Phase-dependent closed-loop modulation of neural oscillations in vivo

Cg, McNamara; Rothwell, Max; Sharott, Andrew

doi:10.1101/2020.05.21.102335

Cited by 16 publications

(12 citation statements)

References 53 publications

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“…For other approaches, it could be possible to utilise the lower amplitude information. Several authors have postulated that phase-dependent stimulation could be an effective therapeutic strategy for treating motor symptoms ( Rosin et al, 2011 ; Azodi-Avval and Gharabaghi, 2015 ; Holt et al, 2016 ; Meidahl et al, 2017 ) and we have recently demonstrated the potential efficacy of this approach ( Holt et al, 2019 ; McNamara et al, 2020 ).…”

Section: Discussionmentioning

confidence: 71%

Parkinson's disease uncovers an underlying sensitivity of subthalamic nucleus neurons to beta-frequency cortical input in vivo

Baaske

Kormann

Holt

et al. 2020

Neurobiology of Disease

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Abnormally sustained beta-frequency synchronisation between the motor cortex and subthalamic nucleus (STN) is associated with motor symptoms in Parkinson's disease (PD). It is currently unclear whether STN neurons have a preference for beta-frequency input (12-35 Hz), rather than cortical input at other frequencies, and how such a preference would arise following dopamine depletion. To address this question, we combined analysis of cortical and STN recordings from awake human PD patients undergoing deep brain stimulation surgery with recordings of identified STN neurons in anaesthetised rats. In these patients, we demonstrate that a subset of putative STN neurons is strongly and selectively sensitive to magnitude fluctuations of cortical beta oscillations over time, linearly increasing their phase-locking strength with respect to the full range of instantaneous amplitude in the beta-frequency range. In rats, we probed the frequency response of STN neurons in the cortico-basal-ganglia-network more precisely, by recording spikes evoked by short bursts of cortical stimulation with variable frequency (4-40 Hz) and constant amplitude. In both healthy and dopamine-depleted rats, only beta-frequency stimulation led to a progressive reduction in the variability of spike timing through the stimulation train. This suggests, that the interval of beta-frequency input provides an optimal window for eliciting the next spike with high fidelity. We hypothesize, that abnormal activation of the indirect pathway, via dopamine depletion and/or cortical stimulation, could trigger an underlying sensitivity of the STN microcircuit to beta-frequency input.

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Section: Discussionmentioning

confidence: 71%

Parkinson's disease uncovers an underlying sensitivity of subthalamic nucleus neurons to beta-frequency cortical input in vivo

Baaske

Kormann

Holt

et al. 2020

Neurobiology of Disease

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“…Additionally tracking phase may augment therapeutic benefit, though, by delivering stimulation pulses at specific points within the oscillatory cycle. This has been shown to effectively disrupt pathological oscillations [10][11][12]17 . So far, to our knowledge, adaptive stimulation algorithms integrating both the phase and amplitude of a signal have not been established yet.…”

Section: Discussionmentioning

confidence: 99%

“…A special application is developing efficient sensing algorithms for adaptive deep brain stimulation, a recent advancement of a widely used treatment option for Parkinson's disease and other neurological disorders 5 . One of the directions in this development is to adjust stimulation parameters according to a peripheral or neurophysiological signal's phase and amplitude computed on the fly [6][7][8][9][10][11][12] . The popular approach to phase and amplitude estimation is to exploit the analytic signal approach based on the Hilbert Transform (HT) or, equivalently, the wavelet transform with a complex wavelet 1,[13][14][15] .…”

Section: Introductionmentioning

confidence: 99%

Real-time estimation of phase and amplitude with application to neural data

Rosenblum¹,

Pikovsky²,

Kühn³

et al. 2021

Preprint

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Computation of the instantaneous phase and amplitude via the Hilbert Transform is a powerful tool of data analysis. This approach finds many applications in various science and engineering branches but is not proper for causal estimation because it requires knowledge of the signal's past and future. However, several problems require real-time estimation of phase and amplitude; an illustrative example is phase-locked or amplitude-dependent stimulation in neuroscience. In this paper, we discuss and compare three causal algorithms that do not rely on the Hilbert Transform but exploit well-known physical phenomena, the synchronization and the resonance. After testing the algorithms on a synthetic data set, we illustrate their performance computing phase and amplitude for the accelerometer tremor measurements and a Parkinsonian patient's beta-band brain activity.

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“…Similarly, adaptive DBS for Parkinson's disease is being trialled in humans, but this is currently limited to adjusting the amplitude of open-loop stimulation (Arlotti et al, 2018). However, phase-dependent electrical stimulation delivered to the globus pallidus has recently been used to disrupt pathological oscillations recorded in the overlying cortex of rodents (McNamara et al, 2020), while optogenetics would allow such stimulation to be controlled in realtime by abnormal activity recorded from the local network without interference from artefacts. Optogenetic therapies for epilepsy have been demonstrated in rodent models, but thus far these consist of continuous inhibitory stimulation delivered once a seizure is detected (Paz et al, 2013, Krook-Magnuson et al, 2013.…”

Section: Discussionmentioning

confidence: 99%

Closed-loop optogenetic control of normal and pathological network dynamics

Zaaimi¹,

Turnbull²,

Hazra³

et al. 2020

Preprint

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Electrical neurostimulation is effective in treating neurological disorders, but associated recording artefacts generally limit applications to ‘open-loop’ stimuli. Since light does not prevent concurrent electrical recordings, optogenetics enables real-time, continuous ‘closed-loop’ control of brain activity. Here we show that closed-loop optogenetic stimulation with excitatory opsins (CLOSe) affords precise manipulation of neural dynamics, both in vitro, in brain slices from transgenic mice, and in vivo, with anesthetised monkeys. We demonstrate the generation of oscillations in quiescent tissue, enhancement or suppression of endogenous patterns in active tissue, and modulation of seizure-like bursts elicited by 4-aminopyridine. New network properties, emergent under CLOSe, depended on the phase-shift imposed between neural activity and optical stimulation, and could be modelled with a nonlinear dynamical system. In particular, CLOSe could stabilise or destabilise limit cycles associated with seizure oscillations, evident from systematic changes in the variability and entropy of seizure trajectories that correlated with their altered duration and intensity. Furthermore, CLOSe was achieved using intracortical optrodes incorporating light-emitting diodes, paving the way for translation of closed-loop optogenetics towards therapeutic applications in humans.

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Phase-dependent closed-loop modulation of neural oscillations in vivo

Cited by 16 publications

References 53 publications

Parkinson's disease uncovers an underlying sensitivity of subthalamic nucleus neurons to beta-frequency cortical input in vivo

Parkinson's disease uncovers an underlying sensitivity of subthalamic nucleus neurons to beta-frequency cortical input in vivo

Real-time estimation of phase and amplitude with application to neural data

Closed-loop optogenetic control of normal and pathological network dynamics

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