei and the cerebellar cortex. These clusters provide a dynamical representation of arbitrary motor intention patterns that are further mapped to the motor execution system. Being supplied with sensory inputs, the olivo-cerebellar network is capable of rearranging the clusters during the process of movement execution. Accordingly, the phase of the IO oscillators can be rapidly reset to a desired phase independently of the history of phase evolution. The goal of this article is to show how this selfreferential phase reset may be implemented into a motor control system by using a biologically based mathematical model. neuron ͉ nonlinear ͉ oscillation ͉ Andronov-Hopf bifurcation C oordinated motor control signals addressing large numbers of muscles at a given time must implement strict temporal coherence, also known as ''temporal motor binding,'' to generate appropriate motricity (1). Electrophysiological studies have indicated that such motor intention patterns require proper olivocerebellar system function (1-4). And, in particular, sets of time-coherent inferior olive (IO) action potentials reach given motor neuron pools by means of the cerebellar nuclei (1, 5-7). To provide the required synchrony of muscle activation, the IO signals must be temporally coherent at the final motor path regardless of the distance between the activated muscle groups. As such, then, the main coherence control parameter is the mutual temporal shifts among sequences of action potentials innervating different muscles. Recent experimental work indicates that such a temporal signal mechanism is provided by the sequence of oscillatory events in the olivo-cerebellar system (7). The possibility that a ''universal control system,'' based on olivo-cerebellar physiology, may be implemented in analog hardware electronic chips has been proposed (8).Indeed, temporal motor intention patterns may be formed as oscillatory phase clusters in the IO (9-12). ...

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Section: Io Neuron Modelmentioning

confidence: 88%

Section: Io Neuron Modelmentioning

confidence: 99%

Section: Spr-induced Synchronizationmentioning

confidence: 99%

mentioning

confidence: 99%

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Self-referential phase reset based on inferior olive oscillator dynamics

Kazantsev

Nekorkin

Makarenko

et al. 2004

Proc. Natl. Acad. Sci. U.S.A.

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“…There is considerable evidence to support the network perspective for describing and explaining brain function, giving rise to theories such as the universal control system, [34] and the concept of synaptic homoeostasis for the stabilization of neuronal circuits [35]. One of the things we know about neural plasticity is that it is enhanced by new behavioral learning, rather than just repetition of exercises/activities in the absence of learning [36], supporting the hypothesis that's implemotor activity is insufficient to produce long-term plasticity in cortical representations.…”

Section: Citationmentioning

confidence: 99%

Improvements in Quality of Life in Individuals with Friedreich’s Ataxia after Participation in a 5-Year Program of Physical Activity: An observational Study Pre-Post Test Design, and Two Years Follow-Up

Unda¹

2014

Int J Neurorehabilitation Eng

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On the other hand, the principle of physiotherapeutic intervention is to activate and demand control mechanisms for balance control and multi-joint coordination. In this regard, a role may be played by neural AbstractPurpose: To determine the effects of a physical activity-based rehabilitation focused on quality of life in individuals with FA who completed a five-year program. Methods:The study design was longitudinal and observational with pre-and post-test assessments, and two years follow-up. We studied 16 patients with FA. Participants received pharmacological treatment and took part in a physical activity rehabilitation program (intervention group) or received pharmacological treatment alone (controls). They were all assessed using the International Cooperative Ataxia Rating Scale (ICARS), SF-36 Health Survey and Functional Independence Measure (FIM). Changes over time and differences between groups were assessed with repeated measure analysis of variance (ANOVA) and Student´s t-tests. Results:In the intervention group, a change in the distribution of the mean ICARS score from 93.10±4.63 to 94.90 ± 4.50 suggested a slight worsening in ataxia (not significant). In contrast, the means on the SF-36 (43.89 ± 5.55 to 51.70±4.19) and FIM (50.20±16.02 to 59.20±15.01) both increased significantly over time. That is, after the treatment, patients in the intervention group showed a significant improvement in communication, daily living skills and socialization, and the improvement in their quality of life was maintained at the two-year follow-up. Conclusions:Long-term rehabilitation improved physical capacity and health-related quality of life. This study provides evidence for maintaining long-term physical activity programs in institutionalized patients with FA. Improvements in Quality of

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Models of the Cortico-cerebellar System

Negrello¹,

Schutter²

2016

Neuroscience in the 21st Century

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Without the cerebellum, organisms are challenged in the learning and execution of accurate and coordinated actions. It has a central position in the nervous system receiving and projecting to the spinal cord, midbrain, and cerebral cortex, implying convergence of sensory and motor streams. Its highly conserved neuroarchitecture would imply it is very good at what it does and that what it does is very general. Here we review theoretical, modeling, and computational work that has attempted to capture the dynamics and/or function of the cerebellum. Keywords Adaptive filter model • Bottom-up models • Cerebellar nucleus • Coupled oscillators • Dynamic models • Golgi gating • Granule cell models • Reverberating loops model • Spatiotemporal patterns in cerebellum • Tidal wave • Echo-state machine • Forward and inverse models • Functional models • Golgi gating • Granule cell models • Inferior olivary models • Coupled oscillators • Echo-state machine • Phase resets • Synchronous groups • Marr-Albus type models • Adaptive filter model and distributed synaptic plasticity • Information encoding and channel capacity • Purkinje neuron single cell modeling • Successes and failures • Pellionisz and Llinas's model • Purkinje neuron single cell modeling • Reverberating loops model • Synchronous groups • Tidal wave hypothesis

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Olivo-cerebellar cluster-based universal control system

Cited by 48 publications

References 20 publications

Self-referential phase reset based on inferior olive oscillator dynamics

Self-referential phase reset based on inferior olive oscillator dynamics

Improvements in Quality of Life in Individuals with Friedreich’s Ataxia after Participation in a 5-Year Program of Physical Activity: An observational Study Pre-Post Test Design, and Two Years Follow-Up

Models of the Cortico-cerebellar System

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