Your search keyword '"Giftakis JE"' showing total 10 results

1. Long Term Performance of a Bi-Directional Neural Interface for Deep Brain Stimulation and Recording.

Author

Stanslaski SR, Case MA, Giftakis JE, Raike RS, and Stypulkowski PH

Abstract

Background: In prior reports, we described the design and initial performance of a fully implantable, bi-directional neural interface system for use in deep brain and other neurostimulation applications. Here we provide an update on the chronic, long-term neural sensing performance of the system using traditional 4-contact leads and extend those results to include directional 8-contact leads. Methods: Seven ovine subjects were implanted with deep brain stimulation (DBS) leads at different nodes within the Circuit of Papez: four with unilateral leads in the anterior nucleus of the thalamus and hippocampus; two with bilateral fornix leads, and one with bilateral hippocampal leads. The leads were connected to either an Activa PC+S ® (Medtronic) or Percept PC °ledR (Medtronic) deep brain stimulation and recording device. Spontaneous local field potentials (LFPs), evoked potentials (EPs), LFP response to stimulation, and electrode impedances were monitored chronically for periods of up to five years in these subjects. Results: The morphology, amplitude, and latencies of chronic hippocampal EPs evoked by thalamic stimulation remained stable over the duration of the study. Similarly, LFPs showed consistent spectral peaks with expected variation in absolute magnitude dependent upon behavioral state and other factors, but no systematic degradation of signal quality over time. Electrode impedances remained within expected ranges with little variation following an initial stabilization period. Coupled neural activity between the two nodes within the Papez circuit could be observed in synchronized recordings up to 5 years post-implant. The magnitude of passive LFP power recorded from directional electrode segments was indicative of the contacts that produced the greatest stimulation-induced changes in LFP power within the Papez network. Conclusion: The implanted device performed as designed, providing the ability to chronically stimulate and record neural activity within this network for up to 5 years of follow-up., Competing Interests: All of the authors are employees of Medtronic PLC., (Copyright © 2022 Stanslaski, Case, Giftakis, Raike and Stypulkowski.)

Published

2022

2. Analysis of Deep Brain Stimulation Lead Targeting in the Stimulation of Anterior Nucleus of the Thalamus for Epilepsy Clinical Trial.

Author

Gross RE, Fisher RS, Sperling MR, Giftakis JE, and Stypulkowski PH

Subjects

Humans, Retrospective Studies, Anterior Thalamic Nuclei, Deep Brain Stimulation, Drug Resistant Epilepsy therapy, Epilepsy therapy

Abstract

Background: Deep brain stimulation (DBS) of the anterior nucleus of the thalamus (ANT) is an effective therapy for patients with drug-resistant focal epilepsy. Best practices for surgical targeting of the ANT can be refined as new information becomes available regarding effective stimulation sites., Objective: To conduct a retrospective analysis of the relationship between outcomes (seizure reduction during year 1) and DBS lead locations in subjects from the SANTÉ pivotal trial (Stimulation of ANT for Epilepsy) based upon recent clinical findings., Methods: Postoperative images from SANTÉ subjects (n = 101) were evaluated with respect to lead trajectory relative to defined anatomic landmarks. A qualitative scoring system was used to rate each lead placement for proximity to an identified target region above the junction of the mammillothalamic tract with the ANT. Each subject was assigned a bilateral lead placement score, and these scores were then compared to clinical outcomes., Results: Approximately 70% of subjects had "good" bilateral lead placements based upon location with respect to the defined target. These subjects had a much higher probability of being a clinical responder (>50% seizure reduction) than those with scores reflecting suboptimal lead placements (43.5% vs 21.9%, P < .05)., Conclusion: Consistent with experience from more established DBS indications, our findings and other recent reports suggest that there may be specific sites within the ANT that are associated with superior clinical outcomes. It will be important to continue to evaluate these relationships and the evolution of other clinical practices (eg, programming) to further optimize this therapy., (© Congress of Neurological Surgeons 2021.)

Published

2021

3. The SANTÉ study at 10 years of follow-up: Effectiveness, safety, and sudden unexpected death in epilepsy.

Author

Salanova V, Sperling MR, Gross RE, Irwin CP, Vollhaber JA, Giftakis JE, and Fisher RS

Subjects

Aged, Double-Blind Method, Electric Stimulation Therapy adverse effects, Electrodes, Implanted, Epilepsy, Tonic-Clonic epidemiology, Female, Follow-Up Studies, Humans, Incidence, Magnetic Resonance Imaging, Male, Middle Aged, Patient Safety, Seizures epidemiology, Seizures prevention & control, Treatment Outcome, Vagus Nerve Stimulation, Anterior Thalamic Nuclei, Electric Stimulation Therapy methods, Sudden Unexpected Death in Epilepsy epidemiology

Abstract

Objective: We evaluated the efficacy and safety of deep brain anterior thalamus stimulation after 7 and 10 years, and report the incidence of sudden unexpected death in epilepsy (SUDEP) and overall mortality in adults in the Stimulation of the Anterior Nucleus of the Thalamus for Epilepsy (SANTÉ) study., Methods: After the 3-month blinded and 9-month unblinded phases, subjects continued to be assessed during long-term follow-up (LTFU) and later a continued therapy access phase (CAP), to further characterize adverse events and the incidence of SUDEP. Stimulus parameter and medication changes were allowed., Results: One hundred ten implanted subjects accumulated a total of 938 device-years of experience (69 subjects during the LTFU phase and 61 subjects in the CAP phase). Prior to study closure, 57 active subjects continued therapy at 14 study centers, with follow-up of at least 10 (maximum 14) years. At 7 years, median seizure frequency percent reduction from baseline was 75% (p < .001), with no outcome differences related to prior vagus nerve stimulation or resective surgery. The most severe seizure type, focal to bilateral tonic-clonic, was reduced by 71%. Adding new antiseizure medications did not impact the pattern of seizure reduction over time. There were no unanticipated serious adverse events in the study. The definite-plus-probable SUDEP rate, based on SANTÉ study experience (two deaths in 938 years) and previous pilot studies (0 deaths in 76 years), indicated a rate of 2.0 deaths for 1000 person-years. Overall mortality was 6.9 deaths per 1000 person-years., Significance: The long-term efficacy and safety profiles of the deep brain stimulation (DBS) system for epilepsy are favorable and demonstrate stable outcomes. Improvement in frequency of the most severe seizure type may reduce SUDEP risk. The SUDEP rate with DBS (2.0) is comparable to other neuromodulation treatments (i.e., vagus nerve stimulation, responsive neurostimulation) for drug-resistant focal epilepsy., (© 2021 International League Against Epilepsy.)

Published

2021

4. Modulation of hippocampal activity with fornix Deep Brain Stimulation.

Author

Stypulkowski PH, Stanslaski SR, and Giftakis JE

Subjects

Animals, Anterior Thalamic Nuclei diagnostic imaging, Anterior Thalamic Nuclei physiology, Evoked Potentials physiology, Female, Hippocampus diagnostic imaging, Hippocampus physiology, Male, Sheep, Temporal Lobe diagnostic imaging, Temporal Lobe physiology, Action Potentials physiology, Deep Brain Stimulation methods, Fornix, Brain diagnostic imaging, Fornix, Brain physiology

Abstract

Background: Deep Brain Stimulation (DBS) within the Papez circuit is under investigation as a treatment for epilepsy and Alzheimer's disease. We previously reported the effects of stimulation at nodes within this network (anterior thalamic nucleus and hippocampus) on hippocampal activity in a large animal model, using a chronic implantable, clinical-grade system that permits concurrent stimulation and recording., Objective: In this study we extended earlier work to compare the effects of fornix DBS on evoked potentials (EPs) and local field potential (LFP) activity within the hippocampus, and to assess closed-loop stimulation., Methods: Unilateral fornix and hippocampal DBS leads were implanted in three ovine subjects using image-guided, frameless stereotaxy. Chronic, awake recordings of EPs and LFPs in response to fornix and hippocampal stimulation were collected with the implanted device and analyzed off-line., Results: Stimulation of the fornix produced robust, short latency hippocampal EPs. High frequency fornix stimulation generated parameter-dependent effects. At low amplitudes, short lasting inhibition of LFP activity occurred. Above a specific amplitude threshold, DBS elicited pronounced bursts of theta activity, followed by a marked state shift in hippocampal activity. These effects persisted for minutes post-DBS and were reflected as changes in LFP spectral content and phase-amplitude coupling. Real-time modulation of hippocampal activity via the implanted device was demonstrated using LFPs as the control signal for closed-loop stimulation., Conclusions: The current results expand earlier findings and demonstrate target-specific effects produced by DBS within this neural circuit. These changes in network activity may provide insights into stimulation targets and parameter selection for clinical investigations., (Copyright © 2017 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2017

5. Brain stimulation for epilepsy--local and remote modulation of network excitability.

Author

Stypulkowski PH, Stanslaski SR, Jensen RM, Denison TJ, and Giftakis JE

Subjects

Algorithms, Animals, Brain Mapping methods, Evoked Potentials physiology, Magnetic Resonance Imaging, Neural Networks, Computer, Sheep, Stereotaxic Techniques, Time Factors, Deep Brain Stimulation methods, Electrodes, Implanted, Epilepsy therapy, Hippocampus physiology, Thalamus physiology

Abstract

Background: The use of Deep Brain Stimulation (DBS) as a potential therapy for treatment resistant epilepsy remains an area of active clinical investigation. We recently reported the first chronic evaluation of an implantable, clinical-grade system that permits concurrent stimulation and recording, in a large animal (ovine) model developed to study DBS for epilepsy., Objective: In this study we extended this work to compare the effects of remote (anterior thalamic) and direct (hippocampal) stimulation on local field potential (LFP) activity and network excitability, and to assess closed-loop stimulation within this neural network., Methods: Following anesthesia and 1.5T MRI acquisition, unilateral anterior thalamic and hippocampal DBS leads were implanted in three subjects using a frameless stereotactic system. Chronic, awake recordings of evoked potentials (EPs) and LFPs in response to thalamic and hippocampal stimulation were collected with the implanted device and analyzed off-line., Results: Consistent with earlier reports, thalamic DBS and direct stimulation of the hippocampus produced parameter-dependent effects on hippocampal activity. LFP suppression could be reliably induced with specific stimulation parameters, and was shown to reflect a state of reduced network excitability, as measured by effects on hippocampal EP amplitudes and after-discharge thresholds. Real-time modulation of network excitability via the implanted device was demonstrated using hippocampal theta-band power level as a control signal for closed-loop stimulation., Conclusions: The results presented provide evidence of network excitability changes induced by stimulation that could underlie the clinical effects that have been reported with both thalamic and direct cortical stimulation., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

6. Chronic evaluation of a clinical system for deep brain stimulation and recording of neural network activity.

Author

Stypulkowski PH, Stanslaski SR, Denison TJ, and Giftakis JE

Subjects

Animals, Deep Brain Stimulation instrumentation, Hippocampus physiology, Monitoring, Intraoperative instrumentation, Sheep, Time Factors, Deep Brain Stimulation methods, Electrodes, Implanted, Evoked Potentials physiology, Monitoring, Intraoperative methods, Nerve Net physiology, Thalamus physiology

Abstract

Background/aims: In conjunction with therapeutic stimulation, next-generation deep brain stimulation (DBS) devices may offer the ability to record and analyze neural signals, providing for unprecedented insight into DBS effects on neural networks. This work was conducted to evaluate an implantable, clinical-grade system that permits concurrent stimulation and recording using a large animal (ovine) model recently developed to study DBS for epilepsy., Methods: Following anesthesia and 1.5-tesla MRI acquisition, unilateral anterior thalamic and hippocampal DBS leads were implanted (n = 3) using a frameless stereotactic system. Chronic, awake recordings of evoked potentials (EPs) and local field potentials were collected with the implanted device and analyzed off-line., Results: Hippocampal EPs were stable over long-term (>1 year) recording and consistent in morphology and latency with prior acute results. Thalamic and hippocampal DBS produced both excitatory and inhibitory network effects that were stimulation site and parameter dependent. Free roaming recordings illustrated periods of highly correlated activity between these two structures within the circuit of Papez., Conclusions: These results provide further insight into mechanisms of DBS therapy for epilepsy and an encouraging demonstration of the capabilities of this new technology, which in the future, may afford unique opportunities to study human brain function and neuromodulation mechanism of action., (Copyright © 2013 S. Karger AG, Basel.)

Published

2013

7. A method for actively tracking excitability of brain networks using a fully implantable monitoring system.

Author

Freestone DR, Long SN, Frey S, Stypulkowski PH, Giftakis JE, and Cook MJ

Subjects

Animals, Anticonvulsants chemistry, Brain Mapping, Circadian Rhythm, Dogs, Drug Delivery Systems, Electrodes, Epilepsy, Levetiracetam, Piracetam analogs & derivatives, Piracetam chemistry, Seizures, Brain physiology, Deep Brain Stimulation, Electrodes, Implanted, Evoked Potentials physiology, Hippocampus physiology, Signal Processing, Computer-Assisted, Thalamus physiology

Abstract

This paper introduces a new method for estimating the excitability of brain networks. The motivation for this research was to develop a system that can track pathological changes in excitability, in diseases such as epilepsy. The ability to track excitability may provide a method for anticipating seizures and intervening therapeutically. Four normally healthy canines were implanted with the Medtronic Activia PC+S deep brain stimulation and sensing system. The devices were used to probe the circuit of Papez, with electrical stimulation in the anterior nucleus of the thalamus to measure evoked potentials in the hippocampus. The canines were given three different dosage levels of anti-convulsant medication in an attempt to manipulate the excitability of the network. The results showed changes in the morphology of the evoked potentials, following a circadian profile and reflecting times of drug delivery.

Published

2013

8. Development of a large animal model for investigation of deep brain stimulation for epilepsy.

Author

Stypulkowski PH, Giftakis JE, and Billstrom TM

Subjects

Animals, Deep Brain Stimulation instrumentation, Epilepsy physiopathology, Evoked Potentials drug effects, Evoked Potentials physiology, Hippocampus drug effects, Hippocampus physiology, Magnetic Resonance Imaging, Penicillins pharmacology, Sheep, Stereotaxic Techniques, Thalamus drug effects, Thalamus physiology, Deep Brain Stimulation methods, Epilepsy therapy, Implantable Neurostimulators, Models, Animal

Abstract

Background/objectives: To better understand the mechanism of action of deep brain stimulation (DBS) for epilepsy and to investigate implantable device features, it is desirable to have a large animal model to evaluate clinical-grade systems. This study assessed the suitability of an ovine model of epilepsy for this purpose., Methods: Animals were anesthetized for surgery and 1.5 T MRIs collected. Unilateral anterior thalamic DBS leads, hippocampal depth electrodes and catheters were implanted using a frameless stereotactic system. Evoked responses and local field potentials were collected and stored for off-line analysis., Results: Despite limited neuroanatomic information for this species, it was possible to reliably implant leads into the target structures using MR-guided techniques. Stimulation of these regions produced robust evoked potentials within this circuit that were dependent on stimulus location and parameters. High-frequency thalamic DBS produced a clear inhibition of both spontaneous and penicillin-induced ictal activity in the hippocampus which far outlasted the duration of the stimulation., Conclusions: These preliminary results suggest that the sheep model may be useful for further investigation of DBS for epilepsy. The demonstration of marked suppression of network excitability with high-frequency stimulation supports a potential therapeutic mechanism for this DBS therapy., (Copyright © 2011 S. Karger AG, Basel.)

Published

2011

9. Deep brain stimulation of the ventral internal capsule/ventral striatum for obsessive-compulsive disorder: worldwide experience.

Author

Greenberg BD, Gabriels LA, Malone DA Jr, Rezai AR, Friehs GM, Okun MS, Shapira NA, Foote KD, Cosyns PR, Kubu CS, Malloy PF, Salloway SP, Giftakis JE, Rise MT, Machado AG, Baker KB, Stypulkowski PH, Goodman WK, Rasmussen SA, and Nuttin BJ

Subjects

Adult, Behavior Therapy methods, Biophysics, Electrodes, Female, Humans, International Cooperation, Longitudinal Studies, Male, Middle Aged, Obsessive-Compulsive Disorder physiopathology, Retrospective Studies, Tomography, X-Ray Computed, Treatment Outcome, Young Adult, Corpus Striatum physiology, Deep Brain Stimulation methods, Internal Capsule physiology, Obsessive-Compulsive Disorder therapy

Abstract

Psychiatric neurosurgery teams in the United States and Europe have studied deep brain stimulation (DBS) of the ventral anterior limb of the internal capsule and adjacent ventral striatum (VC/VS) for severe and highly treatment-resistant obsessive-compulsive disorder. Four groups have collaborated most closely, in small-scale studies, over the past 8 years. First to begin was Leuven/Antwerp, followed by Butler Hospital/Brown Medical School, the Cleveland Clinic and most recently the University of Florida. These centers used comparable patient selection criteria and surgical targeting. Targeting, but not selection, evolved during this period. Here, we present combined long-term results of those studies, which reveal clinically significant symptom reductions and functional improvement in about two-thirds of patients. DBS was well tolerated overall and adverse effects were overwhelmingly transient. Results generally improved for patients implanted more recently, suggesting a 'learning curve' both within and across centers. This is well known from the development of DBS for movement disorders. The main factor accounting for these gains appears to be the refinement of the implantation site. Initially, an anterior-posterior location based on anterior capsulotomy lesions was used. In an attempt to improve results, more posterior sites were investigated resulting in the current target, at the junction of the anterior capsule, anterior commissure and posterior ventral striatum. Clinical results suggest that neural networks relevant to therapeutic improvement might be modulated more effectively at a more posterior target. Taken together, these data show that the procedure can be successfully implemented by dedicated interdisciplinary teams, and support its therapeutic promise.

Published

2010

10. Deep brain stimulation of the ventral capsule/ventral striatum for treatment-resistant depression.

Author

Malone DA Jr, Dougherty DD, Rezai AR, Carpenter LL, Friehs GM, Eskandar EN, Rauch SL, Rasmussen SA, Machado AG, Kubu CS, Tyrka AR, Price LH, Stypulkowski PH, Giftakis JE, Rise MT, Malloy PF, Salloway SP, and Greenberg BD

Subjects

Adolescent, Adult, Chronic Disease, Cognition physiology, Depressive Disorder psychology, Drug Resistance, Electrodes, Implanted, Female, Humans, Male, Middle Aged, Neuropsychological Tests, Psychiatric Status Rating Scales, Recurrence, Treatment Outcome, Young Adult, Deep Brain Stimulation adverse effects, Depressive Disorder therapy, Neostriatum physiology

Abstract

Background: We investigated the use of deep brain stimulation (DBS) of the ventral capsule/ventral striatum (VC/VS) for treatment refractory depression., Methods: Fifteen patients with chronic, severe, highly refractory depression received open-label DBS at three collaborating clinical sites. Electrodes were implanted bilaterally in the VC/VS region. Stimulation was titrated to therapeutic benefit and the absence of adverse effects. All patients received continuous stimulation and were followed for a minimum of 6 months to longer than 4 years. Outcome measures included the Hamilton Depression Rating Scale-24 item (HDRS), the Montgomery-Asberg Depression Rating Scale (MADRS), and the Global Assessment of Function Scale (GAF)., Results: Significant improvements in depressive symptoms were observed during DBS treatment. Mean HDRS scores declined from 33.1 at baseline to 17.5 at 6 months and 14.3 at last follow-up. Similar improvements were seen with the MADRS (34.8, 17.9, and 15.7, respectively) and the GAF (43.4, 55.5, and 61.8, respectively). Responder rates with the HDRS were 40% at 6 months and 53.3% at last follow-up (MADRS: 46.7% and 53.3%, respectively). Remission rates were 20% at 6 months and 40% at last follow-up with the HDRS (MADRS: 26.6% and 33.3%, respectively). The DBS was well-tolerated in this group., Conclusions: Deep brain stimulation of the VC/VS offers promise for the treatment of refractory major depression.

Published

2009