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1. Multi-level encoding of reward, effort, and choice across the frontal cortex and basal ganglia during cost-benefit decision-making

Author

Oliver Härmson, Isaac Grennan, Brook Perry, Robert Toth, Colin G. McNamara, Timothy Denison, Hayriye Cagnan, Sanjay G. Manohar, Mark E. Walton, and Andrew Sharott

Subjects
CP: Neuroscience, Biology (General), QH301-705.5
Abstract

Summary: Adaptive value-guided decision-making requires weighing up the costs and benefits of pursuing an available opportunity. Though neurons across frontal cortical-basal ganglia circuits have been repeatedly shown to represent decision-related parameters, it is unclear whether and how this information is coordinated. To address this question, we performed large-scale single-unit recordings simultaneously across 5 medial/orbital frontal and basal ganglia regions as rats decided whether to pursue varying reward payoffs available at different effort costs. Single neurons encoding combinations of decision variables (reward, effort, and choice) were represented within all recorded regions. Coactive cell assemblies, ensembles of neurons that repeatedly coactivated within short time windows (

Published
2025
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2. Evoked resonant neural activity long-term dynamics can be reproduced by a computational model with vesicle depletion

Author

James J. Sermon, Christoph Wiest, Huiling Tan, Timothy Denison, and Benoit Duchet

Subjects
Evoked resonant neural activity, Deep brain stimulation, Subthalamic nucleus, parkinson's disease, Synaptic vesicle depletion, Computational modelling, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Subthalamic deep brain stimulation (DBS) robustly generates high-frequency oscillations known as evoked resonant neural activity (ERNA). Recently the importance of ERNA has been demonstrated through its ability to predict the optimal DBS contact in the subthalamic nucleus in patients with Parkinson's disease. However, the underlying mechanisms of ERNA are not well understood, and previous modelling efforts have not managed to reproduce the wealth of published data describing the dynamics of ERNA. Here, we aim to present a minimal model capable of reproducing the characteristics of the slow ERNA dynamics published to date. We make biophysically-motivated modifications to the Kuramoto model and fit its parameters to the slow dynamics of ERNA obtained from data. Our results demonstrate that it is possible to reproduce the slow dynamics of ERNA (over hundreds of seconds) with a single neuronal population, and, crucially, with vesicle depletion as one of the key mechanisms behind the ERNA frequency decay in our model. We further validate the proposed model against experimental data from Parkinson's disease patients, where it captures the variations in ERNA frequency and amplitude in response to variable stimulation frequency, amplitude, and to stimulation pulse bursting. We provide a series of predictions from the model that could be the subject of future studies for further validation.

Published
2024
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3. Multi-night cortico-basal recordings reveal mechanisms of NREM slow-wave suppression and spontaneous awakenings in Parkinson’s disease

Author

Md Fahim Anjum, Clay Smyth, Rafael Zuzuárregui, Derk Jan Dijk, Philip A. Starr, Timothy Denison, and Simon Little

Subjects
Science
Abstract

Abstract Sleep disturbance is a prevalent and disabling comorbidity in Parkinson’s disease (PD). We performed multi-night (n = 57) at-home intracranial recordings from electrocorticography and subcortical electrodes using sensing-enabled Deep Brain Stimulation (DBS), paired with portable polysomnography in four PD participants and one with cervical dystonia (clinical trial: NCT03582891). Cortico-basal activity in delta increased and in beta decreased during NREM (N2 + N3) versus wakefulness in PD. DBS caused further elevation in cortical delta and decrease in alpha and low-beta compared to DBS OFF state. Our primary outcome demonstrated an inverse interaction between subcortical beta and cortical slow-wave during NREM. Our secondary outcome revealed subcortical beta increases prior to spontaneous awakenings in PD. We classified NREM vs. wakefulness with high accuracy in both traditional (30 s: 92.6 ± 1.7%) and rapid (5 s: 88.3 ± 2.1%) data epochs of intracranial signals. Our findings elucidate sleep neurophysiology and impacts of DBS on sleep in PD informing adaptive DBS for sleep dysfunction.

Published
2024
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6. Development and Evaluation of a Real-Time Phase-Triggered Stimulation Algorithm for the CorTec Brain Interchange

Author

Hanbin Cho, Moaad Benjaber, C. Alexis Gkogkidis, Marina Buchheit, Juan F. Ruiz-Rodriguez, Benjamin L. Grannan, Kurt E. Weaver, Andrew L. Ko, Steven C. Cramer, Jeffrey G. Ojemann, Timothy Denison, and Jeffrey A. Herron

Subjects
Feedback, neurostimulation, signal processing, system analysis and design, Medical technology, R855-855.5, Therapeutics. Pharmacology, RM1-950
Abstract

With the development and characterization of biomarkers that may reflect neural network state as well as a patient’s clinical deficits, there is growing interest in more complex stimulation designs. While current implantable neuromodulation systems offer pathways to expand the design and application of adaptive stimulation paradigms, technological drawbacks of these systems limit adaptive neuromodulation exploration. In this paper, we discuss the implementation of a phase-triggered stimulation paradigm using a research platform composed of an investigational system known as the CorTec Brain Interchange (CorTec GmbH, Freiburg, Germany), and an open-source software tool known as OMNI-BIC. We then evaluate the stimulation paradigm’s performance in both benchtop and in vivo human demonstrations. Our findings indicate that the Brain Interchange and OMNI-BIC platform is capable of reliable administration of phase-triggered stimulation and has the potential to help expand investigation within the adaptive neuromodulation design space.

Published
2024
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7. Adaptive Deep Brain Stimulation for sleep stage targeting in Parkinson’s disease

Author

Clay Smyth, Md Fahim Anjum, Shravanan Ravi, Timothy Denison, Philip Starr, and Simon Little

Subjects
Adaptive Deep Brain Stimulation, Parkinson’s disease, Sleep, Real-time neural control, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Background: Sleep dysfunction is disabling in people with Parkinson’s disease and is linked to worse motor and non-motor outcomes. Sleep-specific adaptive Deep Brain Stimulation has the potential to target pathophysiologies of sleep. Objective: Develop an adaptive Deep Brain Stimulation algorithm that modulates stimulation parameters in response to intracranially classified sleep stages. Methods: We performed at-home, multi-night intracranial electrocorticography and polysomnogram recordings to train personalized linear classifiers for discriminating the N3 NREM sleep stage. Classifiers were embedded into investigational Deep Brain Stimulators for N3 specific adaptive DBS. Results: We report high specificity of embedded, autonomous, intracranial electrocorticography N3 sleep stage classification across two participants and provide proof-of-principle of successful sleep stage specific adaptive Deep Brain Stimulation. Conclusion: Multi-night cortico-basal recordings and sleep specific adaptive Deep Brain Stimulation provide an experimental framework to investigate sleep pathophysiology and mechanistic interactions with stimulation, towards the development of therapeutic neurostimulation paradigms directly targeting sleep dysfunction.

Published
2023
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8. Sub-harmonic entrainment of cortical gamma oscillations to deep brain stimulation in Parkinson's disease: Model based predictions and validation in three human subjects

Author

James J. Sermon, Maria Olaru, Juan Ansó, Stephanie Cernera, Simon Little, Maria Shcherbakova, Rafal Bogacz, Philip A. Starr, Timothy Denison, and Benoit Duchet

Subjects
Sub-harmonic entrainment, Deep brain stimulation, Cortical gamma oscillations, Parkinson's disease, Wilson-Cowan model, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Objectives: The exact mechanisms of deep brain stimulation (DBS) are still an active area of investigation, in spite of its clinical successes. This is due in part to the lack of understanding of the effects of stimulation on neuronal rhythms. Entrainment of brain oscillations has been hypothesised as a potential mechanism of neuromodulation. A better understanding of entrainment might further inform existing methods of continuous DBS, and help refine algorithms for adaptive methods. The purpose of this study is to develop and test a theoretical framework to predict entrainment of cortical rhythms to DBS across a wide range of stimulation parameters. Materials and Methods: We fit a model of interacting neural populations to selected features characterising PD patients' off-stimulation finely-tuned gamma rhythm recorded through electrocorticography. Using the fitted models, we predict basal ganglia DBS parameters that would result in 1:2 entrainment, a special case of sub-harmonic entrainment observed in patients and predicted by theory. Results: We show that the neural circuit models fitted to patient data exhibit 1:2 entrainment when stimulation is provided across a range of stimulation parameters. Furthermore, we verify key features of the region of 1:2 entrainment in the stimulation frequency/amplitude space with follow-up recordings from the same patients, such as the loss of 1:2 entrainment above certain stimulation amplitudes. Conclusion: Our results reveal that continuous, constant frequency DBS in patients may lead to nonlinear patterns of neuronal entrainment across stimulation parameters, and that these responses can be predicted by modelling. Should entrainment prove to be an important mechanism of therapeutic stimulation, our modelling framework may reduce the parameter space that clinicians must consider when programming devices for optimal benefit.

Published
2023
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9. The effect of pulse shape in theta-burst stimulation: Monophasic vs biphasic TMS

Author

Karen Wendt, Majid Memarian Sorkhabi, Charlotte J. Stagg, Melanie K. Fleming, Timothy Denison, and Jacinta O'Shea

Subjects
Transcranial magnetic stimulation (TMS), Theta burst stimulation (TBS), Pulse-width modulation based TMS, TMS pulse shape, Motor plasticity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Background: Intermittent theta-burst stimulation (i) (TBS) is a transcranial magnetic stimulation (TMS) plasticity protocol. Conventionally, TBS is applied using biphasic pulses due to hardware limitations. However, monophasic pulses are hypothesised to recruit cortical neurons more selectively than biphasic pulses, predicting stronger plasticity effects. Monophasic and biphasic TBS can be generated using a custom-made pulse-width modulation-based TMS device (pTMS). Objective: Using pTMS, we tested the hypothesis that monophasic iTBS would induce a stronger plasticity effect than biphasic, measured as induced increases in motor corticospinal excitability. Methods: In a repeated-measures design, thirty healthy volunteers participated in three separate sessions, where monophasic and biphasic iTBS was applied to the primary motor cortex (M1 condition) or the vertex (control condition). Plasticity was quantified as increases in motor corticospinal excitability after versus before iTBS, by comparing peak-to-peak amplitudes of motor evoked potentials (MEP) measured at baseline and over 60 min after iTBS. Results: Both monophasic and biphasic M1 iTBS led to significant increases in MEP amplitude. As predicted, linear mixed effects (LME) models showed that the iTBS condition had a significant effect on the MEP amplitude (χ2 (1) = 27.615, p

Published
2023
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13. Diurnal modulation of subthalamic beta oscillatory power in Parkinson’s disease patients during deep brain stimulation

Author

Joram J. van Rheede, Lucia K. Feldmann, Johannes L. Busch, John E. Fleming, Varvara Mathiopoulou, Timothy Denison, Andrew Sharott, and Andrea A. Kühn

Subjects
Neurology. Diseases of the nervous system, RC346-429
Abstract

Abstract Beta-band activity in the subthalamic local field potential (LFP) is correlated with Parkinson’s disease (PD) symptom severity and is the therapeutic target of deep brain stimulation (DBS). While beta fluctuations in PD patients are well characterized on shorter timescales, it is not known how beta activity evolves around the diurnal cycle, outside a clinical setting. Here, we obtained chronic recordings (34 ± 13 days) of subthalamic beta power in PD patients implanted with the Percept DBS device during high-frequency DBS and analysed their diurnal properties as well as sensitivity to artifacts. Time of day explained 41 ± 9% of the variance in beta power (p

Published
2022
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14. Toward therapeutic electrophysiology: beta-band suppression as a biomarker in chronic local field potential recordings

Author

Lucia K. Feldmann, Roxanne Lofredi, Wolf-Julian Neumann, Bassam Al-Fatly, Jan Roediger, Bahne H. Bahners, Petyo Nikolov, Timothy Denison, Assel Saryyeva, Joachim K. Krauss, Katharina Faust, Esther Florin, Alfons Schnitzler, Gerd-Helge Schneider, and Andrea A. Kühn

Subjects
Neurology. Diseases of the nervous system, RC346-429
Abstract

Abstract Adaptive deep brain stimulation (aDBS) is a promising concept for feedback-based neurostimulation, with the potential of clinical implementation with the sensing-enabled Percept neurostimulator. We aim to characterize chronic electrophysiological activity during stimulation and to validate beta-band activity as a biomarker for bradykinesia. Subthalamic activity was recorded during stepwise stimulation amplitude increase OFF medication in 10 Parkinson’s patients during rest and finger tapping. Offline analysis of wavelet-transformed beta-band activity and assessment of inter-variable relationships in linear mixed effects models were implemented. There was a stepwise suppression of low-beta activity with increasing stimulation intensity (p = 0.002). Low-beta power was negatively correlated with movement speed and predictive for velocity improvements (p

Published
2022
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15. Development and validation of a diagnostic aid for convulsive epilepsy in sub-Saharan Africa: a retrospective case-control study

Author

Gabriel Davis Jones, MD, Symon M Kariuki, PhD, Anthony K Ngugi, PhD, Angelina Kakooza Mwesige, PhD, Honorati Masanja, PhD, Seth Owusu-Agyei, ProfPhD, Ryan Wagner, PhD, J Helen Cross, ProfMD, Josemir W Sander, ProfPhD, Charles R Newton, ProfMD, Arjune Sen, ProfPhD, Hanna Abban, Patrick Adjei, Ken Ae-Ngibise, Francis Agbokey, Lisa Aissaoui, Albert Akpalu, Bright Akpalu, Sabina Asiamah, Gershim Asiki, Mercy Atieno, Evasius Bauni, Dan Bhwana, Mary Bitta, Christian Bottomley, Martin Chabi, Eddie Chengo, Neerja Chowdhary, Myles Connor, Helen Cross, Mark Collinson, Emmanuel Darkwa, Timothy Denison, Victor Doku, Tarun Dua, Isaac Egesa, Tony Godi, F. Xavier Gómez-Olivé, Simone Grassi, Samuel Iddi, Daniel Nana Yaw Abankwah Junior, Kathleen Kahn, Angelina Kakooza, Symon Kariuki, Gathoni Kamuyu, Clarah Khalayi, Henrika Kimambo, Immo Kleinschmidt, Thomas Kwasa, Sloan Mahone, Gergana Manolova, Honorati Masanja, Alexander Mathew, William Matuja, David McDaid, Bruno Mmbando, Daniel Mtai Mwanga, Dorcas Muli, Victor Mung'ala Odera, Frederick Murunga Wekesah, Vivian Mushi, Anthony Ngugi, Peter Odermatt, Rachael Odhiambo, James O Mageto, Peter Otieno, Seth Owusu-Agyei, George Pariyo, Stefan Peterson, Josemir Sander, Arjune Sen, Cynthia Sottie, Isolide Sylvester, Stephen Tollman, Yvonne Thoya, Rhian Twine, Sonia Vallentin, Ryan Wagner, Richard Walker, and Stella Waruingi

Subjects
Computer applications to medicine. Medical informatics, R858-859.7
Abstract

Summary: Background: Identification of convulsive epilepsy in sub-Saharan Africa relies on access to resources that are often unavailable. Infrastructure and resource requirements can further complicate case verification. Using machine-learning techniques, we have developed and tested a region-specific questionnaire panel and predictive model to identify people who have had a convulsive seizure. These findings have been implemented into a free app for health-care workers in Kenya, Uganda, Ghana, Tanzania, and South Africa. Methods: In this retrospective case-control study, we used data from the Studies of the Epidemiology of Epilepsy in Demographic Sites in Kenya, Uganda, Ghana, Tanzania, and South Africa. We randomly split these individuals using a 7:3 ratio into a training dataset and a validation dataset. We used information gain and correlation-based feature selection to identify eight binary features to predict convulsive seizures. We then assessed several machine-learning algorithms to create a multivariate prediction model. We validated the best-performing model with the internal dataset and a prospectively collected external-validation dataset. We additionally evaluated a leave-one-site-out model (LOSO), in which the model was trained on data from all sites except one that, in turn, formed the validation dataset. We used these features to develop a questionnaire-based predictive panel that we implemented into a multilingual app (the Epilepsy Diagnostic Companion) for health-care workers in each geographical region. Findings: We analysed epilepsy-specific data from 4097 people, of whom 1985 (48·5%) had convulsive epilepsy, and 2112 were controls. From 170 clinical variables, we initially identified 20 candidate predictor features. Eight features were removed, six because of negligible information gain and two following review by a panel of qualified neurologists. Correlation-based feature selection identified eight variables that demonstrated predictive value; all were associated with an increased risk of an epileptic convulsion except one. The logistic regression, support vector, and naive Bayes models performed similarly, outperforming the decision-tree model. We chose the logistic regression model for its interpretability and implementability. The area under the receiver operator curve (AUC) was 0·92 (95% CI 0·91–0·94, sensitivity 85·0%, specificity 93·7%) in the internal-validation dataset and 0·95 (0·92–0·98, sensitivity 97·5%, specificity 82·4%) in the external-validation dataset. Similar results were observed for the LOSO model (AUC 0·94, 0·93–0·96, sensitivity 88·2%, specificity 95·3%). Interpretation: On the basis of these findings, we developed the Epilepsy Diagnostic Companion as a predictive model and app offering a validated culture-specific and region-specific solution to confirm the diagnosis of a convulsive epileptic seizure in people with suspected epilepsy. The questionnaire panel is simple and accessible for health-care workers without specialist knowledge to administer. This tool can be iteratively updated and could lead to earlier, more accurate diagnosis of seizures and improve care for people with epilepsy. Funding: The Wellcome Trust, the UK National Institute of Health Research, and the Oxford NIHR Biomedical Research Centre.

Published
2023
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16. Evoked resonant neural activity in subthalamic local field potentials reflects basal ganglia network dynamics

Author

Christoph Wiest, Shenghong He, Benoit Duchet, Alek Pogosyan, Moaad Benjaber, Timothy Denison, Harutomo Hasegawa, Keyoumars Ashkan, Fahd Baig, Ilaria Bertaina, Francesca Morgante, Erlick A. Pereira, Flavie Torrecillos, and Huiling Tan

Subjects
Parkinson's disease, Deep brain stimulation, Evoked resonant neural activity, Adaptive DBS, Local field potentials, Subthalamic nucleus, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Evoked resonant neural activity (ERNA) is induced by subthalamic deep brain stimulation (DBS) and was recently suggested as a marker of lead placement and contact selection in Parkinson's disease. Yet, its underlying mechanisms and how it is modulated by stimulation parameters are unclear. Here, we recorded local field potentials from 27 Parkinson's disease patients, while leads were externalised to scrutinise the ERNA. First, we show that ERNA in the time series waveform and spectrogram likely represent the same activity, which was contested before. Second, our results show that the ERNA has fast and slow dynamics during stimulation, consistent with the synaptic failure hypothesis. Third, we show that ERNA parameters are modulated by different DBS frequencies, intensities, medication states and stimulation modes (continuous DBS vs. adaptive DBS). These results suggest the ERNA might prove useful as a predictor of the best DBS frequency and lowest effective intensity in addition to contact selection. Changes with levodopa and DBS mode suggest that the ERNA may indicate the state of the cortico-basal ganglia circuit making it a putative biomarker to track clinical state in adaptive DBS.

Published
2023
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19. The sensitivity of ECG contamination to surgical implantation site in brain computer interfaces

Author

Wolf-Julian Neumann, Majid Memarian Sorkhabi, Moaad Benjaber, Lucia K. Feldmann, Assel Saryyeva, Joachim K. Krauss, Maria Fiorella Contarino, Tomas Sieger, Robert Jech, Gerd Tinkhauser, Claudio Pollo, Chiara Palmisano, Ioannis U. Isaias, Daniel D. Cummins, Simon J. Little, Philip A. Starr, Vasileios Kokkinos, Schneider Gerd-Helge, Todd Herrington, Peter Brown, R. Mark Richardson, Andrea A. Kühn, and Timothy Denison

Subjects
Deep brain stimulation, Brain computer interface, Oscillations, Artifacts, Neuromodulation, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Background: Brain sensing devices are approved today for Parkinson's, essential tremor, and epilepsy therapies. Clinical decisions for implants are often influenced by the premise that patients will benefit from using sensing technology. However, artifacts, such as ECG contamination, can render such treatments unreliable. Therefore, clinicians need to understand how surgical decisions may affect artifact probability. Objectives: Investigate neural signal contamination with ECG activity in sensing enabled neurostimulation systems, and in particular clinical choices such as implant location that impact signal fidelity. Methods: Electric field modeling and empirical signals from 85 patients were used to investigate the relationship between implant location and ECG contamination. Results: The impact on neural recordings depends on the difference between ECG signal and noise floor of the electrophysiological recording. Empirically, we demonstrate that severe ECG contamination was more than 3.2x higher in left-sided subclavicular implants (48.3%), when compared to right-sided implants (15.3%). Cranial implants did not show ECG contamination. Conclusions: Given the relative frequency of corrupted neural signals, we conclude that implant location will impact the ability of brain sensing devices to be used for “closed-loop” algorithms. Clinical adjustments such as implant location can significantly affect signal integrity and need consideration.

Published
2021
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21. Neurostimulation as a Method of Treatment and a Preventive Measure in Canine Drug-Resistant Epilepsy: Current State and Future Prospects

Author

Marta Nowakowska, Muammer Üçal, Marios Charalambous, Sofie F. M. Bhatti, Timothy Denison, Sebastian Meller, Gregory A. Worrell, Heidrun Potschka, and Holger A. Volk

Subjects
drug-resistant epilepsy, dogs, vagus nerve stimulation, deep brain stimulation, transcranial magnetic stimulation, seizure, Veterinary medicine, SF600-1100
Abstract

Modulation of neuronal activity for seizure control using various methods of neurostimulation is a rapidly developing field in epileptology, especially in treatment of refractory epilepsy. Promising results in human clinical practice, such as diminished seizure burden, reduced incidence of sudden unexplained death in epilepsy, and improved quality of life has brought neurostimulation into the focus of veterinary medicine as a therapeutic option. This article provides a comprehensive review of available neurostimulation methods for seizure management in drug-resistant epilepsy in canine patients. Recent progress in non-invasive modalities, such as repetitive transcranial magnetic stimulation and transcutaneous vagus nerve stimulation is highlighted. We further discuss potential future advances and their plausible application as means for preventing epileptogenesis in dogs.

Published
2022
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22. Numerical Modeling of Plasticity Induced by Quadri-Pulse Stimulation

Author

Majid Memarian Sorkhabi, Karen Wendt, Marcus T. Wilson, and Timothy Denison

Subjects
Transcranial magnetic stimulation, TMS-induced plasticity, QPS, near-rectangular magnetic stimuli, cTMS device, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Quadri-pulse stimulation (QPS), a type of repetitive transcranial magnetic stimulation (rTMS), can induce a considerable aftereffect on cortical synapses. Human experiments have shown that the type of effect on synaptic efficiency (in terms of potentiation or depression) depends on the time interval between pulses. The maturation of biophysically-based models, which describe the physiological properties of plasticity mathematically, offers a beneficial framework to explore induced plasticity for new stimulation protocols. To model the QPS paradigm, a phenomenological model based on the knowledge of spike timing-dependent plasticity (STDP) mechanisms of synaptic plasticity was utilized where the cortex builds upon the platform of neuronal population modeling. Induced cortical plasticity was modeled for both conventional monophasic pulses and unidirectional pulses generated by the cTMS device, in a total of 117 different scenarios. For the conventional monophasic stimuli, the results of the predictive model broadly follow what is typically seen in human experiments. Unidirectional pulses can produce a similar range of plasticity. Additionally, changing the pulse width had a considerable effect on the plasticity (approximately 20% increase). As the width of the positive phase increases, the size of the potentiation will also increase. The proposed model can generate predictions to guide future plasticity experiments. Estimating the plasticity and optimizing the rTMS protocols might effectively improve the safety implications of TMS experiments by reducing the number of delivered pulses to participants. Finding the optimal stimulation protocol with the maximum potentiation/depression can lead to the design of a new TMS pulse generator device with targeted hardware and control algorithms.

Published
2021
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23. Case Report: Embedding 'Digital Chronotherapy' Into Medical Devices—A Canine Validation for Controlling Status Epilepticus Through Multi-Scale Rhythmic Brain Stimulation

Author

Mayela Zamora, Sebastian Meller, Filip Kajin, James J. Sermon, Robert Toth, Moaad Benjaber, Derk-Jan Dijk, Rafal Bogacz, Gregory A. Worrell, Antonio Valentin, Benoit Duchet, Holger A. Volk, and Timothy Denison

Subjects
deep brain stimulation, centromedian thalamus, circadian, entrainment, epilepsy, chronotherapy, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Circadian and other physiological rhythms play a key role in both normal homeostasis and disease processes. Such is the case of circadian and infradian seizure patterns observed in epilepsy. However, these rhythms are not fully exploited in the design of active implantable medical devices. In this paper we explore a new implantable stimulator that implements chronotherapy as a feedforward input to supplement both open-loop and closed-loop methods. This integrated algorithm allows for stimulation to be adjusted to the ultradian, circadian and infradian patterns observed in patients through slowly-varying temporal adjustments of stimulation and algorithm sub-components, while also enabling adaption of stimulation based on immediate physiological needs such as a breakthrough seizure or change of posture. Embedded physiological sensors in the stimulator can be used to refine the baseline stimulation circadian pattern as a “digital zeitgeber,” i.e., a source of stimulus that entrains or synchronizes the subject's natural rhythms. This algorithmic approach is tested on a canine with severe drug-resistant idiopathic generalized epilepsy exhibiting a characteristic diurnal pattern correlated with sleep-wake cycles. Prior to implantation, the canine's cluster seizures evolved to status epilepticus (SE) and required emergency pharmacological intervention. The cranially-mounted system was fully-implanted bilaterally into the centromedian nucleus of the thalamus. Using combinations of time-based modulation, thalamocortical rhythm-specific tuning of frequency parameters as well as fast-adaptive modes based on activity, the canine experienced no further SE events post-implant as of the time of writing (7 months). Importantly, no significant cluster seizures have been observed either, allowing the reduction of rescue medication. The use of digitally-enabled chronotherapy as a feedforward signal to augment adaptive neurostimulators could prove a useful algorithmic method in conditions where sensitivity to temporal patterns are characteristics of the disease state, providing a novel mechanism for tailoring a more patient-specific therapy approach.

Published
2021
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24. A high-performance 8 nV/√Hz 8-channel wearable and wireless system for real-time monitoring of bioelectrical signals

Author

Konstantinos Petkos, Simos Koutsoftidis, Thomas Guiho, Patrick Degenaar, Andrew Jackson, Stephen E. Greenwald, Peter Brown, Timothy Denison, and Emmanuel M. Drakakis

Subjects
Neurological disorders, Bioelectrical signals, Analog front-end, High-performance, Wearable, Wireless, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Abstract Background It is widely accepted by the scientific community that bioelectrical signals, which can be used for the identification of neurophysiological biomarkers indicative of a diseased or pathological state, could direct patient treatment towards more effective therapeutic strategies. However, the design and realisation of an instrument that can precisely record weak bioelectrical signals in the presence of strong interference stemming from a noisy clinical environment is one of the most difficult challenges associated with the strategy of monitoring bioelectrical signals for diagnostic purposes. Moreover, since patients often have to cope with the problem of limited mobility being connected to bulky and mains-powered instruments, there is a growing demand for small-sized, high-performance and ambulatory biopotential acquisition systems in the Intensive Care Unit (ICU) and in High-dependency wards. Finally, to the best of our knowledge, there are no commercial, small, battery-powered, wearable and wireless recording-only instruments that claim the capability of recording electrocorticographic (ECoG) signals. Methods To address this problem, we designed and developed a low-noise (8 nV/√Hz), eight-channel, battery-powered, wearable and wireless instrument (55 × 80 mm2). The performance of the realised instrument was assessed by conducting both ex vivo and in vivo experiments. Results To provide ex vivo proof-of-function, a wide variety of high-quality bioelectrical signal recordings are reported, including electroencephalographic (EEG), electromyographic (EMG), electrocardiographic (ECG), acceleration signals, and muscle fasciculations. Low-noise in vivo recordings of weak local field potentials (LFPs), which were wirelessly acquired in real time using segmented deep brain stimulation (DBS) electrodes implanted in the thalamus of a non-human primate, are also presented. Conclusions The combination of desirable features and capabilities of this instrument, namely its small size (~one business card), its enhanced recording capabilities, its increased processing capabilities, its manufacturability (since it was designed using discrete off-the-shelf components), the wide bandwidth it offers (0.5–500 Hz) and the plurality of bioelectrical signals it can precisely record, render it a versatile and reliable tool to be utilized in a wide range of applications and environments.

Published
2019
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25. Epilepsy Personal Assistant Device—A Mobile Platform for Brain State, Dense Behavioral and Physiology Tracking and Controlling Adaptive Stimulation

Author

Tal Pal Attia, Daniel Crepeau, Vaclav Kremen, Mona Nasseri, Hari Guragain, Steven W. Steele, Vladimir Sladky, Petr Nejedly, Filip Mivalt, Jeffrey A. Herron, Matt Stead, Timothy Denison, Gregory A. Worrell, and Benjamin H. Brinkmann

Subjects
epilepsy, deep brain stimulation, implantable devices, neuromodulation, seizure detection, seizure prediction, Neurology. Diseases of the nervous system, RC346-429
Abstract

Epilepsy is one of the most common neurological disorders, and it affects almost 1% of the population worldwide. Many people living with epilepsy continue to have seizures despite anti-epileptic medication therapy, surgical treatments, and neuromodulation therapy. The unpredictability of seizures is one of the most disabling aspects of epilepsy. Furthermore, epilepsy is associated with sleep, cognitive, and psychiatric comorbidities, which significantly impact the quality of life. Seizure predictions could potentially be used to adjust neuromodulation therapy to prevent the onset of a seizure and empower patients to avoid sensitive activities during high-risk periods. Long-term objective data is needed to provide a clearer view of brain electrical activity and an objective measure of the efficacy of therapeutic measures for optimal epilepsy care. While neuromodulation devices offer the potential for acquiring long-term data, available devices provide very little information regarding brain activity and therapy effectiveness. Also, seizure diaries kept by patients or caregivers are subjective and have been shown to be unreliable, in particular for patients with memory-impairing seizures. This paper describes the design, architecture, and development of the Mayo Epilepsy Personal Assistant Device (EPAD). The EPAD has bi-directional connectivity to the implanted investigational Medtronic Summit RC+STM device to implement intracranial EEG and physiological monitoring, processing, and control of the overall system and wearable devices streaming physiological time-series signals. In order to mitigate risk and comply with regulatory requirements, we developed a Quality Management System (QMS) to define the development process of the EPAD system, including Risk Analysis, Verification, Validation, and protocol mitigations. Extensive verification and validation testing were performed on thirteen canines and benchtop systems. The system is now under a first-in-human trial as part of the US FDA Investigational Device Exemption given in 2018 to study modulated responsive and predictive stimulation using the Mayo EPAD system and investigational Medtronic Summit RC+STM in ten patients with non-resectable dominant or bilateral mesial temporal lobe epilepsy. The EPAD system coupled with an implanted device capable of EEG telemetry represents a next-generation solution to optimizing neuromodulation therapy.

Published
2021
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27. Proceedings of the second biennial Cleveland Neural Engineering Workshop 2013

Author

Kim Anderson, Abidemi Ajiboye, Timothy Denison, Jennifer French, Kenneth Gustafson, Kevin Kilgore, Naomi Kleitman, Audrey Kusiak, Brian Litt, Megan Moynahan, Eric Perreault, Douglas Weber, Justin Williams, and Dustin Tyler

Subjects
Neural, Engineering, Strategy, Infrastructure, Advocacy, Rehabilitation, Medical technology, R855-855.5
Abstract

Abstract The Cleveland Neural Engineering Workshop (NEW) is a biennial meeting started in 2011 as an “unconference” to bring together leaders in the neural engineering and related fields. Since the first iteration of the meeting, NEW has evolved from “just getting together” to a more important purpose of creating, reviewing, and promoting a uniform strategic roadmap for the field. The purpose of this short report, as well as the companion 2015 and 2017 reports, is to provide a historical record of this meeting and the evolution of the roadmap. These reports more importantly establish a baseline for the next meeting to be held in June, 2019. The second Neural Engineering Workshop (NEW) was held in June 2013. The two-day workshop was hosted by the Cleveland Advanced Platform for Technology National Veterans Affairs Center, the Functional Electrical Stimulation National Veterans Affairs Center, and the Case Western Reserve University in Cleveland, Ohio. Participants identified seven areas of future focus in the field of neural engineering: active communications with users, advocacy (regulatory), network building (clinical practice), case studies (clinical and technical), early industrial feedback, value chain resources, engagement, and advocacy (funding). This proceedings document summarizes the meeting outcome.

Published
2018
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28. Integrating Brain Implants With Local and Distributed Computing Devices: A Next Generation Epilepsy Management System

Author

Vaclav Kremen, Benjamin H. Brinkmann, Inyong Kim, Hari Guragain, Mona Nasseri, Abigail L. Magee, Tal Pal Attia, Petr Nejedly, Vladimir Sladky, Nathanial Nelson, Su-Youne Chang, Jeffrey A. Herron, Tom Adamski, Steven Baldassano, Jan Cimbalnik, Vince Vasoli, Elizabeth Fehrmann, Tom Chouinard, Edward E. Patterson, Brian Litt, Matt Stead, Jamie Van Gompel, Beverly K. Sturges, Hang Joon Jo, Chelsea M. Crowe, Timothy Denison, and Gregory A. Worrell

Subjects
Epilepsy, deep brain stimulation, implantable devices, seizure detection, seizure prediction, distributed computing, Computer applications to medicine. Medical informatics, R858-859.7, Medical technology, R855-855.5
Abstract

Brain stimulation has emerged as an effective treatment for a wide range of neurological and psychiatric diseases. Parkinson's disease, epilepsy, and essential tremor have FDA indications for electrical brain stimulation using intracranially implanted electrodes. Interfacing implantable brain devices with local and cloud computing resources have the potential to improve electrical stimulation efficacy, disease tracking, and management. Epilepsy, in particular, is a neurological disease that might benefit from the integration of brain implants with off-the-body computing for tracking disease and therapy. Recent clinical trials have demonstrated seizure forecasting, seizure detection, and therapeutic electrical stimulation in patients with drug-resistant focal epilepsy. In this paper, we describe a next-generation epilepsy management system that integrates local handheld and cloud-computing resources wirelessly coupled to an implanted device with embedded payloads (sensors, intracranial EEG telemetry, electrical stimulation, classifiers, and control policy implementation). The handheld device and cloud computing resources can provide a seamless interface between patients and physicians, and realtime intracranial EEG can be used to classify brain state (wake/sleep, preseizure, and seizure), implement control policies for electrical stimulation, and track patient health. This system creates a flexible platform in which low demand analytics requiring fast response times are embedded in the implanted device and more complex algorithms are implemented in offthebody local and distributed cloud computing environments. The system enables tracking and management of epileptic neural networks operating over time scales ranging from milliseconds to months.

Published
2018
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29. Sensorimotor ECoG Signal Features for BCI Control: A Comparison Between People With Locked-In Syndrome and Able-Bodied Controls

Author

Zachary V. Freudenburg, Mariana P. Branco, Sacha Leinders, Benny H. van der Vijgh, Elmar G. M. Pels, Timothy Denison, Leonard H. van den Berg, Kai J. Miller, Erik J. Aarnoutse, Nick F. Ramsey, and Mariska J. Vansteensel

Subjects
brain-computer interface, implant, sensorimotor cortex, amyotrophic lateral sclerosis, brain stem stroke, electrocorticography, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

The sensorimotor cortex is a frequently targeted brain area for the development of Brain-Computer Interfaces (BCIs) for communication in people with severe paralysis and communication problems (locked-in syndrome; LIS). It is widely acknowledged that this area displays an increase in high-frequency band (HFB) power and a decrease in the power of the low frequency band (LFB) during movement of, for example, the hand. Upon termination of hand movement, activity in the LFB band typically shows a short increase (rebound). The ability to modulate the neural signal in the sensorimotor cortex by imagining or attempting to move is crucial for the implementation of sensorimotor BCI in people who are unable to execute movements. This may not always be self-evident, since the most common causes of LIS, amyotrophic lateral sclerosis (ALS) and brain stem stroke, are associated with significant damage to the brain, potentially affecting the generation of baseline neural activity in the sensorimotor cortex and the modulation thereof by imagined or attempted hand movement. In the Utrecht NeuroProsthesis (UNP) study, a participant with LIS caused by ALS and a participant with LIS due to brain stem stroke were implanted with a fully implantable BCI, including subdural electrocorticography (ECoG) electrodes over the sensorimotor area, with the purpose of achieving ECoG-BCI-based communication. We noted differences between these participants in the spectral power changes generated by attempted movement of the hand. To better understand the nature and origin of these differences, we compared the baseline spectral features and task-induced modulation of the neural signal of the LIS participants, with those of a group of able-bodied people with epilepsy who received a subchronic implant with ECoG electrodes for diagnostic purposes. Our data show that baseline LFB oscillatory components and changes generated in the LFB power of the sensorimotor cortex by (attempted) hand movement differ between participants, despite consistent HFB responses in this area. We conclude that the etiology of LIS may have significant effects on the LFB spectral components in the sensorimotor cortex, which is relevant for the development of communication-BCIs for this population.

Published
2019
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30. Proceedings of the Fourth Annual Deep Brain Stimulation Think Tank - A Review of Emerging Issues and Technologies

Author

Wissam Deeb, James J Giordano, Peter Justin Rossi, Alon Mogilner, Aysegul Gunduz, Jack William Judy, Bryan T. Klassen, Christopher R. Butson, Craig van Horne, Damiaan Denys, Darin D Dougherty, David Rowell, Greg A Gerhardt, Gwenn S. Smith, Harrison C. Walker, Helen M Bronte-Stewart, Helen S. Mayberg, Howard J. Chizeck, Jean-Philippe Langevin, Jens Volkmann, Jill Ostrem, Jonathan B Shute, Joohi Jimenez-Shahed, Kelly Douglas Foote, Marvin A Rossi, Michael Oh, Michael Pourfar, Paul B. Rosenburg, Peter Allen Silburn, Coralie De Hemptinne, Philip A. Starr, Timothy Denison, Umer Akbar, Warren M Grill, and Michael S. Okun

Subjects
Alzheimer Disease, Depression, Parkinson Disease, Tourette Syndrome, Neuromodulation, deep brain stimulation (DBS), Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571, Neurology. Diseases of the nervous system, RC346-429
Abstract

This paper provides an overview of current progress in the technological advances and the use of deep brain stimulation (DBS) to treat neurological and neuropsychiatric disorders, as presented by participants of the Fourth Annual Deep Brain Stimulation Think Tank, which was convened in March 2016 in conjunction with the Center for Movement Disorders and Neurorestoration at the University of Florida, Gainesveille FL, USA. The Think Tank discussions first focused on policy and advocacy in DBS research and clinical practice, formation of registries, and issues involving the use of DBS in the treatment of Tourette Syndrome. Next, advances in the use of neuroimaging and electrochemical markers to enhance DBS specificity were addressed. Updates on ongoing use and developments of DBS for the treatment of Parkinson’s disease, essential tremor, Alzheimer’s disease, depression, post-traumatic stress disorder, obesity, addiction were presented, and progress toward innovation(s) in closed-loop applications were discussed. Each section of these proceedings provides updates and highlights of new information as presented at this year’s international Think Tank, with a view toward current and near future advancement of the field.

Published
2016
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31. Towards network-guided neuromodulation for epilepsy

Author

Rory J Piper, R Mark Richardson, Gregory Worrell, David W Carmichael, Torsten Baldeweg, Brian Litt, Timothy Denison, and Martin M Tisdall

Subjects
Adult, Epilepsy, Thalamus, Subthalamic Nucleus, Deep Brain Stimulation, Humans, Anticonvulsants, Epilepsies, Partial, Neurology (clinical), Child
Abstract

Epilepsy is well-recognized as a disorder of brain networks. There is a growing body of research to identify critical nodes within dynamic epileptic networks with the aim to target therapies that halt the onset and propagation of seizures. In parallel, intracranial neuromodulation, including deep brain stimulation and responsive neurostimulation, are well-established and expanding as therapies to reduce seizures in adults with focal-onset epilepsy; and there is emerging evidence for their efficacy in children and generalized-onset seizure disorders. The convergence of these advancing fields is driving an era of ‘network-guided neuromodulation’ for epilepsy. In this review, we distil the current literature on network mechanisms underlying neurostimulation for epilepsy. We discuss the modulation of key ‘propagation points’ in the epileptogenic network, focusing primarily on thalamic nuclei targeted in current clinical practice. These include (i) the anterior nucleus of thalamus, now a clinically approved and targeted site for open loop stimulation, and increasingly targeted for responsive neurostimulation; and (ii) the centromedian nucleus of the thalamus, a target for both deep brain stimulation and responsive neurostimulation in generalized-onset epilepsies. We discuss briefly the networks associated with other emerging neuromodulation targets, such as the pulvinar of the thalamus, piriform cortex, septal area, subthalamic nucleus, cerebellum and others. We report synergistic findings garnered from multiple modalities of investigation that have revealed structural and functional networks associated with these propagation points — including scalp and invasive EEG, and diffusion and functional MRI. We also report on intracranial recordings from implanted devices which provide us data on the dynamic networks we are aiming to modulate. Finally, we review the continuing evolution of network-guided neuromodulation for epilepsy to accelerate progress towards two translational goals: (i) to use pre-surgical network analyses to determine patient candidacy for neurostimulation for epilepsy by providing network biomarkers that predict efficacy; and (ii) to deliver precise, personalized and effective antiepileptic stimulation to prevent and arrest seizure propagation through mapping and modulation of each patients’ individual epileptogenic networks.

Published
2022
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32. The Design of Brainstem Interfaces: Characterisation of Physiological Artefacts and Implications for Closed-loop Algorithms

Author

Alceste Deli, Robert Toth, Mayela Zamora, Amir P. Divanbeighi Zand, Alexander L. Green, and Timothy Denison

Abstract

Surgical neuromodulation through implantable devices allows for stimulation delivery to subcortical regions, crucial for symptom control in many debilitating neurological conditions. Novel closed-loop algorithms deliver therapy tailor-made to endogenous physiological activity, however rely on precise sensing of signals such as subcortical oscillations. The frequency of such intrinsic activity can vary depending on subcortical target nucleus, while factors such as regional anatomy may also contribute to variability in sensing signals. While artefact parameters have been explored in more ‘standard’ and commonly used targets (such as the basal ganglia, which are implanted in movement disorders), characterisation in novel candidate nuclei is still under investigation. One such important area is the brainstem, which contains nuclei crucial for arousal and autonomic regulation. The brainstem provides additional implantation targets for treatment indications in disorders of consciousness and sleep, yet poses distinct anatomical challenges compared to central subcortical targets. Here we investigate the region-specific artefacts encountered during activity and rest while streaming data from brainstem implants with a cranially-mounted device in two patients. Such artefacts result from this complex anatomical environment and its interactions with physiological parameters such as head movement and cardiac functions. The implications of the micromotion-induced artefacts, and potential mitigation, are then considered for future closed-loop stimulation methods.

Published
2023
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33. Computationally efficient neural network classifiers for next generation closed loop neuromodulation therapy - a case study in epilepsy

Author

Ali Kavoosi, Robert Toth, Moaad Benjaber, Mayela Zamora, Antonio Valentin, Andrew Sharott, and Timothy Denison

Subjects
Signal Processing (eess.SP), Drug Resistant Epilepsy, ComputingMethodologies_PATTERNRECOGNITION, Epilepsy, Seizures, FOS: Biological sciences, FOS: Electrical engineering, electronic engineering, information engineering, Humans, Neural Networks, Computer, Electrical Engineering and Systems Science - Signal Processing, Quantitative Biology - Quantitative Methods, Quantitative Methods (q-bio.QM)
Abstract

This work explores the potential utility of neural network classifiers for real-time classification of field-potential based biomarkers in next-generation responsive neuromodulation systems. Compared to classical filter-based classifiers, neural networks offer an ease of patient-specific parameter tuning, promising to reduce the burden of programming on clinicians. The paper explores a compact, feed-forward neural network architecture of only dozens of units for seizure-state classification in refractory epilepsy. The proposed classifier offers comparable accuracy to filter classifiers on clinician-labelled data, while reducing detection latency. As a trade-off to classical methods, the paper focuses on keeping the complexity of the architecture minimal, to accommodate the on-board computational constraints of implantable pulse generator systems., 4 pages, 5 figures

Published
2022

34. How to entrain a selected neuronal rhythm but not others: open-loop dithered brain stimulation for selective entrainment

Author

Benoit Duchet, James J Sermon, Gihan Weerasinghe, Timothy Denison, and Rafal Bogacz

Subjects
Cellular and Molecular Neuroscience, Biomedical Engineering
Abstract

Objective. While brain stimulation therapies such as deep brain stimulation for Parkinson’s disease (PD) can be effective, they have yet to reach their full potential across neurological disorders. Entraining neuronal rhythms using rhythmic brain stimulation has been suggested as a new therapeutic mechanism to restore neurotypical behaviour in conditions such as chronic pain, depression, and Alzheimer’s disease. However, theoretical and experimental evidence indicate that brain stimulation can also entrain neuronal rhythms at sub- and super-harmonics, far from the stimulation frequency. Crucially, these counterintuitive effects could be harmful to patients, for example by triggering debilitating involuntary movements in PD. We therefore seek a principled approach to selectively promote rhythms close to the stimulation frequency, while avoiding potential harmful effects by preventing entrainment at sub- and super-harmonics. Approach. Our open-loop approach to selective entrainment, dithered stimulation, consists in adding white noise to the stimulation period. Main results. We theoretically establish the ability of dithered stimulation to selectively entrain a given brain rhythm, and verify its efficacy in simulations of uncoupled neural oscillators, and networks of coupled neural oscillators. Furthermore, we show that dithered stimulation can be implemented in neurostimulators with limited capabilities by toggling within a finite set of stimulation frequencies. Significance. Likely implementable across a variety of existing brain stimulation devices, dithering-based selective entrainment has potential to enable new brain stimulation therapies, as well as new neuroscientific research exploiting its ability to modulate higher-order entrainment.

Published
2022
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35. Distributed brain co-processor for tracking spikes, seizures and behaviour during electrical brain stimulation

Author

Vladimir Sladky, Petr Nejedly, Filip Mivalt, Benjamin H Brinkmann, Inyong Kim, Erik K St. Louis, Nicholas M Gregg, Brian N Lundstrom, Chelsea M Crowe, Tal Pal Attia, Daniel Crepeau, Irena Balzekas, Victoria S Marks, Lydia P Wheeler, Jan Cimbalnik, Mark Cook, Radek Janca, Beverly K Sturges, Kent Leyde, Kai J Miller, Jamie J Van Gompel, Timothy Denison, Gregory A Worrell, and Vaclav Kremen

Subjects
Assistive Technology, machine learning, Epilepsy, Clinical Research, Neurological, Neurosciences, General Engineering, Bioengineering, Original Article, Neurodegenerative, electrophysiology, seizures, Brain Disorders
Abstract

Early implantable epilepsy therapy devices provided open-loop electrical stimulation without brain sensing, computing, or an interface for synchronized behavioural inputs from patients. Recent epilepsy stimulation devices provide brain sensing but have not yet developed analytics for accurately tracking and quantifying behaviour and seizures. Here we describe a distributed brain co-processor providing an intuitive bi-directional interface between patient, implanted neural stimulation and sensing device, and local and distributed computing resources. Automated analysis of continuous streaming electrophysiology is synchronized with patient reports using a handheld device and integrated with distributed cloud computing resources for quantifying seizures, interictal epileptiform spikes and patient symptoms during therapeutic electrical brain stimulation. The classification algorithms for interictal epileptiform spikes and seizures were developed and parameterized using long-term ambulatory data from nine humans and eight canines with epilepsy, and then implemented prospectively in out-of-sample testing in two pet canines and four humans with drug-resistant epilepsy living in their natural environments. Accurate seizure diaries are needed as the primary clinical outcome measure of epilepsy therapy and to guide brain-stimulation optimization. The brain co-processor system described here enables tracking interictal epileptiform spikes, seizures and correlation with patient behavioural reports. In the future, correlation of spikes and seizures with behaviour will allow more detailed investigation of the clinical impact of spikes and seizures on patients.

Published
2022
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36. A Neurostimulator System for Real, Sham, and Multi-Target Transcranial Magnetic Stimulation

Author

Majid Memarian Sorkhabi and Timothy Denison

Subjects
Cellular and Molecular Neuroscience, Magnetics, Heart Rate, Movement, Biomedical Engineering, Electronics, Transcranial Magnetic Stimulation, Article
Abstract

Objective. Transcranial magnetic stimulation (TMS) is a clinically effective therapeutic instrument used to modulate neural activity. Despite three decades of research, two challenging issues remain, the possibility of changing the (a) stimulated spot and (b) stimulation type (real or sham) without physically moving the coil. In this study, a second-generation programmable TMS device with advanced stimulus shaping is introduced that uses a five-level cascaded H-bridge inverter and phase-shifted pulse-width modulation. The principal idea of this research is to obtain real, sham, and multi-locus stimulation using the same TMS system. Approach. We propose a two-channel modulation-based magnetic pulse generator and a novel coil arrangement, consisting of two circular coils with a physical distance of 20 mm between the coils and a control method for modifying the effective stimulus intensity, which leads to the live steerability of the target and type of stimulation. Main results. Based on the measured system performance, the stimulation profile can be steered ±20 mm along a line from the centroid of the coil locations by modifying the modulation index. Significance. The proposed system supports electronic control of the stimulation spot without physical coil movement, resulting in tunable modulation of targets, which is a crucial step towards automated TMS machines.

Published
2022

37. Sub-harmonic Entrainment of Cortical Gamma Oscillations to Deep Brain Stimulation in Parkinson’s Disease: Model Based Predictions and Validation in Three Human Subjects

Author

James J. Sermon, Maria Olaru, Juan Anso, Stephanie Cernera, Simon Little, Maria Shcherbakova, Rafal Bogacz, Philip A. Starr, Timothy Denison, and Benoit Duchet

Abstract

ObjectivesThe exact mechanisms of deep brain stimulation (DBS) are still an active area of investigation, in spite of its clinical successes. This is due in part to the lack of understanding of the effects of stimulation on neuronal rhythms. Entrainment of brain oscillations has been hypothesised as a potential mechanism of neuromodulation. A better understanding of entrainment might further inform existing methods of continuous DBS, and help refine algorithms for adaptive methods. The purpose of this study is to develop and test a theoretical framework to predict entrainment of cortical rhythms to DBS across a wide range of stimulation parameters.Materials and MethodsWe fit a model of interacting neural populations to selected features characterising PD patients’ off-stimulation finely-tuned gamma rhythm recorded through electrocorticography. Using the fitted models, we predict basal ganglia DBS parameters that would result in 1:2 entrainment, a special case of sub-harmonic entrainment observed in patients and predicted by theory.ResultsWe show that the neural circuit models fitted to patient data exhibit 1:2 entrainment when stimulation is provided across a range of stimulation parameters. Furthermore, we verify key features of the region of 1:2 entrainment in the stimulation frequency/amplitude space with follow-up recordings from the same patients, such as the loss of 1:2 entrainment above certain stimulation amplitudes.ConclusionOur results reveal that continuous, constant frequency DBS in patients may lead to nonlinear patterns of neuronal entrainment across stimulation parameters, and that these responses can be predicted by modelling. Should entrainment prove to be an important mechanism of therapeutic stimulation, our modelling framework may reduce the parameter space that clinicians must consider when programming devices for optimal benefit.

Published
2022
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38. Comparison between the modelled response of primary motor cortex neurons to pulse-width modulated and conventional TMS stimuli

Author

Karen Wendt, Majid Memarian Sorkhabi, Jacinta O'Shea, Hayriye Cagnan, and Timothy Denison

Subjects
Neurons, Heart Rate, Motor Cortex, Evoked Potentials, Motor, Transcranial Magnetic Stimulation
Abstract

In this study, the neural response to pulse-width modulated (PWM) transcranial magnetic stimulation (TMS) is estimated using a computational neural model which simulates the response of cortical neurons to TMS. The recently introduced programmable TMS uses PWM to approximate conventional resonance-based TMS pulses by fast switching between voltage levels. The effect of such stimulation on the six cortical layers is modelled by estimating the activation threshold of the neurons. Modelling results are compared between the novel device and that of conventional TMS stimuli generated by Magstim stimulators. The neural responses to the PWM pulses and the conventional stimuli show a high correlation, which validates the use of pulse-width modulated pulses in TMS.Clinical Relevance- This computational modelling study demonstrates an equivalent effect of PWM and conventional TMS pulses on the nervous system which paves the way to more flexibility in exploring and choosing stimulation parameters for TMS treatment.

Published
2021

40. Concurrent stimulation and sensing in bi-directional brain interfaces: a multi-site translational experience

Author

Juan Ansó, Moaad Benjaber, Brandon Parks, Samuel Parker, Carina Renate Oehrn, Matthew Petrucci, Ro’ee Gilron, Simon Little, Robert Wilt, Helen Bronte-Stewart, Aysegul Gunduz, David Borton, Philip A Starr, and Timothy Denison

Subjects
Cellular and Molecular Neuroscience, Deep Brain Stimulation, Biomedical Engineering, Brain, Humans, Algorithms, Feedback
Abstract

Objective. To provide a design analysis and guidance framework for the implementation of concurrent stimulation and sensing during adaptive deep brain stimulation (aDBS) with particular emphasis on artifact mitigations. Approach. We defined a general architecture of feedback-enabled devices, identified key components in the signal chain which might result in unwanted artifacts and proposed methods that might ultimately enable improved aDBS therapies. We gathered data from research subjects chronically-implanted with an investigational aDBS system, Summit RC + S, to characterize and explore artifact mitigations arising from concurrent stimulation and sensing. We then used a prototype investigational implantable device, DyNeuMo, and a bench-setup that accounts for tissue–electrode properties, to confirm our observations and verify mitigations. The strategies to reduce transient stimulation artifacts and improve performance during aDBS were confirmed in a chronic implant using updated configuration settings. Main results. We derived and validated a ‘checklist’ of configuration settings to improve system performance and areas for future device improvement. Key considerations for the configuration include (a) active instead of passive recharge, (b) sense-channel blanking in the amplifier, (c) high-pass filter settings, (d) tissue–electrode impedance mismatch management, (e) time-frequency trade-offs in the classifier, (f) algorithm blanking and transition rate limits. Without proper channel configuration, the aDBS algorithm was susceptible to limit-cycles of oscillating stimulation independent of physiological state. By applying the checklist, we could optimize each block’s performance characteristics within the overall system. With system-level optimization, a ‘fast’ aDBS prototype algorithm was demonstrated to be feasible without reentrant loops, and with noise performance suitable for subcortical brain circuits. Significance. We present a framework to study sources and propose mitigations of artifacts in devices that provide chronic aDBS. This work highlights the trade-offs in performance as novel sensing devices translate to the clinic. Finding the appropriate balance of constraints is imperative for successful translation of aDBS therapies. Clinical trial: Institutional Review Board and Investigational Device Exemption numbers: NCT02649166/IRB201501021 (University of Florida), NCT04043403/IRB52548 (Stanford University), NCT03582891/IRB1824454 (University of California San Francisco). IDE #180 097.

Published
2021

41. Embedding Digital Chronotherapy into Bioelectronic Medicines

Author

John Edward Fleming, Vaclav Kremen, Roee Gilron, Nicholas M. Gregg, Derk-Jan Dijk, Philip Starr, Gregory Worrell, Simon Little, and Timothy Denison

Subjects
engrXiv|Engineering, engrXiv|Engineering|Biomedical Engineering and Bioengineering, bepress|Engineering, engrXiv|Engineering|Biomedical Engineering and Bioengineering|Bioelectrical and Neuroengineering, bepress|Engineering|Biomedical Engineering and Bioengineering|Bioelectrical and Neuroengineering, bepress|Engineering|Biomedical Engineering and Bioengineering
Abstract

Biological rhythms permeate all living organisms at a variety of timescales. These rhythms are fundamental to physiological homeostasis, and their disruption is thought to play a key role in the initiation, progression, and expression of disease. In the last two decades, neuromodulation has been established as an effective adjunct therapy for medically refractory neurological disorders. To date, however, due to the limited sensing and algorithm capabilities of neuromodulation devices, exploring the influence of biological rhythms on therapy efficacy has not been feasible. However, with the development of new bioelectronic devices capable of long-term data recording and adaptive stimulation parameter adjustments, clinical neuroscience researchers are now gaining unprecedented insight into patient physiology across a variety of neurological diseases, including longitudinal rhythmic behavior. In this perspective, we propose that future bioelectronic devices should integrate chronobiological considerations in their physiological control structure to maximize the benefits of therapy. We specifically highlight this need for deep brain stimulation (DBS) chronotherapy, where the DBS therapeutic dosage would be titrated based on the time-of-day and synchronized to each patient’s individual chronotype/sleep-wake cycle. This is motivated by preliminary longitudinal data recorded from both patients with Parkinson’s disease (PD) and epilepsy, which show periodic symptom biomarkers synchronized to sub-daily (ultradian), daily (circadian), and longer time scale (infradian) rhythms. In addition, considering side effects, tonic stimulation can undermine diurnal patterns and cause fragmentation of sleep-wake rhythms. Based on these observations, we suggest a control structure for future bioelectronic devices which incorporates anticipatory, time-based adaptation of stimulation control, locked to patient-specific biological rhythms, as an adjunct to classical feedforward and feedback control methods. Initial results from three case studies using chronotherapy-enabled prototypes will illustrate the concept. The proposed control architecture for a future bioelectronic implant mimics more closely the classical integration of adaptive, feedforward, and feedback control methods found in physiology, and could be useful as a general method for personalized therapy refinement.

Published
2021

42. DyNeuMo Mk-1: Design and pilot validation of an investigational motion-adaptive neurostimulator with integrated chronotherapy

Author

Mayela Zamora, Robert Toth, Francesca Morgante, Jon Ottaway, Tom Gillbe, Sean Martin, Guy Lamb, Tara Noone, Moaad Benjaber, Zachary Nairac, Devang Sehgal, Timothy G. Constandinou, Jeffrey Herron, Tipu Z. Aziz, Ivor Gillbe, Alexander L. Green, Erlick A.C. Pereira, and Timothy Denison

Subjects
Chronotherapy, Movement Disorders, Developmental Neuroscience, Neurology, Brain, Humans, Reproducibility of Results, Algorithms, Article
Abstract

There is growing interest in using adaptive neuro-modulation to provide a more personalized therapy experience that might improve patient outcomes. Current implant technology, however, can be limited in its adaptive algorithm capability. To enable exploration of adaptive algorithms with chronic implants, we designed and validated the, ‘Picostim DyNeuMo Mk-1’, (DyNeuMo Mk-1 for short), a fully-implantable, adaptive research stimulator that titrates stimulation based on circadian rhythms (e.g. sleep, wake) and the patient’s movement state (e.g. posture, activity, shock, free-fall). The design leverages off-the-shelf consumer technology that provides inertial sensing with low-power, high reliability, and relatively modest cost. The DyNeuMo Mk-1 system was designed, manufactured and verified using ISO 13485 design controls, including ISO 14971 risk management techniques to ensure patient safety, while enabling novel algorithms. The system was validated for an intended use case in movement disorders under an emergency-device authorization from the Medicines and Healthcare Products Regulatory Agency (MHRA). The algorithm configurability and expanded stimulation parameter space allows for a number of applications to be explored in both central and peripheral applications. Intended applications include adaptive stimulation for movement disorders, synchronizing stimulation with circadian patterns, and reacting to transient inertial events such as posture changes, general activity, and walking. With appropriate design controls in place, first-in-human research trials are now being prepared to explore the utility of automated motion-adaptive algorithms.

Published
2022
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43. OxVent: Design and evaluation of a rapidly-manufactured Covid-19 ventilator

Author

Richard Beale, Jacqueline Beddoe Rosendo, Christos Bergeles, Anair Beverly, Luigi Camporota, Alfonso A. Castrejón-Pita, Douglas C. Crockett, John N. Cronin, Timothy Denison, Sebastian East, Chantal Edwardes, Andrew D. Farmery, Filiberto Fele, James Fisk, Carla V. Fuenteslópez, Michael Garstka, Paul Goulart, Clare Heaysman, Azad Hussain, Prashant Jha, Idris Kempf, Adhithya Senthil Kumar, Annika Möslein, Andrew C.J. Orr, Sebastien Ourselin, David Salisbury, Carlo Seneci, Robert Staruch, Harrison Steel, Mark Thompson, Minh C. Tran, Valentina Vitiello, Miguel Xochicale, Feibiao Zhou, Federico Formenti, and Thomas Kirk

Subjects
Male, Respiratory Rate, SARS-CoV-2, Swine, Tidal Volume, Animals, COVID-19, Female, Equipment Design, General Medicine, Respiration, Artificial, General Biochemistry, Genetics and Molecular Biology
Abstract

Background The manufacturing of any standard mechanical ventilator cannot rapidly be upscaled to several thousand units per week, largely due to supply chain limitations. The aim of this study was to design, verify and perform a pre-clinical evaluation of a mechanical ventilator based on components not required for standard ventilators, and that met the specifications provided by the Medicines and Healthcare Products Regulatory Agency (MHRA) for rapidly-manufactured ventilator systems (RMVS). Methods The design utilises closed-loop negative feedback control, with real-time monitoring and alarms. Using a standard test lung, we determined the difference between delivered and target tidal volume (VT) at respiratory rates between 20 and 29 breaths per minute, and the ventilator's ability to deliver consistent VT during continuous operation for >14 days (RMVS specification). Additionally, four anaesthetised domestic pigs (3 male-1 female) were studied before and after lung injury to provide evidence of the ventilator's functionality, and ability to support spontaneous breathing. Findings Continuous operation lasted 23 days, when the greatest difference between delivered and target VT was 10% at inspiratory flow rates >825 mL/s. In the pre-clinical evaluation, the VT difference was -1 (-90 to 88) mL [mean (LoA)], and positive end-expiratory pressure (PEEP) difference was -2 (-8 to 4) cmH2O. VT delivery being triggered by pressures below PEEP demonstrated spontaneous ventilation support. Interpretation The mechanical ventilator presented meets the MHRA therapy standards for RMVS and, being based on largely available components, can be manufactured at scale. Funding Work supported by Wellcome/EPSRC Centre for Medical Engineering,King’s Together Fund and Oxford University.

Published
2022
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44. A high-performance 4 nV (√Hz)

Author

Konstantinos, Petkos, Thomas, Guiho, Patrick, Degenaar, Andrew, Jackson, Peter, Brown, Timothy, Denison, and Emmanuel M, Drakakis

Subjects
analog filtering, high-performance analog front-end, Deep Brain Stimulation, Humans, DBS, artefact suppression, LFP (/E × G) bioinstrumentation, Artifacts, Brain Waves, Basal Ganglia, Article
Abstract

Objective Recording of local field potentials (LFPs) during deep brain stimulation (DBS) is necessary to investigate the instantaneous brain response to stimulation, minimize time delays for closed-loop neurostimulation and maximise the available neural data. To our knowledge, existing recording systems lack the ability to provide artefact-free high-frequency (>100 Hz) LFP recordings during DBS in real time primarily because of the contamination of the neural signals of interest by the stimulation artefacts. Approach To solve this problem, we designed and developed a novel, low-noise and versatile analog front-end (AFE) that uses a high-order (8th) analog Chebyshev notch filter to suppress the artefacts originating from the stimulation frequency. After defining the system requirements for concurrent LFP recording and DBS artefact suppression, we assessed the performance of the realised AFE by conducting both in vitro and in vivo experiments using unipolar and bipolar DBS (monophasic pulses, amplitude ranging from 3 to 6 V peak-to-peak, frequency 140 Hz and pulse width 100 μs). A full performance comparison between the proposed AFE and an identical AFE, equipped with an 8th order analog Bessel notch filter, was also conducted. Main results A high-performance, 4 nV (Hz)−1 AFE that is capable of recording nV-scale signals was designed in accordance with the imposed specifications. Under both in vitro and in vivo experimental conditions, the proposed AFE provided real-time, low-noise and artefact-free LFP recordings (in the frequency range 0.5–250 Hz) during stimulation. Its sensing and stimulation artefact suppression capabilities outperformed the capabilities of the AFE equipped with the Bessel notch filter. Significance The designed AFE can precisely record LFP signals, in and without the presence of either unipolar or bipolar DBS, which renders it as a functional and practical AFE architecture to be utilised in a wide range of applications and environments. This work paves the way for the development of externalized research tools for closed-loop neuromodulation that use low- and higher-frequency LFPs as control signals.

Published
2019

45. Stimulating at the right time: phase-specific deep brain stimulation

Author

Hayriye, Cagnan, David, Pedrosa, Simon, Little, Alek, Pogosyan, Binith, Cheeran, Tipu, Aziz, Alexander, Green, James, Fitzgerald, Thomas, Foltynie, Patricia, Limousin, Ludvic, Zrinzo, Marwan, Hariz, Karl J, Friston, Timothy, Denison, and Peter, Brown

Subjects
Dystonia, Thalamus, Deep Brain Stimulation, Essential Tremor, Accelerometry, Tremor, Humans
Abstract

SEE MOLL AND ENGEL DOI101093/AWW308 FOR A SCIENTIFIC COMMENTARY ON THIS ARTICLE: Brain regions dynamically engage and disengage with one another to execute everyday actions from movement to decision making. Pathologies such as Parkinson's disease and tremor emerge when brain regions controlling movement cannot readily decouple, compromising motor function. Here, we propose a novel stimulation strategy that selectively regulates neural synchrony through phase-specific stimulation. We demonstrate for the first time the therapeutic potential of such a stimulation strategy for the treatment of patients with pathological tremor. Symptom suppression is achieved by delivering stimulation to the ventrolateral thalamus, timed according to the patient's tremor rhythm. Sustained locking of deep brain stimulation to a particular phase of tremor afforded clinically significant tremor relief (up to 87% tremor suppression) in selected patients with essential tremor despite delivering less than half the energy of conventional high frequency stimulation. Phase-specific stimulation efficacy depended on the resonant characteristics of the underlying tremor network. Selective regulation of neural synchrony through phase-locked stimulation has the potential to both increase the efficiency of therapy and to minimize stimulation-induced side effects.

Published
2016

46. Predictive ability of cerebrospinal fluid biomarkers in diagnosing and evaluating Parkinson's disease

Author

Timothy Denison and Timothy Denison., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., Wang, Michelle J, Timothy Denison and Timothy Denison., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science., and Wang, Michelle J

Abstract

Thesis: M. Eng., Massachusetts Institute of Technology, Department of Electrical Engineering and Computer Science, 2014., This electronic version was submitted by the student author. The certified thesis is available in the Institute Archives and Special Collections., Cataloged from student-submitted PDF version of thesis., Includes bibliographical references (page 31)., Currently, there are a variety of clinical assessments and rating scales used in the research and treatment of Parkinson's disease (PD). Despite the widespread use and reliance on these scales, they do not offer a uniform, objective measure. Many previous studies have indicated promising relationships between various biomarkers and Parkinsonian symptoms that could lead to objective measures by using statistical methods and providing p-values. However, we could not find any literature that uses machine learning or directly tests predictive value. The goal of this thesis was to determine whether or not cerebrospinal fluid (CSF) biomarker data could predict incidence of Parkinson's with a high degree of accuracy and differentiate between patients with varying levels of severity. We used various supervised machine learning algorithms on the Parkinson's Progression Markers Initiative (PPMI) baseline data set provided by the Michael J. Fox Foundation, and reported the percentage of patients correctly diagnosed by each algorithm on an isolated test data set. The best classifier averaged 69% accuracy in distinguishing human controls from PD patients. While this does indicate the presence of some predictive power, it is not clinically useful and we tentatively conclude a negative result. The data pertain to the CSF biomarkers available from PPMI at the end of October 2013., by Michelle J. Wang., M. Eng.

Published
2014

47. High performance amplifier topologies implemented with a micro-machined vibrating capacitor

Author

Timothy Denison and Steven Leeb., Massachusetts Institute of Technology. Dept. of Electrical Engineering and Computer Science., Aina, Akin Adeniyi, 1974, Timothy Denison and Steven Leeb., Massachusetts Institute of Technology. Dept. of Electrical Engineering and Computer Science., and Aina, Akin Adeniyi, 1974

Abstract

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2003., Includes bibliographical references (leaves 201-206)., In this work, the design of a MEMS based differential amplifier is investigated. The goal of this investigation is to design, fabricate and characterize a differential amplifier whose performance is based on a physically coupled, but electrically isolated fully differential mechanical transconductor input stage that is fabricated using SOI-MEMS technology. The MEMS sensor will act as a vibrating capacitor input stage. It will provide galvanic isolation and up-modulation of the input signal as it vibrates. The galvanic isolation facilitates low-leakage inputs and a very wide input common mode voltage range. The up-modulation provides a means for achieving a low input referred offset voltage and low-noise via the use of correlated double sampling or chopper stabilization. At the system level, this amplifier consists of two major loops: the drive loop and a sense loop. The drive loop includes half of the MEMS structure along with some electronics and provides a means of moving the beam at a constant frequency. The drive loop's design was facilitated by describing function analysis. The drive loop vibrated the beam at its mechanical resonance because at that frequency, the displacement of the beam is maximized for a given electrostatic force and consequently, the sensitivity of the amplifier is maximized. The sense loop includes the other half of the beam and some electronics whose role is to process the differential input signal applied at the MEMS structure's inputs. Common-mode rejection is performed by the mechanical transconductor, while the sense loop's crossover frequency sets the signal bandwidth., (cont.) The performance of the amplifier agreed very well with hand calculations and simulations. The noise performance was dominated by the total noise at the preamplifier's input. The noise performance achieved in this design was 55 ... Hz , which is higher than that of other high performance amplifiers. Based on the analytical model created for the amplifier, a noise level of 450 ... Hz can be achieved when the circuitry is fully integrated with the sensor., by Akin Adeniyi Aina., Ph.D.

Published
2005

48. From basic sciences and engineering to epileptology: A translational approach

Author

Elie Bou Assi, Kaspar Schindler, Christophe de Bézenac, Timothy Denison, Sharanya Desai, Simon S. Keller, Émile Lemoine, Abbas Rahimi, Mahsa Shoaran, and Christian Rummel

Subjects
hyperdimensional computing, dynamics, intelligence, scientific platforms, stimulation, Neurology, classification, intelligent neural prostheses, magnetic resonance imaging, epilepsy, Neurology (clinical), patient, eeg, 610 Medicine & health, electroencephalography, mri
Abstract

Collaborative efforts between basic scientists, engineers, and clinicians are enabling translational epileptology. In this article, we summarize the recent advances presented at the International Conference for Technology and Analysis of Seizures (ICTALS 2022): (1) novel developments of structural magnetic resonance imaging; (2) latest electroencephalography signal-processing applications; (3) big data for the development of clinical tools; (4) the emerging field of hyperdimensional computing; (5) the new generation of artificial intelligence (AI)-enabled neuroprostheses; and (6) the use of collaborative platforms to facilitate epilepsy research translation. We highlight the promise of AI reported in recent investigations and the need for multicenter data-sharing initiatives.

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