Deep brain stimulation for Parkinson's disease modulates high-frequency evoked and spontaneous neural activity

Sinclair, Nicholas C; McDermott, Hugh J.; Fallon, James B; Perera, Thushara; Brown, Peter; Bulluss, Kristian J; Thevathasan, Wesley

doi:10.1016/j.nbd.2019.104522

Cited by 52 publications

(95 citation statements)

References 55 publications

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“…It is important to note that a contradictory hypothesis was suggested by Sinclair et al 44 , since the authors report a decrease in HFO frequency after high-frequency DBS. The authors suggested that DBS and dopaminergic therapy have different mechanisms of action.…”

Section: Dbsmentioning

confidence: 91%

Electroceutically induced subthalamic high frequency oscillations and evoked compound activity may explain the mechanism of therapeutic stimulation in Parkinson's Disease

Öztürk

Viswanathan

Sheth

et al. 2020

Preprint

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Despite having remarkable utility in treating movement disorders, the lack of understanding of the underlying mechanisms of high-frequency deep brain stimulation (DBS) is a main challenge in choosing personalized stimulation parameters. Here we investigate the modulations in local field potentials induced by therapeutic and non-therapeutic electrical stimulation of the subthalamic nucleus (STN) in Parkinson’s disease patients undergoing DBS surgery. We find that therapeutic high-frequency stimulation (130-180 Hz) induces high-frequency oscillations (~300 Hz, HFO) similar to those observed with pharmacological treatment. Along with HFOs, we also observed evoked compound activity (ECA) after each stimulation pulse. While ECA was observed in both therapeutic and non-therapeutic (20Hz) stimulation, the HFOs were induced only with therapeutic frequencies and the associated ECA were significantly more resonant. The relative degree of enhancement in the HFO power was related to the interaction of stimulation pulse with the phase of ECA.We propose that high-frequency STN-DBS tunes the neural oscillations to their healthy/treated state, similar to pharmacological treatment, and the stimulation frequency to maximize these oscillations can be inferred from the phase of ECA waveforms of individual subjects. The induced HFOs can, therefore, be utilized as a marker of successful re-calibration of the dysfunctional circuit generating PD symptoms.

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Section: Dbsmentioning

confidence: 91%

Electroceutically induced subthalamic high frequency oscillations and evoked compound activity may explain the mechanism of therapeutic stimulation in Parkinson's Disease

Öztürk

Viswanathan

Sheth

et al. 2020

Preprint

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“…These findings raise the possibility that the ERNA amplitude could help guide electrode contact selection. Moreover, the frequency of ERNA modulates during DBS (Supplementary Figure S4E), reducing on average from around 310 Hz pre-therapy to around 260 Hz when therapy reaches clinically effective levels (Sinclair et al, 2019). It is intriguing that the latter value is around twice the commonly employed applied STN DBS frequency of 130 Hz, though it is crucial to note that the plateau frequency that ERNA reaches with therapeutic DBS differs between individuals.…”

Section: Dbs Local Evoked Potentials: the Ernamentioning

confidence: 97%

“…However, these oscillations are small (<15 µV), and can be difficult to detect in and across certain conditions. In this light, we propose a new biomarker, evoked resonant neural activity (ERNA), which is significantly larger than the beta band (>100 µV) and can be reliably recorded across all conditions (Sinclair et al, 2018(Sinclair et al, , 2019. ERNA is evoked and recorded from within the STN itself and is generated by a train of square biphasic pulses.…”

Section: Dbs Local Evoked Potentials: the Ernamentioning

confidence: 99%

“…Future work will assess whether the plateau frequency that ERNA reaches with therapeutic DBS could inform on the ideal DBS frequency to apply in individuals. During DBS, modulation of ERNA frequency correlates with the amplitude of beta oscillations (a useful surrogate of the clinical state of the patient; Supplementary Figure S4F; Sinclair et al, 2019). During programming, the ERNA could facilitate optimization of more precise settings, especially given that there is a larger amplitude in the dorsal motor region of the STN (Sinclair et al, 2018).…”

Section: Dbs Local Evoked Potentials: the Ernamentioning

confidence: 99%

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Proceedings of the Seventh Annual Deep Brain Stimulation Think Tank: Advances in Neurophysiology, Adaptive DBS, Virtual Reality, Neuroethics and Technology

Ramirez‐Zamora

Giordano

Gündüz

et al. 2020

Front. Hum. Neurosci.

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“…The advantage of these signals is that they use methods of synchronous detection to avoid artifacts. Similar to chopper methods to remove low-frequency offset and drift [25], if the stimulation frequency is above the cardiac energy, then the impact of the cardiac artifact is greatly attenuated. The major trade-off of this technique is the bandwidth required for sampling, typically ten times higher than for low frequency field potentials, and the need to manage stimulation artifacts to allow for resolution of physiological signals within milliseconds of stimulation termination [24], [26].…”

Section: Model Interpretationmentioning

confidence: 99%

Physiological Artefacts and the Implications for Brain-Machine-Interface Design

Sorkhabi

Benjaber

Brown³

et al. 2020

Preprint

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The accurate measurement of brain activity by Brain-Machine-Interfaces (BMI) and closed-loop Deep Brain Stimulators (DBS) is one of the most important steps in communicating between the brain and subsequent processing blocks. In conventional chest-mounted systems, frequently used in DBS, a significant amount of artifact can be induced in the sensing interface, often as a common-mode signal applied between the case and the sensing electrodes. Attenuating this common-mode signal can be a serious challenge in these systems due to finite commonmode-rejection-ratio (CMRR) capability in the interface. Emerging BMI and DBS devices are being developed which can mount on the skull. Mounting the system on the cranial region can potentially suppress these induced physiological signals by limiting the artifact amplitude. In this study, we model the effect of artifacts by focusing on cardiac activity, using a current-source dipole model in a torso-shaped volume conductor. Performing finite element simulation with the different DBS architectures, we estimate the ECG common mode artifacts for several device architectures. Using this model helps define the overall requirements for the total system CMRR to maintain resolution of brain activity. The results of the simulations estimate that the cardiac artifacts for skull-mounted systems will have a significantly lower effect than non-cranial systems that include the pectoral region. It is expected that with a pectoral mounted device, a minimum of 60-80 dB CMRR is required to suppress the ECG artifact, while in cranially-mounted devices, a 20 dB CMRR is sufficient, in the worst-case scenario. The methods used for estimating cardiac artifacts can be extended to other sources such as motion/muscle sources. The susceptibility of the device to artifacts has significant implications for the practical translation of closed-loop DBS and BMI, including the choice of biomarkers and the design requirements for insulators and lead systems. Keywords-Deep brain stimulation, Cranial mounted DBS, ECG artifact, Current-source dipole model, Finite element method.I.

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Deep brain stimulation for Parkinson's disease modulates high-frequency evoked and spontaneous neural activity

Cited by 52 publications

References 55 publications

Electroceutically induced subthalamic high frequency oscillations and evoked compound activity may explain the mechanism of therapeutic stimulation in Parkinson's Disease

Electroceutically induced subthalamic high frequency oscillations and evoked compound activity may explain the mechanism of therapeutic stimulation in Parkinson's Disease

Proceedings of the Seventh Annual Deep Brain Stimulation Think Tank: Advances in Neurophysiology, Adaptive DBS, Virtual Reality, Neuroethics and Technology

Physiological Artefacts and the Implications for Brain-Machine-Interface Design

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