Your search keyword '"Gavin Elias"' showing total 6 results

1. Probing responses to deep brain stimulation with functional magnetic resonance imaging

Author

Aaron Loh, David Gwun, Clement T. Chow, Alexandre Boutet, Jordy Tasserie, Jürgen Germann, Brendan Santyr, Gavin Elias, Kazuaki Yamamoto, Can Sarica, Artur Vetkas, Ajmal Zemmar, Radhika Madhavan, Alfonso Fasano, and Andres M. Lozano

Subjects

Deep brain stimulation, fMRI, Movement disorders, Functional imaging, Neuromodulation, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Background: Deep brain stimulation (DBS) is an established treatment for certain movement disorders and has additionally shown promise for various psychiatric, cognitive, and seizure disorders. However, the mechanisms through which stimulation exerts therapeutic effects are incompletely understood. A technique that may help to address this knowledge gap is functional magnetic resonance imaging (fMRI). This is a non-invasive imaging tool which permits the observation of DBS effects in vivo. Objective: The objective of this review was to provide a comprehensive overview of studies in which fMRI during active DBS was performed, including studied disorders, stimulated brain regions, experimental designs, and the insights gleaned from stimulation-evoked fMRI responses. Methods: We conducted a systematic review of published human studies in which fMRI was performed during active stimulation in DBS patients. The search was conducted using PubMED and MEDLINE. Results: The rate of fMRI DBS studies is increasing over time, with 37 studies identified overall. The median number of DBS patients per study was 10 (range = 1–67, interquartile range = 11). Studies examined fMRI responses in various disease cohorts, including Parkinson's disease (24 studies), essential tremor (3 studies), epilepsy (3 studies), obsessive-compulsive disorder (2 studies), pain (2 studies), Tourette syndrome (1 study), major depressive disorder, anorexia, and bipolar disorder (1 study), and dementia with Lewy bodies (1 study). The most commonly stimulated brain region was the subthalamic nucleus (24 studies). Studies showed that DBS modulates large-scale brain networks, and that stimulation-evoked fMRI responses are related to the site of stimulation, stimulation parameters, patient characteristics, and therapeutic outcomes. Finally, a number of studies proposed fMRI-based biomarkers for DBS treatment, highlighting ways in which fMRI could be used to confirm circuit engagement and refine DBS therapy. Conclusion: A review of the literature reflects an exciting and expanding field, showing that the combination of DBS and fMRI represents a uniquely powerful tool for simultaneously manipulating and observing neural circuitry. Future work should focus on relatively understudied disease cohorts and stimulated regions, while focusing on the prospective validation of putative fMRI-based biomarkers.

Published

2022

2. Tractography analysis of subcallosal cingulate DBS for treatment-resistant depression using normative connectome data

Author

Ha Neul Song, Gavin Elias, Jurgen Germann, Alexandre Boutet, Andres Lozano, Helen Mayberg, and Ki Sueng Choi

Subjects

Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2023

3. Deep brain stimulation targets in epilepsy: Systematic review and meta-analysis of anterior and centromedian thalamic nuclei and hippocampus

Author

Artur Vetkas, Anton Fomenko, Jürgen Germann, Can Sarica, Christian Iorio‐Morin, Nardin Samuel, Kazuaki Yamamoto, Vanessa Milano, Cletus Cheyuo, Ajmal Zemmar, Gavin Elias, Alexandre Boutet, Aaron Loh, Brendan Santyr, Dave Gwun, Jordy Tasserie, Suneil K. Kalia, and Andres M. Lozano

Subjects

Death, Sudden, Drug Resistant Epilepsy, Epilepsy, Neurology, Anterior Thalamic Nuclei, Intralaminar Thalamic Nuclei, Seizures, Deep Brain Stimulation, Humans, Neurology (clinical), Hippocampus

Abstract

Deep brain stimulation (DBS) is a neuromodulatory treatment used in patients with drug-resistant epilepsy (DRE). The primary goal of this systematic review and meta-analysis is to describe recent advancements in the field of DBS for epilepsy, to compare the results of published trials, and to clarify the clinical utility of DBS in DRE. A systematic literature search was performed by two independent authors. Forty-four articles were included in the meta-analysis (23 for anterior thalamic nucleus [ANT], 8 for centromedian thalamic nucleus [CMT], and 13 for hippocampus) with a total of 527 patients. The mean seizure reduction after stimulation of the ANT, CMT, and hippocampus in our meta-analysis was 60.8%, 73.4%, and 67.8%, respectively. DBS is an effective and safe therapy in patients with DRE. Based on the results of randomized controlled trials and larger clinical series, the best evidence exists for DBS of the anterior thalamic nucleus. Further randomized trials are required to clarify the role of CMT and hippocampal stimulation. Our analysis suggests more efficient deep brain stimulation of ANT for focal seizures, wider use of CMT for generalized seizures, and hippocampal DBS for temporal lobe seizures. Factors associated with clinical outcome after DBS for epilepsy are electrode location, stimulation parameters, type of epilepsy, and longer time of stimulation. Recent advancements in anatomical targeting, functional neuroimaging, responsive neurostimulation, and sensing of local field potentials could potentially lead to improved outcomes after DBS for epilepsy and reduced sudden, unexpected death of patients with epilepsy. Biomarkers are needed for successful patient selection, targeting of electrodes and optimization of stimulation parameters.

Published

2021

4. Probing responses to deep brain stimulation with functional magnetic resonance imaging

Author

Aaron Loh, David Gwun, Clement T. Chow, Alexandre Boutet, Jordy Tasserie, Jürgen Germann, Brendan Santyr, Gavin Elias, Kazuaki Yamamoto, Can Sarica, Artur Vetkas, Ajmal Zemmar, Radhika Madhavan, Alfonso Fasano, and Andres M. Lozano

Subjects

Depressive Disorder, Major, Subthalamic Nucleus, General Neuroscience, Deep Brain Stimulation, Biophysics, Humans, Parkinson Disease, Neurology (clinical), Magnetic Resonance Imaging

Abstract

Deep brain stimulation (DBS) is an established treatment for certain movement disorders and has additionally shown promise for various psychiatric, cognitive, and seizure disorders. However, the mechanisms through which stimulation exerts therapeutic effects are incompletely understood. A technique that may help to address this knowledge gap is functional magnetic resonance imaging (fMRI). This is a non-invasive imaging tool which permits the observation of DBS effects in vivo.The objective of this review was to provide a comprehensive overview of studies in which fMRI during active DBS was performed, including studied disorders, stimulated brain regions, experimental designs, and the insights gleaned from stimulation-evoked fMRI responses.We conducted a systematic review of published human studies in which fMRI was performed during active stimulation in DBS patients. The search was conducted using PubMED and MEDLINE.The rate of fMRI DBS studies is increasing over time, with 37 studies identified overall. The median number of DBS patients per study was 10 (range = 1-67, interquartile range = 11). Studies examined fMRI responses in various disease cohorts, including Parkinson's disease (24 studies), essential tremor (3 studies), epilepsy (3 studies), obsessive-compulsive disorder (2 studies), pain (2 studies), Tourette syndrome (1 study), major depressive disorder, anorexia, and bipolar disorder (1 study), and dementia with Lewy bodies (1 study). The most commonly stimulated brain region was the subthalamic nucleus (24 studies). Studies showed that DBS modulates large-scale brain networks, and that stimulation-evoked fMRI responses are related to the site of stimulation, stimulation parameters, patient characteristics, and therapeutic outcomes. Finally, a number of studies proposed fMRI-based biomarkers for DBS treatment, highlighting ways in which fMRI could be used to confirm circuit engagement and refine DBS therapy.A review of the literature reflects an exciting and expanding field, showing that the combination of DBS and fMRI represents a uniquely powerful tool for simultaneously manipulating and observing neural circuitry. Future work should focus on relatively understudied disease cohorts and stimulated regions, while focusing on the prospective validation of putative fMRI-based biomarkers.

Published

2021

5. Identifying the neural network for neuromodulation in epilepsy through connectomics and graphs

Author

Artur Vetkas, Jürgen Germann, Gavin Elias, Aaron Loh, Alexandre Boutet, Kazuaki Yamamoto, Can Sarica, Nardin Samuel, Vanessa Milano, Anton Fomenko, Brendan Santyr, Jordy Tasserie, Dave Gwun, Hyun Ho Jung, Taufik Valiante, George M Ibrahim, Richard Wennberg, Suneil K Kalia, and Andres M Lozano

Subjects

General Engineering

Abstract

Deep brain stimulation is a treatment option for patients with drug-resistant epilepsy. The precise mechanism of neuromodulation in epilepsy is unknown, and biomarkers are needed for optimizing treatment. The aim of this study was to describe the neural network associated with deep brain stimulation targets for epilepsy and to explore its potential application as a novel biomarker for neuromodulation. Using seed-to-voxel functional connectivity maps, weighted by seizure outcomes, brain areas associated with stimulation were identified in normative resting state functional scans of 1000 individuals. To pinpoint specific regions in the normative epilepsy deep brain stimulation network, we examined overlapping areas of functional connectivity between the anterior thalamic nucleus, centromedian thalamic nucleus, hippocampus and less studied epilepsy deep brain stimulation targets. Graph network analysis was used to describe the relationship between regions in the identified network. Furthermore, we examined the associations of the epilepsy deep brain stimulation network with disease pathophysiology, canonical resting state networks and findings from a systematic review of resting state functional MRI studies in epilepsy deep brain stimulation patients. Cortical nodes identified in the normative epilepsy deep brain stimulation network were in the anterior and posterior cingulate, medial frontal and sensorimotor cortices, frontal operculum and bilateral insulae. Subcortical nodes of the network were in the basal ganglia, mesencephalon, basal forebrain and cerebellum. Anterior thalamic nucleus was identified as a central hub in the network with the highest betweenness and closeness values, while centromedian thalamic nucleus and hippocampus showed average centrality values. The caudate nucleus and mammillothalamic tract also displayed high centrality values. The anterior cingulate cortex was identified as an important cortical hub associated with the effect of deep brain stimulation in epilepsy. The neural network of deep brain stimulation targets shared hubs with known epileptic networks and brain regions involved in seizure propagation and generalization. Two cortical clusters identified in the epilepsy deep brain stimulation network included regions corresponding to resting state networks, mainly the default mode and salience networks. Our results were concordant with findings from a systematic review of resting state functional MRI studies in patients with deep brain stimulation for epilepsy. Our findings suggest that the various epilepsy deep brain stimulation targets share a common cortico-subcortical network, which might in part underpin the antiseizure effects of stimulation. Interindividual differences in this network functional connectivity could potentially be used as biomarkers in selection of patients, stimulation parameters and neuromodulation targets.

Published

2021

6. Response: Deep brain stimulation targets in epilepsy: Systematic review and meta‐analysis of anterior and centromedian thalamic nuclei and hippocampus

Author

Artur Vetkas, Anton Fomenko, Jürgen Germann, Can Sarica, Christian Iorio‐Morin, Nardin Samuel, Kazuaki Yamamoto, Vanessa Milano, Cletus Cheyuo, Ajmal Zemmar, Gavin Elias, Alexandre Boutet, Aaron Loh, Brendan Santyr, Dave Gwun, Jordy Tasserie, Suneil K. Kalia, and Andres M. Lozano

Subjects

Epilepsy, Anterior Thalamic Nuclei, Neurology, Intralaminar Thalamic Nuclei, Deep Brain Stimulation, Humans, Neurology (clinical), Hippocampus

Published

2022