Your search keyword '"Till A. Dembek"' showing total 2 results

1. EEG-based biomarkers for optimizing deep brain stimulation contact configuration in Parkinson’s disease

Author

Jana Peeters, Tine Van Bogaert, Alexandra Boogers, Till Anselm Dembek, Robin Gransier, Jan Wouters, Wim Vandenberghe, Philippe De Vloo, Bart Nuttin, and Myles Mc Laughlin

Subjects

evoked potentials, deep brain stimulation, movement disorders, Parkinson’s disease, programming, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

ObjectiveSubthalamic deep brain stimulation (STN-DBS) is a neurosurgical therapy to treat Parkinson’s disease (PD). Optimal therapeutic outcomes are not achieved in all patients due to increased DBS technological complexity; programming time constraints; and delayed clinical response of some symptoms. To streamline the programming process, biomarkers could be used to accurately predict the most effective stimulation configuration. Therefore, we investigated if DBS-evoked potentials (EPs) combined with imaging to perform prediction analyses could predict the best contact configuration.MethodsIn 10 patients, EPs were recorded in response to stimulation at 10 Hz for 50 s on each DBS-contact. In two patients, we recorded from both hemispheres, resulting in recordings from a total of 12 hemispheres. A monopolar review was performed by stimulating on each contact and measuring the therapeutic window. CT and MRI data were collected. Prediction models were created to assess how well the EPs and imaging could predict the best contact configuration.ResultsEPs at 3 ms and at 10 ms were recorded. The prediction models showed that EPs can be combined with imaging data to predict the best contact configuration and hence, significantly outperformed random contact selection during a monopolar review.ConclusionEPs can predict the best contact configuration. Ultimately, these prediction tools could be implemented into daily practice to ease the DBS programming of PD patients.

Published

2023

2. Towards biomarker-based optimization of deep brain stimulation in Parkinson’s disease patients

Author

Jana Peeters, Alexandra Boogers, Tine Van Bogaert, Till Anselm Dembek, Robin Gransier, Jan Wouters, Wim Vandenberghe, Philippe De Vloo, Bart Nuttin, and Myles Mc Laughlin

Subjects

evoked potentials, deep brain stimulation, electroencephalography, Parkinson’s disease, programming, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

BackgroundSubthalamic deep brain stimulation (DBS) is an established therapy to treat Parkinson’s disease (PD). To maximize therapeutic outcome, optimal DBS settings must be carefully selected for each patient. Unfortunately, this is not always achieved because of: (1) increased technological complexity of DBS devices, (2) time restraints, or lack of expertise, and (3) delayed therapeutic response of some symptoms. Biomarkers to accurately predict the most effective stimulation settings for each patient could streamline this process and improve DBS outcomes.ObjectiveTo investigate the use of evoked potentials (EPs) to predict clinical outcomes in PD patients with DBS.MethodsIn ten patients (12 hemispheres), a monopolar review was performed by systematically stimulating on each DBS contact and measuring the therapeutic window. Standard imaging data were collected. EEG-based EPs were then recorded in response to stimulation at 10 Hz for 50 s on each DBS-contact. Linear mixed models were used to assess how well both EPs and image-derived information predicted the clinical data.ResultsEvoked potential peaks at 3 ms (P3) and at 10 ms (P10) were observed in nine and eleven hemispheres, respectively. Clinical data were well predicted using either P3 or P10. A separate model showed that the image-derived information also predicted clinical data with similar accuracy. Combining both EPs and image-derived information in one model yielded the highest predictive value.ConclusionEvoked potentials can accurately predict clinical DBS responses. Combining EPs with imaging data further improves this prediction. Future refinement of this approach may streamline DBS programming, thereby improving therapeutic outcomes.Clinical trial registrationClinicalTrials.gov, identifier NCT04658641.

Published

2023