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3. Modulation of basal ganglia local field potentials by deep brain stimulation in Parkinson's disease and dystonia

Author

Wiest, Christoph, Tan, Huiling, Sharott, Andrew, Torrecillos, Flavie, and Brown, Peter

Subjects
Clinical Neurosciences
Abstract

Subthalamic (STN) deep brain stimulation (DBS) is an effective treatment option in advanced Parkinson's disease, however, its underlying mechanism remains largely speculative. Continuous DBS may come with side effects such as speech impairment, paraesthesia and mood changes, which necessitates research into adaptive DBS. Adaptive DBS requires feedback signals reflecting pathological activity to guide stimulation. Previous studies have focused on beta oscillations in the STN as a potential biomarker for parkinsonian symptoms and beta power suppression has been suggested as a potential action mechanism of DBS. In this thesis, we sought to investigate mechanisms underlying STN stimulation beyond beta power suppression and studied other potential feedback markers to improve current frameworks of adaptive DBS. In the first part, we performed local field potential (LFP) recordings from Parkinson's disease patients and studied evoked and induced changes with DBS. DBS-evoked resonant neural activity (ERNA) consists of a high-frequency, high-amplitude activity focal to dorsolateral STN that has fast and slow components. Furthermore, the ERNA is highly adjustable and varies with different DBS frequencies, intensities, medication states and stimulation modes. DBS also induced instantaneous power suppression in the beta and gamma frequency range and de-novo finely-tuned gamma (FTG) oscillations that are modulated during and after DBS. In the second part, we demonstrate in rodent data that aperiodic exponents of subthalamic LFPs reflect excitatory and inhibitory input to STN and report higher aperiodic exponents ON levodopa and stimulation, in keeping with more inhibition. Subsequently, we found aperiodic exponent changes with levodopa and DBS in Parkinson's disease patients, consistent with more inhibition of STN when symptoms are alleviated. In the third part, we recorded subthalamic and thalamic LFPs from cervical dystonia patients and found that neither ERNA, FTG, power suppression or aperiodic exponent changes with DBS are specific to Parkinson's disease. Overall, this thesis extends the knowledge on existing feedback signals for adaptive DBS and supports the inactivation hypothesis of subthalamic DBS.

Published
2022

7. Perspectives of Implementation of Closed-Loop Deep Brain Stimulation: From Neurological to Psychiatric Disorders.

Author

Groppa, Sergiu, Gonzalez-Escamilla, Gabriel, Tinkhauser, Gerd, Baqapuri, Halim Ibrahim, Sajonz, Bastian, Wiest, Christoph, Pereira, Joana, Herz, Damian M., Dold, Matthias R., Bange, Manuel, Ciolac, Dumitru, Almeida, Viviane, Neuber, John, Mirzac, Daniela, Martín-Rodríguez, Juan Francisco, Dresel, Christian, Muthuraman, Muthuraman, Adarmes Gomez, Astrid D., Navas, Marta, and Temiz, Gizem

Abstract

Background: Deep brain stimulation (DBS) is a highly efficient, evidence-based therapy to alleviate symptoms and improve quality of life in movement disorders such as Parkinson's disease, essential tremor, and dystonia, which is also being applied in several psychiatric disorders, such as obsessive-compulsive disorder and depression, when they are otherwise resistant to therapy. Summary: At present, DBS is clinically applied in the so-called open-loop approach, with fixed stimulation parameters, irrespective of the patients' clinical state(s). This approach ignores the brain states or feedback from the central nervous system or peripheral recordings, thus potentially limiting its efficacy and inducing side effects by stimulation of the targeted networks below or above the therapeutic level. Key Messages: The currently emerging closed-loop (CL) approaches are designed to adapt stimulation parameters to the electrophysiological surrogates of disease symptoms and states. CL-DBS paves the way for adaptive personalized DBS protocols. This review elaborates on the perspectives of the CL technology and discusses its opportunities as well as its potential pitfalls for both clinical and research use in neuropsychiatric disorders. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Beta-triggered adaptive deep brain stimulation during reaching movement in Parkinson's disease.

Author

He, Shenghong, Baig, Fahd, Merla, Anca, Torrecillos, Flavie, Perera, Andrea, Wiest, Christoph, Debarros, Jean, Benjaber, Moaad, Hart, Michael G, Ricciardi, Lucia, Morgante, Francesca, Hasegawa, Harutomo, Samuel, Michael, Edwards, Mark, Denison, Timothy, Pogosyan, Alek, Ashkan, Keyoumars, Pereira, Erlick, and Tan, Huiling

Subjects
DEEP brain stimulation, PARKINSON'S disease, SUBTHALAMIC nucleus, BRAIN stimulation
Abstract

Subthalamic nucleus (STN) beta-triggered adaptive deep brain stimulation (ADBS) has been shown to provide clinical improvement comparable to conventional continuous DBS (CDBS) with less energy delivered to the brain and less stimulation induced side effects. However, several questions remain unanswered. First, there is a normal physiological reduction of STN beta band power just prior to and during voluntary movement. ADBS systems will therefore reduce or cease stimulation during movement in people with Parkinson's disease and could therefore compromise motor performance compared to CDBS. Second, beta power was smoothed and estimated over a time period of 400 ms in most previous ADBS studies, but a shorter smoothing period could have the advantage of being more sensitive to changes in beta power, which could enhance motor performance. In this study, we addressed these two questions by evaluating the effectiveness of STN beta-triggered ADBS using a standard 400 ms and a shorter 200 ms smoothing window during reaching movements. Results from 13 people with Parkinson's disease showed that reducing the smoothing window for quantifying beta did lead to shortened beta burst durations by increasing the number of beta bursts shorter than 200 ms and more frequent switching on/off of the stimulator but had no behavioural effects. Both ADBS and CDBS improved motor performance to an equivalent extent compared to no DBS. Secondary analysis revealed that there were independent effects of a decrease in beta power and an increase in gamma power in predicting faster movement speed, while a decrease in beta event related desynchronization (ERD) predicted quicker movement initiation. CDBS suppressed both beta and gamma more than ADBS, whereas beta ERD was reduced to a similar level during CDBS and ADBS compared with no DBS, which together explained the achieved similar performance improvement in reaching movements during CDBS and ADBS. In addition, ADBS significantly improved tremor compared with no DBS but was not as effective as CDBS. These results suggest that STN beta-triggered ADBS is effective in improving motor performance during reaching movements in people with Parkinson's disease, and that shortening of the smoothing window does not result in any additional behavioural benefit. When developing ADBS systems for Parkinson's disease, it might not be necessary to track very fast beta dynamics; combining beta, gamma, and information from motor decoding might be more beneficial with additional biomarkers needed for optimal treatment of tremor. [ABSTRACT FROM AUTHOR]

Published
2023
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9. The aperiodic exponent of subthalamic field potentials reflects excitation/inhibition balance in Parkinsonism.

Author

Wiest, Christoph, Torrecillos, Flavie, Pogosyan, Alek, Bange, Manuel, Muthuraman, Muthuraman, Groppa, Sergiu, Hulse, Natasha, Hasegawa, Harutomo, Ashkan, Keyoumars, Baig, Fahd, Morgante, Francesca, Pereira, Erlick A., Mallet, Nicolas, Magill, Peter J., Brown, Peter, Sharott, Andrew, and Huiling Tan

Subjects
*SUBTHALAMIC nucleus, *DOPAMINERGIC neurons, *PARKINSON'S disease, *DEEP brain stimulation, *ACTION potentials, *PARKINSONIAN disorders, *EXPONENTS, *OCCLUSION (Chemistry)
Abstract

Periodic features of neural time-series data, such as local field potentials (LFPs), are often quantified using power spectra. While the aperiodic exponent of spectra is typically disregarded, it is nevertheless modulated in a physiologically relevant manner and was recently hypothesised to reflect excitation/inhibition (E/I) balance in neuronal populations. Here, we used a cross-species in vivo electrophysiological approach to test the E/I hypothesis in the context of experimental and idiopathic Parkinsonism. We demonstrate in dopamine-depleted rats that aperiodic exponents and power at 30-100 Hz in subthalamic nucleus (STN) LFPs reflect defined changes in basal ganglia network activity; higher aperiodic exponents tally with lower levels of STN neuron firing and a balance tipped towards inhibition. Using STN-LFPs recorded from awake Parkinson's patients, we show that higher exponents accompany dopaminergic medication and deep brain stimulation (DBS) of STN, consistent with untreated Parkinson's manifesting as reduced inhibition and hyperactivity of STN. These results suggest that the aperiodic exponent of STN-LFPs in Parkinsonism reflects E/I balance and might be a candidate biomarker for adaptive DBS. [ABSTRACT FROM AUTHOR]

Published
2023
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10. Subthalamic Nucleus Stimulation–Induced Local Field Potential Changes in Dystonia.

Author

Wiest, Christoph, Morgante, Francesca, Torrecillos, Flavie, Pogosyan, Alek, He, Shenghong, Baig, Fahd, Bertaina, Ilaria, Hart, Michael G., Edwards, Mark J., Pereira, Erlick A., and Tan, Huiling

Abstract

Background: Subthalamic nucleus (STN) stimulation is an effective treatment for Parkinson's disease and induced local field potential (LFP) changes that have been linked with clinical improvement. STN stimulation has also been used in dystonia although the internal globus pallidus is the standard target where theta power has been suggested as a physiomarker for adaptive stimulation. Objective: We aimed to explore if enhanced theta power was also present in STN and if stimulation‐induced spectral changes that were previously reported for Parkinson's disease would occur in dystonia. Methods: We recorded LFPs from 7 patients (12 hemispheres) with isolated craniocervical dystonia whose electrodes were placed such that inferior, middle, and superior contacts covered STN, zona incerta, and thalamus. Results: We did not observe prominent theta power in STN at rest. STN stimulation induced similar spectral changes in dystonia as in Parkinson's disease, such as broadband power suppression, evoked resonant neural activity (ERNA), finely‐tuned gamma oscillations, and an increase in aperiodic exponents in STN‐LFPs. Both power suppression and ERNA localize to STN. Based on this, single‐pulse STN stimulation elicits evoked neural activities with largest amplitudes in STN, which are relayed to the zona incerta and thalamus with changing characteristics as the distance from STN increases. Conclusions: Our results show that STN stimulation–induced spectral changes are a nondisease‐specific response to high‐frequency stimulation, which can serve as placement markers for STN. This broadens the scope of STN stimulation and makes it an option for other disorders with excessive oscillatory peaks in STN. © 2022 The Authors. Movement Disorders published by Wiley Periodicals LLC on behalf of International Parkinson and Movement Disorder Society. [ABSTRACT FROM AUTHOR]

Published
2023
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12. Gait-Phase Modulates Alpha and Beta Oscillations in the Pedunculopontine Nucleus.

Author

Shenghong He, Deli, Alceste, Fischer, Petra, Wiest, Christoph, Yongzhi Huang, Martin, Sean, Khawaldeh, Saed, Aziz, Tipu Z., Green, Alexander L., Brown, Peter, and Huiling Tan

Subjects
SUBTHALAMIC nucleus, GAIT in humans, DEEP brain stimulation, MULTIPLE system atrophy, PARKINSONIAN disorders, PARKINSON'S disease
Abstract

The pedunculopontine nucleus (PPN) is a reticular collection of neurons at the junction of the midbrain and pons, playing an important role in modulating posture and locomotion. Deep brain stimulation of the PPN has been proposed as an emerging treatment for patients with Parkinson’s disease (PD) or multiple system atrophy (MSA) who have gait-related atypical parkinsonian syndromes. In this study, we investigated PPN activities during gait to better understand its functional role in locomotion. Specifically, we investigated whether PPN activity is rhythmically modulated by gait cycles during locomotion. PPN local field potential (LFP) activities were recorded from PD or MSA patients with gait difficulties during stepping in place or free walking. Simultaneous measurements from force plates or accelerometers were used to determine the phase within each gait cycle at each time point. Our results showed that activities in the alpha and beta frequency bands in the PPN LFPs were rhythmically modulated by the gait phase within gait cycles, with a higher modulation index when the stepping rhythm was more regular. Meanwhile, the PPN–cortical coherence was most prominent in the alpha band. Both gait phase-related modulation in the alpha/beta power and the PPN–cortical coherence in the alpha frequency band were spatially specific to the PPN and did not extend to surrounding regions. These results suggest that alternating PPN modulation may support gait control. Whether enhancing alternating PPN modulation by stimulating in an alternating fashion could positively affect gait control remains to be tested. [ABSTRACT FROM AUTHOR]

Published
2021
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13. Beta-triggered adaptive deep brain stimulation during reaching movement in Parkinson's disease.

Author

He S, Baig F, Merla A, Torrecillos F, Perera A, Wiest C, Debarros J, Benjaber M, Hart MG, Ricciardi L, Morgante F, Hasegawa H, Samuel M, Edwards M, Denison T, Pogosyan A, Ashkan K, Pereira E, and Tan H

Subjects
Humans, Tremor therapy, Movement physiology, Parkinson Disease therapy, Deep Brain Stimulation methods, Subthalamic Nucleus physiology
Abstract

Subthalamic nucleus (STN) beta-triggered adaptive deep brain stimulation (ADBS) has been shown to provide clinical improvement comparable to conventional continuous DBS (CDBS) with less energy delivered to the brain and less stimulation induced side effects. However, several questions remain unanswered. First, there is a normal physiological reduction of STN beta band power just prior to and during voluntary movement. ADBS systems will therefore reduce or cease stimulation during movement in people with Parkinson's disease and could therefore compromise motor performance compared to CDBS. Second, beta power was smoothed and estimated over a time period of 400 ms in most previous ADBS studies, but a shorter smoothing period could have the advantage of being more sensitive to changes in beta power, which could enhance motor performance. In this study, we addressed these two questions by evaluating the effectiveness of STN beta-triggered ADBS using a standard 400 ms and a shorter 200 ms smoothing window during reaching movements. Results from 13 people with Parkinson's disease showed that reducing the smoothing window for quantifying beta did lead to shortened beta burst durations by increasing the number of beta bursts shorter than 200 ms and more frequent switching on/off of the stimulator but had no behavioural effects. Both ADBS and CDBS improved motor performance to an equivalent extent compared to no DBS. Secondary analysis revealed that there were independent effects of a decrease in beta power and an increase in gamma power in predicting faster movement speed, while a decrease in beta event related desynchronization (ERD) predicted quicker movement initiation. CDBS suppressed both beta and gamma more than ADBS, whereas beta ERD was reduced to a similar level during CDBS and ADBS compared with no DBS, which together explained the achieved similar performance improvement in reaching movements during CDBS and ADBS. In addition, ADBS significantly improved tremor compared with no DBS but was not as effective as CDBS. These results suggest that STN beta-triggered ADBS is effective in improving motor performance during reaching movements in people with Parkinson's disease, and that shortening of the smoothing window does not result in any additional behavioural benefit. When developing ADBS systems for Parkinson's disease, it might not be necessary to track very fast beta dynamics; combining beta, gamma, and information from motor decoding might be more beneficial with additional biomarkers needed for optimal treatment of tremor., (© The Author(s) 2023. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published
2023
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14. Gait-Phase Modulates Alpha and Beta Oscillations in the Pedunculopontine Nucleus.

Author

He S, Deli A, Fischer P, Wiest C, Huang Y, Martin S, Khawaldeh S, Aziz TZ, Green AL, Brown P, and Tan H

Subjects
Aged, Electroencephalography methods, Female, Humans, Male, Middle Aged, Multiple System Atrophy physiopathology, Multiple System Atrophy therapy, Parkinson Disease physiopathology, Parkinson Disease therapy, Alpha Rhythm physiology, Beta Rhythm physiology, Deep Brain Stimulation methods, Gait physiology, Pedunculopontine Tegmental Nucleus physiology
Abstract

The pedunculopontine nucleus (PPN) is a reticular collection of neurons at the junction of the midbrain and pons, playing an important role in modulating posture and locomotion. Deep brain stimulation of the PPN has been proposed as an emerging treatment for patients with Parkinson's disease (PD) or multiple system atrophy (MSA) who have gait-related atypical parkinsonian syndromes. In this study, we investigated PPN activities during gait to better understand its functional role in locomotion. Specifically, we investigated whether PPN activity is rhythmically modulated by gait cycles during locomotion. PPN local field potential (LFP) activities were recorded from PD or MSA patients with gait difficulties during stepping in place or free walking. Simultaneous measurements from force plates or accelerometers were used to determine the phase within each gait cycle at each time point. Our results showed that activities in the alpha and beta frequency bands in the PPN LFPs were rhythmically modulated by the gait phase within gait cycles, with a higher modulation index when the stepping rhythm was more regular. Meanwhile, the PPN-cortical coherence was most prominent in the alpha band. Both gait phase-related modulation in the alpha/beta power and the PPN-cortical coherence in the alpha frequency band were spatially specific to the PPN and did not extend to surrounding regions. These results suggest that alternating PPN modulation may support gait control. Whether enhancing alternating PPN modulation by stimulating in an alternating fashion could positively affect gait control remains to be tested. SIGNIFICANCE STATEMENT The therapeutic efficacy of pedunculopontine nucleus (PPN) deep brain stimulation (DBS) and the extent to which it can improve quality of life are still inconclusive. Understanding how PPN activity is modulated by stepping or walking may offer insight into how to improve the efficacy of PPN DBS in ameliorating gait difficulties. Our study shows that PPN alpha and beta activity was modulated by the gait phase, and that this was most pronounced when the stepping rhythm was regular. It remains to be tested whether enhancing alternating PPN modulation by stimulating in an alternating fashion could positively affect gait control., (Copyright © 2021 He et al.)

Published
2021
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