Responses of the red nucleus neurons to limb stimulation after cerebellar lesions

Tarnecki, R

doi:10.1080/14734220309405

Cited by 12 publications

(14 citation statements)

References 20 publications

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“…These reasons, along with the data presented in Table 1, suggest that a direct and/or substantial contribution to the major cerebellar phenotype by transgene-expressing noncerebellar neurons is unlikely. These noncerebellar transgene-expressing neurons receive projections from the DCN (cerebello-rubral, cerebello-thalamic, cerebello-vestibular, and cerebello-reticular pathways), however, and they may therefore indirectly modify the phenotype (3,26). The absence of neurodegeneration suggests that an electrical alteration in the DCN, the only neurons in the cerebellum expressing the transgene, is the predominant cause of the observed cerebellar ataxia.…”

Section: Resultsmentioning

confidence: 97%

Enhanced neuronal excitability in the absence of neurodegeneration induces cerebellar ataxia

Shakkottai¹,

Chou²,

Oddo³

et al. 2004

J. Clin. Invest.

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Cerebellar ataxia, a devastating neurological disease, may be initiated by hyperexcitability of deep cerebellar nuclei (DCN) secondary to loss of inhibitory input from Purkinje neurons that frequently degenerate in this disease. This mechanism predicts that intrinsic DCN hyperexcitability would cause ataxia in the absence of upstream Purkinje degeneration. We report the generation of a transgenic (Tg) model that supports this mechanism of disease initiation. Small-conductance calciumactivated potassium (SK) channels, regulators of firing frequency, were silenced in the CNS of Tg mice with the dominant-inhibitory construct SK3-1B-GFP. Transgene expression was restricted to the DCN within the cerebellum and was detectable beginning on postnatal day 10, concomitant with the onset of cerebellar ataxia. Neurodegeneration was not evident up to the sixth month of age. Recordings from Tg DCN neurons revealed loss of the apamin-sensitive after-hyperpolarization current (I AHP ) and increased spontaneous firing through SK channel suppression, indicative of DCN hyperexcitability. Spike duration and other electrogenic conductance were unaffected. Thus, a purely electrical alteration is sufficient to cause cerebellar ataxia, and SK openers such as the neuroprotective agent riluzole may reduce neuronal hyperexcitability and have therapeutic value. This dominant-inhibitory strategy may help define the in vivo role of SK channels in other neuronal pathways.

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Section: Resultsmentioning

confidence: 97%

Enhanced neuronal excitability in the absence of neurodegeneration induces cerebellar ataxia

Shakkottai¹,

Chou²,

Oddo³

et al. 2004

J. Clin. Invest.

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“…What could be the explanation for a short time course of spinal excitability changes? One of the important loops subserving the two‐way communication between the sensory and motor systems is the spino–cerebello–rubro–spinal projection system (Tarnecki, 2003). This loop is linked to the musculature by the rubral projection to spinal motoneurones.…”

Section: Discussionmentioning

confidence: 99%

“…Rubrospinal neurones receive major input from cerebellar nuclei (Courville, 1966) and show intense responses to sensory stimuli. Moreover, behavioural data indicate that the cerebello–rubral system is involved in learning and memory (Rosenfield & Moore, 1983; Tarnecki, 2003). Interestingly, the major decrease in the spontaneous firing of rubrospinal neurones, which appears after hemicerebellectomy, is reversible (Toyama et al 1967; Tarnecki, 2003), and this could participate in the transient spinal excitability changes observed here.…”

Section: Discussionmentioning

confidence: 99%

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Hemicerebellectomy blocks the enhancement of cortical motor output associated with repetitive somatosensory stimulation in the rat

Nordeyn¹,

Manto²,

Pandolfo³

et al. 2005

The Journal of Physiology

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Repetitive peripheral stimulation is associated with an enhancement of the intensity of corticomotor responses. We analysed the effects of hemicerebellectomy on the modulation of cortical motor output associated with repetitive electrical stimulation of the sciatic nerve in the rat. Hemicerebellectomy blocked the enhancement of the corticomotor response. The cerebellum is a key player in this form of short-term plasticity.

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“…Modelling studies of cerebellar DCS indicate that the electric field (E) and the current density (J) spatial distributions occur mainly in the cerebellar cortex, with negligible spreads towards the brainstem [25]. Studies on cerebellar cortex ablation have confirmed the importance of Purkinje cell firings upon the discharges of cerebellar nuclei [27]. Such lesions cause a considerable increase in the background firing and cancel the pauses in discharges occurring in responses induced by somatosensory stimuli.…”

Section: Discussionmentioning

confidence: 99%

The in vivo reduction of afferent facilitation induced by low frequency electrical stimulation of the motor cortex is antagonized by cathodal direct current stimulation of the cerebellum

Taib

Manto

2016

cerebellum ataxias

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BackgroundLow-frequency electrical stimulation to the motor cortex (LFSMC) depresses the excitability of motor circuits by long-term depression (LTD)-like effects. The interactions between LFSMC and cathodal direct current stimulation (cDCS) over the cerebellum are unknown.MethodsWe assessed the corticomotor responses and the afferent facilitation of corticomotor responses during a conditioning paradigm in anaesthetized rats. We applied LFSMC at a frequency of 1 Hz and a combination of LFSMC with cDCS.ResultsLFSMC significantly depressed both the corticomotor responses and the afferent facilitation of corticomotor responses. Simultaneous application of cDCS over the cerebellum antagonized the depression of corticomotor responses and cancelled the depression of the afferent facilitation.ConclusionOur results demonstrate that cDCS of the cerebellum is a potent modulator the inhibition of the motor circuits induced by LFSMC applied in vivo. These results expand our understanding of the effects of cerebellar DCS on motor commands and open novel applications for a cerebellar remote control of LFSMC-induced neuroplasticity. We suggest that the cerebellum acts as a neuronal machine supervising not only long-term potentiation (LTP)-like effects, but also LTD-like effects in the motor cortex, two mechanisms which underlie cerebello-cerebral interactions and the cerebellar control of remote plasticity. Implications for clinical ataxiology are discussed.

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Responses of the red nucleus neurons to limb stimulation after cerebellar lesions

Cited by 12 publications

References 20 publications

Enhanced neuronal excitability in the absence of neurodegeneration induces cerebellar ataxia

Enhanced neuronal excitability in the absence of neurodegeneration induces cerebellar ataxia

Hemicerebellectomy blocks the enhancement of cortical motor output associated with repetitive somatosensory stimulation in the rat

The in vivo reduction of afferent facilitation induced by low frequency electrical stimulation of the motor cortex is antagonized by cathodal direct current stimulation of the cerebellum

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