Linking oscillations in cerebellar circuits

Courtemanche, Richard; Robinson, J.C.; Aponte, Daniel I

doi:10.3389/fncir.2013.00125

Cited by 51 publications

(53 citation statements)

References 178 publications

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“…Alpha and beta EEG rhythms have been identified in the cerebellum, the thalamus and a cortical network including the insula, cingulate and prefrontal cortex and show a correlation with fMRI signal fluctuations in the tonic alertness state40. Alpha oscillations in the cerebral cortex and alpha-beta oscillation in the cerebellar cortex follow similar behaviour in relation to movement preparation41. In both cortical circuits, the persistence of sensory or cognitive inputs is supported by neuronal membrane properties and by a recurrent chain of neurons that act as neural integrators42.…”

Section: Discussionmentioning

confidence: 99%

“…It has been demonstrated in rodents, primates and humans that cerebellar oscillations may interact with cerebral oscillations4. Oscillations in cerebellar circuits could serve to coordinate their internal activity, but also to relate cerebellar activity to other distant cerebral areas41. In this way, specific theta/beta range oscillations (4–25 Hz) of the granule cell layer in the cerebellum have been linked to cerebral cortex activity45.…”

Section: Discussionmentioning

confidence: 99%

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“Cerebellar contribution to visuo-attentional alpha rhythm: insights from weightlessness”

Cebolla

Petieau

Dan

et al. 2016

Sci Rep

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Human brain adaptation in weightlessness follows the necessity to reshape the dynamic integration of the neural information acquired in the new environment. This basic aspect was here studied by the electroencephalogram (EEG) dynamics where oscillatory modulations were measured during a visuo-attentional state preceding a visuo-motor docking task. Astronauts in microgravity conducted the experiment in free-floating aboard the International Space Station, before the space flight and afterwards. We observed stronger power decrease (~ERD: event related desynchronization) of the ~10 Hz oscillation from the occipital-parietal (alpha ERD) to the central areas (mu ERD). Inverse source modelling of the stronger alpha ERD revealed a shift from the posterior cingulate cortex (BA31, from the default mode network) on Earth to the precentral cortex (BA4, primary motor cortex) in weightlessness. We also observed significant contribution of the vestibular network (BA40, BA32, and BA39) and cerebellum (lobule V, VI). We suggest that due to the high demands for the continuous readjustment of an appropriate body posture in free-floating, this visuo-attentional state required more contribution from the motor cortex. The cerebellum and the vestibular network involvement in weightlessness might support the correction signals processing necessary for postural stabilization, and the increased demand to integrate incongruent vestibular information.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

“Cerebellar contribution to visuo-attentional alpha rhythm: insights from weightlessness”

Cebolla

Petieau

Dan

et al. 2016

Sci Rep

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“…These could indeed affect the coding in the GCL, the granule/Purkinje connection geometry via the ascending branch and parallel fibers, and the Purkinje cell layer (and interneurons), all the way to the deep cerebellar nuclei [14,58]. In future experiments on Golgi network organization and GCL LFP oscillations, a few parameters could be explored from a local to global perspective.…”

Section: Local Circuit Interactions In Cerebellar Cortex Rhythmogenesismentioning

confidence: 99%

“…The cerebellum plays a pivotal role in many aspects of sensorimotor processing and displays low-frequency LFP oscillations that are synchronized with those in primary somatosensory cortex and motor areas [11][12][13][14]. Low-frequency cerebellar oscillations have been recorded in the granule cell layer (GCL) of awake and alert rodents (7)(8) and primates (10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20)(21)(22)(23)(24)(25) [12,[15][16][17], and are present both at rest and during preparation for movement [12,14,[16][17][18]. In addition, single and multi-unit firing activity within the GCL is phase-locked with GCL oscillations [15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Gap Junction Modulation of Low-Frequency Oscillations in the Cerebellar Granule Cell Layer

Robinson¹,

Chapman

Courtemanche³

2017

Cerebellum

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Local field potential (LFP) oscillations in the granule cell layer (GCL) of the cerebellar cortex have been identified previously in the awake rat and monkey during immobility. These low-frequency oscillations are thought to be generated through local circuit interactions between Golgi cells and granule cells within the GCL. Golgi cells display rhythmic firing and pacemaking properties, and also are electrically coupled through gap junctions within the GCL. Here, we tested if gap junctions in the rat cerebellar cortex contribute to the generation of LFP oscillations in the GCL. We recorded LFP oscillations under urethane anesthesia, and examined the effects of local infusion of gap junction blockers on 5-15 Hz oscillations. Local infusion of the gap junction blockers carbenoxolone and mefloquine resulted in significant decreases in the power of oscillations over a 30-min period, but the power of oscillations was unchanged in control experiments following vehicle injections. In addition, infusion of gap junction blockers had no significant effect on multi-unit activity, suggesting that the attenuation of low-frequency oscillations was likely due to reductions in electrical coupling rather than a decreased excitability within the granule cell layer. Our results indicate that electrical coupling among the Golgi cell networks in the cerebellar cortex contributes to the local circuit mechanisms that promote the occurrence of GCL LFP slow oscillations in the anesthetized rat.

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“…Interpreting the spontaneous cerebellocortical rhythms is particularly difficult, owing to the multitude of both peripheral and central inputs to cerebellar cortex and the high spontaneous activity of its principal neurons, the Purkinje cells (Bremer, 1958;Cebolla et al, 2016;Courtemanche et al, 2013;Middleton et al, 2008). On the other hand, it has been argued that cerebellar cortex and neocortex may generate the same rhythms independently (Niedermeyer, 2004).…”

Section: Extrapolation From Cerebellar Cortex To Other Brain Regionsmentioning

confidence: 99%

An Interneuron Circuit Reproducing Essential Spectral Features of Field Potentials

Maex

2018

Neural Computation

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Recent advances in engineering and signal processing have renewed the interest in invasive and surface brain recordings, yet many features of cortical field potentials remain incompletely understood.In the present computational study, we show that a model circuit of interneurons, coupled via both GABA A receptor synapses and electrical synapses, reproduces many essential features of the power spectrum of local field potential (LFP) recordings, such as 1/f power scaling at low (< 15 Hz) frequencies, power accumulation in the γ-frequency band (30-100 Hz), and a robust α rhythm in the absence of stimulation. The low-frequency 1/f power scaling depends on strong reciprocal inhibition, whereas the α rhythm is generated by electrical coupling of intrinsically active neurons. As in previous studies, the γ power arises through the amplification of single-neuron spectral properties, owing to the refractory period, by parameters that favour neuronal synchrony, such as delayed inhibition. The present study also confirms that both synaptic and voltage-gated membrane currents substantially contribute to the LFP, and that high-frequency signals such as action potentials quickly taper off with distance. Given the ubiquity of electrically coupled interneuron circuits in the mammalian brain, they may be major determinants of the recorded potentials.

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Linking oscillations in cerebellar circuits

Cited by 51 publications

References 178 publications

“Cerebellar contribution to visuo-attentional alpha rhythm: insights from weightlessness”

“Cerebellar contribution to visuo-attentional alpha rhythm: insights from weightlessness”

Gap Junction Modulation of Low-Frequency Oscillations in the Cerebellar Granule Cell Layer

An Interneuron Circuit Reproducing Essential Spectral Features of Field Potentials

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