Dissociation of duration-based and beat-based auditory timing in cerebellar degeneration

Grube, Manon; Cooper, Freya E.; Chinnery, Patrick F.; Griffiths, Timothy D.

doi:10.1073/pnas.0910473107

Cited by 168 publications

(201 citation statements)

References 60 publications

(81 reference statements)

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“…The cerebellum also responds more during learning of non-metric than metric rhythms [40]. The fMRI findings are supported by findings from other methods: deficits in encoding of single durations, but not of metric sequences, occur when cerebellar function is disrupted, either by disease [41] or through transcranial magnetic stimulation [42]. Thus, although the cerebellum is commonly activated during rhythm tasks, the evidence indicates it is involved in absolute, not relative, timing and therefore does not play a significant role in beat perception or entrainment.…”

Section: Functional Imaging Of Beat Perception and Entrainment In Humanssupporting

confidence: 74%

Finding the beat: a neural perspective across humans and non-human primates

Merchant¹,

Grahn

Trainor

et al. 2015

Phil. Trans. R. Soc. B

316

262

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One contribution of 12 to a theme Issue 'Biology, cognition and origins of musicality'. Humans possess an ability to perceive and synchronize movements to the beat in music ('beat perception and synchronization'), and recent neuroscientific data have offered new insights into this beat-finding capacity at multiple neural levels. Here, we review and compare behavioural and neural data on temporal and sequential processing during beat perception and entrainment tasks in macaques (including direct neural recording and local field potential (LFP)) and humans (including fMRI, EEG and MEG). These abilities rest upon a distributed set of circuits that include the motor cortico-basalganglia-thalamo-cortical (mCBGT) circuit, where the supplementary motor cortex (SMA) and the putamen are critical cortical and subcortical nodes, respectively. In addition, a cortical loop between motor and auditory areas, connected through delta and beta oscillatory activity, is deeply involved in these behaviours, with motor regions providing the predictive timing needed for the perception of, and entrainment to, musical rhythms. The neural discharge rate and the LFP oscillatory activity in the gamma-and beta-bands in the putamen and SMA of monkeys are tuned to the duration of intervals produced during a beat synchronization-continuation task (SCT). Hence, the tempo during beat synchronization is represented by different interval-tuned cells that are activated depending on the produced interval. In addition, cells in these areas are tuned to the serial-order elements of the SCT. Thus, the underpinnings of beat synchronization are intrinsically linked to the dynamics of cell populations tuned for duration and serial order throughout the mCBGT. We suggest that a cross-species comparison of behaviours and the neural circuits supporting them sets the stage for a new generation of neurally grounded computational models for beat perception and synchronization.

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Section: Functional Imaging Of Beat Perception and Entrainment In Humanssupporting

confidence: 74%

Finding the beat: a neural perspective across humans and non-human primates

Merchant¹,

Grahn

Trainor

et al. 2015

Phil. Trans. R. Soc. B

316

262

View full text Add to dashboard Cite

show abstract

“…Therefore, our results strongly support the notion that the mCBGT circuit is part of the beat-based timing mechanism, with a global entrainment in the ␤ band during the production of internally timed movements. On the other hand, the cerebellum takes part in absolute timing (Grahn and Rowe, 2009;Grube et al, 2010;Teki et al, 2011) or in the processing of temporal prediction errors, which can occur during the RTT (Teki et al, 2012). However, the mCBGT circuit and the cerebellum are not isolated systems.…”

Section: Discussionmentioning

confidence: 99%

β Oscillations Are Linked to the Initiation of Sensory-Cued Movement Sequences and the Internal Guidance of Regular Tapping in the Monkey

2015

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␤ oscillations in the basal ganglia have been associated with interval timing. We recorded the putaminal local field potentials (LFPs) from monkeys performing a synchronization-continuation task (SCT) and a serial reaction-time task (RTT), where the animals produced regularly and irregularly paced tapping sequences, respectively. We compared the activation profile of ␤ oscillations between tasks and found transient bursts of ␤ activity in both the RTT and SCT. During the RTT, ␤ power was higher at the beginning of the task, especially when LFPs were aligned to the stimuli. During the SCT, ␤ was higher during the internally driven continuation phase, especially for tap-aligned LFPs. Interestingly, a set of LFPs showed an initial burst of ␤ at the beginning of the SCT, similar to the RTT, followed by a decrease in ␤ oscillations during the synchronization phase, to finally rebound during the continuation phase. The rebound during the continuation phase of the SCT suggests that the corticostriatal circuit is involved in the control of internally driven motor sequences. In turn, the transient bursts of ␤ activity at the beginning of both tasks suggest that the basal ganglia produce a general initiation signal that engages the motor system in different sequential behaviors.

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“…However, some recent studies have investigated the timing of successive intervals and yielded results suggesting that different neural substrates are engaged, depending on whether or not an underlying beat is perceived (Grube, Cooper, Chinnery, & Griffiths, 2010;Teki, Grube, Kumar, & Griffiths, 2011). A duration-based mechanism is thought to be responsible for timing successive intervals in the absence of a beat, and it recruits an olivo-cerebellar network.…”

Section: Timing Mechanismsmentioning

confidence: 99%

Sensorimotor synchronization: A review of recent research (2006–2012)

2013

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Sensorimotor synchronization (SMS) is the coordination of rhythmic movement with an external rhythm, ranging from finger tapping in time with a metronome to musical ensemble performance. An earlier review (Repp, 2005) covered tapping studies; two additional reviews (Repp, 2006a, b) focused on music performance and on rate limits of SMS, respectively. The present article supplements and extends these earlier reviews by surveying more recent research in what appears to be a burgeoning field. The article comprises four parts, dealing with (1) conventional tapping studies, (2) other forms of moving in synchrony with external rhythms (including dance and nonhuman animals' synchronization abilities), (3) interpersonal synchronization (including musical ensemble performance), and (4) the neuroscience of SMS. It is evident that much new knowledge about SMS has been acquired in the last 7 years.

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Dissociation of duration-based and beat-based auditory timing in cerebellar degeneration

Cited by 168 publications

References 60 publications

Finding the beat: a neural perspective across humans and non-human primates

Finding the beat: a neural perspective across humans and non-human primates

β Oscillations Are Linked to the Initiation of Sensory-Cued Movement Sequences and the Internal Guidance of Regular Tapping in the Monkey

Sensorimotor synchronization: A review of recent research (2006–2012)

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