Neuronal activity in the human subthalamic nucleus encodes decision conflict during action selection.

The subthalamic nucleus (STN), which receives excitatory inputs from the cortex and has direct connections with the inhibitory pathways of the basal ganglia, is well positioned to efficiently mediate action selection. Here, we use microelectrode recordings captured during deep brain stimulation surgery as participants engage in a decision task to examine the role of the human STN in action selection. We demonstrate that spiking activity in the STN increases when participants engage in a decision and that the level of spiking activity increases with the degree of decision conflict. These data implicate the STN as an important mediator of action selection during decision processes.

Depth-time interpolation of feature trends extracted from mobile microelectrode data with kernel functions.

BACKGROUND/AIMS: Microelectrode recording (MER) is necessary for precision localization of target structures such as the subthalamic nucleus during deep brain stimulation (DBS) surgery. Attempts to automate this process have produced quantitative temporal trends (feature activity vs. time) extracted from mobile MER data. Our goal was to evaluate computational methods of generating spatial profiles (feature activity vs. depth) from temporal trends that would decouple automated MER localization from the clinical procedure and enhance functional localization in DBS surgery. METHODS: We evaluated two methods of interpolation (standard vs. kernel) that generated spatial profiles from temporal trends. We compared interpolated spatial profiles to true spatial profiles that were calculated with depth windows, using correlation coefficient analysis. RESULTS: Excellent approximation of true spatial profiles is achieved by interpolation. Kernel-interpolated spatial profiles produced superior correlation coefficient values at optimal kernel widths (r = 0.932-0.940) compared to standard interpolation (r = 0.891). The choice of kernel function and kernel width resulted in trade-offs in smoothing and resolution. CONCLUSIONS: Interpolation of feature activity to create spatial profiles from temporal trends is accurate and can standardize and facilitate MER functional localization of subcortical structures. The methods are computationally efficient, enhancing localization without imposing additional constraints on the MER clinical procedure during DBS surgery.

The effect of intraventricular trajectory on brain shift in deep brain stimulation.

BACKGROUND: Brain shift during deep brain stimulation (DBS) surgery may compromise target localization. Loss of cerebrospinal fluid is believed to be the underlying mechanism, thus an intraventricular trajectory during DBS surgery may be associated with increased shift, in addition to other complications, such as intraventricular hemorrhage. OBJECTIVE: We set out to assess the effect of traversing the lateral ventricle on brain shift during DBS surgery. METHODS: We performed a retrospective review of 65 pre- and postoperative MR images of patients who underwent bilateral subthalamic nucleus deep brain stimulator placement to treat advanced Parkinson's disease. Patients were separated into two groups: Group A (intraventricular trajectory, n = 46) and Group B (no intraventricular trajectory, n = 19). In these patients, we compared pre- and postoperative frame coordinates of the red nucleus (RN). RESULTS: Group B demonstrated significantly more posterior shift of the center of the RN (1.40 ± 1.32 mm) than Group A (0.64 ± 1.76 mm; p < 0.02). We found no increase in incidence of intraventricular hemorrhage or the number of microelectrode trajectory attempts. CONCLUSIONS: Intraventricular trajectories during DBS surgery do not appear to compromise safety or targeting accuracy.

Error reduction with routine checklist use during deep brain stimulation surgery.

BACKGROUND: The use of checklists to reduce error rates in procedural literature has led our group to employ this strategy during deep brain stimulation (DBS) surgery. OBJECTIVES: We sought to examine the improvement in the number of errors made during DBS surgery after long-term use of a checklist. METHODS: Our checklist has been used for all DBS cases at our institution since the beginning of this study's enrollment in 2008. The number of cases in which errors were detected after 1 year of routine use (group B, n = 11) was compared in one cohort of DBS subjects to that of an earlier cohort of patients (group A, n = 17), which underwent DBS exactly 1 year prior. RESULTS: Eleven of the 14 cases where major errors were detected occurred in group A; 6 of the 9 cases where only minor errors were detected were also in group A; of the patients without any error, all 5 were in group B. We found a significant difference in these proportions between group A and group B [χ(2)(2) = 9.73; p < 0.008]. CONCLUSIONS: After 1 year of checklist use, the total number of major and minor errors made was reduced, indicating an improvement in error rate after long-term routine incorporation of this checklist.

Longevity analysis of currently available deep brain stimulation devices.

OBJECTIVE: There continues to be debate about the surgical technique, electrophysiology, and hardware used in deep brain stimulation (DBS), despite its widespread use in medically intractable Parkinson's disease and essential tremor. This article is the first, to our knowledge, to compare the longevity of the available internal pulse generators (IPGs) of DBS (Kinetra and Soletra, Medtronics). METHODS: We compared the elapsed time from the initial surgery to the first replacement of IPGs in patients with bilateral Soletra IPGs to those with the unilateral Kinetra IPG and analyzed the various stimulation parameters of each device. RESULTS: The battery life of the Soletra system was significantly longer than that of the Kinetra and also allowed for higher voltages, longer use of monopolar mode, and a greater number of electrode contacts. CONCLUSIONS: Our findings support superior battery life and a greater capacity for titration to symptom control with bilateral Soletra IPGs.

Expanding applications of deep brain stimulation: a potential therapeutic role in obesity and addiction management.

BACKGROUND: The indications for deep brain stimulation (DBS) are expanding, and the feasibility and efficacy of this surgical procedure in various neurologic and neuropsychiatric disorders continue to be tested. This review attempts to provide background and rationale for applying this therapeutic option to obesity and addiction. We review neural targets currently under clinical investigation for DBS­the hypothalamus and nucleus accumbens­in conditions such as cluster headache and obsessive-compulsive disorder. These brain regions have also been strongly implicated in obesity and addiction. These disorders are frequently refractory, with very high rates of weight regain or relapse, respectively, despite the best available treatments. METHODS: We performed a structured literature review of the animal studies of DBS, which revealed attenuation of food intake, increased metabolism, or decreased drug seeking. We also review the available radiologic evidence in humans, implicating the hypothalamus and nucleus in obesity and addiction. RESULTS: The available evidence of the promise of DBS in these conditions combined with significant medical need, support pursuing pilot studies and clinical trials of DBS in order to decrease the risk of dietary and drug relapse. CONCLUSIONS: Well-designed pilot studies and clinical trials enrolling carefully selected patients with obesity or addiction should be initiated.

Deep brain stimulation in the treatment of refractory epilepsy: update on current data and future directions.

Deep brain stimulation for epilepsy has garnered attention from epileptologists due to its well-documented success in treating movement disorders and the low morbidity associated with the implantation of electrodes. Given the large proportion of patients who fail medical therapy and are not candidates for surgical amelioration, as well as the suboptimal seizure control offered by vagus nerve stimulation, the search for appropriate brain structures to serve as targets for deep brain stimulation has generated a useful body of evidence to serve as the basis for larger investigations. Early results of the SANTE trial should lay the foundation for widespread implementation of DBS for epilepsy targeting the anterior thalamic nucleus. Other targets also offer promise, including the caudate nucleus, the subthalamic nucleus, the cerebellum, the centromedian nucleus of the thalamus, and the hippocampus. This paper reviews the logic which underlies these potential targets and recapitulates the current data from limited human trials supporting each one. It also provides a succinct overview of the surgical procedure used for electrode implantation.

Best surgical practices: a stepwise approach to the University of Pennsylvania deep brain stimulation protocol.

Deep brain stimulation (DBS) is the treatment of choice for otherwise healthy patients with advanced Parkinson disease who are suffering from disabling dyskinesias and motor fluctuations related to dopaminergic therapy. As DBS is an elective procedure, it is essential to minimize the risk of morbidity. Further, precision in targeting deep brain structures is critical to optimize efficacy in controlling motor features. The authors have already established an operational checklist in an effort to minimize errors made during DBS surgery. Here, they set out to standardize a strict, step-by-step approach to the DBS surgery used at their institution, including preoperative evaluation, the day of surgery, and the postoperative course. They provide careful instruction on Leksell frame assembly and placement as well as the determination of indirect coordinates derived from MR images used to target deep brain structures. Detailed descriptions of the operative procedure are provided, outlining placement of the stereotactic arc as well as determination of the appropriate bur hole location, lead placement using electrophysiology, and placement of the internal pulse generator. The authors also include their approach to preventing postoperative morbidity. They believe that a strategic, step-by-step approach to DBS surgery combined with a standardized checklist will help to minimize operating room mistakes that can compromise targeting and increase the risk of complication.

Feasibility of an operational standardized checklist for movement disorder surgery. A pilot study.

Despite the clinical success of deep brain stimulation (DBS), it remains to be elucidated where within the work process the surgical result could diverge from the surgical plan. We sought to determine this. We implemented a standardized checklist to detect and remediate procedural errors. A consecutive series of 13 patients was studied. Revisions, explantations and thermal lesions were excluded. We tabulated the number and type of errors that could occur when implementing a surgical plan. Errors were categorized as minor or major. The elapsed time was also assessed. A mean of two errors per case were identified: 1.15 major errors/case and 0.85 minor errors per case. The total number of errors identified per case did not change significantly over the course of the series. Time to complete the checklist decreased monotonically from 4 min 5 s to 1 min 10 s. The checklist applied in this scenario is a useful tool to identify and remediate errors during DBS, adding minimal additional operative time and consistently identifying errors.

Thalamic deep brain stimulation for midbrain tremor secondary to cystic degeneration of the brainstem.

OBJECTIVE: Tremor resulting from damage to midbrain structures is poorly understood and often difficult to treat. The authors report a case of cystic degeneration of the brainstem with resultant Holmes-like tremor which was successfully treated using a stimulating electrode placed in the contralateral ventralis intermedius nucleus (VIM) of the thalamus. CLINICAL PRESENTATION: A 31-year-old man presented with a multilobulated, multiseptated lesion of the upper brainstem diagnosed after subacute onset of headaches. The patient subsequently developed an incapacitating left-upper-extremity tremor refractory to medical treatment. INTERVENTION: The patient underwent implantation of a deep brain stimulator in the VIM with symptomatic and functional improvement. CONCLUSIONS: Deep brain stimulation is an effective and safe intervention for tremor of unusual etiology. Electrode placement should be based on an understanding of the structure-function relationships underlying the various and distinct types of tremor.

Determination of subthalamic nucleus location by quantitative analysis of despiked background neural activity from microelectrode recordings obtained during deep brain stimulation surgery.

Microelectrode recording during deep brain stimulation surgery is a useful adjunct for subthalamic nucleus (STN) localization. We hypothesize that information in the nonspike background activity can help identify STN boundaries. We present results from a novel quantitative analysis that accomplishes this goal. Thirteen consecutive microelectrode recordings were retrospectively analyzed. Spikes were removed from the recordings with an automated algorithm. The remaining "despiked" signals were converted via root mean square amplitude and curve length calculations into "feature profile" time series. Subthalamic nucleus boundaries determined by inspection, based on sustained deviations from baseline for each feature profile, were compared against those determined intraoperatively by the clinical neurophysiologist. Feature profile activity within STN exhibited a sustained rise in 10 of 13 tracks (77%). The sensitivity of STN entry was 60% and 90% for curve length and root mean square amplitude, respectively, when agreement within 0.5 mm of the neurophysiologist's prediction was used. Sensitivities were 70% and 100% for 1 mm accuracy. Exit point sensitivities were 80% and 90% for both features within 0.5 mm and 1.0 mm, respectively. Reproducible activity patterns in deep brain stimulation microelectrode recordings can allow accurate identification of STN boundaries. Quantitative analyses of this type may provide useful adjunctive information for electrode placement in deep brain stimulation surgery.

Deep brain stimulation in the treatment of obesity.

Obesity is a growing global health problem frequently intractable to current treatment options. Recent evidence suggests that deep brain stimulation (DBS) may be effective and safe in the management of various, refractory neuropsychiatric disorders, including obesity. The authors review the literature implicating various neural regions in the pathophysiology of obesity, as well as the evidence supporting these regions as targets for DBS, in order to explore the therapeutic promise of DBS in obesity. The lateral hypothalamus and ventromedial hypothalamus are the appetite and satiety centers in the brain, respectively. Substantial data support targeting these regions with DBS for the purpose of appetite suppression and weight loss. However, reward sensation associated with highly caloric food has been implicated in overconsumption as well as obesity, and may in part explain the failure rates of conservative management and bariatric surgery. Thus, regions of the brain's reward circuitry, such as the nucleus accumbens, are promising alternatives for DBS in obesity control. The authors conclude that deep brain stimulation should be strongly considered as a promising therapeutic option for patients suffering from refractory obesity.

Brain shift during deep brain stimulation surgery for Parkinson's disease.

BACKGROUND: Brain shift may occur during deep brain stimulation (DBS) surgery, which may affect the position of subcortical structures, compromising target localization. METHODS: We retrospectively evaluated pre- and postoperative magnetic resonance imaging in 50 Parkinson's disease patients who underwent bilateral subthalamic nucleus (STN) DBS. Patients were separated into two groups: group A - those with <2 mm cortical displacement (66 leads) and group B - those with >or=2 mm cortical displacement (34 leads). Pre and post-op coordinates of anterior (AC) and posterior commissures (PC), as well as the boundaries of red nucleus (RN) were compared. RESULTS: AC-PC shortening due to posterior displacement of AC correlated with cortical displacement (p < 0.02) and was significantly greater in group B (0.41 +/- 0.68 mm) than A (0.04 +/- 0.76 mm; p < 0.005). Posterior shift of AC and RN's center positively correlated (p < 0.0001). Shift appeared to impact the number of microelectrode tracks made to optimize STN targeting. AC-PC shortening also correlated with age (p < 0.003) and duration of surgery (p < 0.04). CONCLUSIONS: Subcortical structures shift during DBS surgery. This shift appears to be gravity-dependent since structures only shifted posteriorly, and patients were primarily in the supine position. Posterior shift of RN may indicate STN displacement. Such positional change may compromise target localization, requiring multiple microelectrode adjustments. This may provide indirect justification for the necessity of microelectrode recordings during DBS surgery.

Subthalamic nucleus deep brain stimulation for severe idiopathic dystonia: impact on severity, neuropsychological status, and quality of life.

OBJECT: Medically refractory dystonia has recently been treated using deep brain stimulation (DBS) targeting the globus pallidus internus (GPI). Outcomes have varied depending on the features of the dystonia. There has been limited literature regarding outcomes for refractory dystonia following DBS of the subthalamic nucleus (STN). METHODS: Four patients with medically refractory, predominantly cervical dystonia underwent STN DBS. Intraoperative assessments with the patients in a state of general anesthesia were performed to determine the extent of fixed deformities that might predict outcome. Patients were rated using the Toronto Western Spasmodic Torticollis Rating Scale (TWSTRS) and the Burke-Fahn-Marsden Dystonia Rating Scale (BFMDRS) preoperatively and 3 and 12 months following surgery by a rater blinded to the study. Mean changes and standard errors of the mean in scores were calculated for each subscore of the two scales. Scores were also analyzed using analysis of variance and probability values were generated. Neuropsychological assessments and quality of life ratings using the 36-Item Short Form Health Survey (SF-36) were evaluated longitudinally. RESULTS: Significant improvements were seen in motor (p = 0.04), disability (p = 0.02), and total TWSTRS scores (p = 0.03). Better outcomes were seen in those patients who did not have fixed deformities. There was marked improvement in the mental component score of the SF-36. Neuropsychological function was not definitively impacted as a result of the surgery. CONCLUSIONS: Deep brain stimulation of the STN is a novel target for dystonia and may be an alternative to GPI DBS. Further studies need to be performed to confirm these conclusions and to determine optimal candidates and stimulation parameters.

Electroconvulsive therapy for depression in a Parkinson's disease patient with bilateral subthalamic nucleus deep brain stimulators.

We report a patient with advanced Parkinson's disease (PD) who developed a recurrence of major depression with psychotic features after bilateral subthalamic nucleus (STN) deep brain stimulation (DBS) surgery. Electroconvulsive therapy (ECT) dramatically improved the depression without shifting electrode position or damaging the DBS hardware. This case suggests that ECT can be a safe and effective option for severe depression in PD patients treated with STN DBS.

Thalamic deep brain stimulation for disabling tremor after excision of a midbrain cavernous angioma. Case report.

Thalamic deep brain stimulation (DBS) has been demonstrated to be effective for the treatment of parkinsonian or essential tremor. To date, however, few data exist to support the application of this method to treat midbrain tremor. A 24-year-old right-handed man underwent radiosurgery and subsequent resection of a recurrently hemorrhaging cavernous angioma located in the left side of the midbrain. The surgery exacerbated severe choreoathetotic resting and action tremors of his right extremities and trunk. The patient underwent placement of a deep brain stimulator into the left ventral intermediate nucleus of the thalamus (Vim). Postoperatively, decreased truncal ataxia and right-sided choreoathetotic tremor were demonstrated, with a 57% increase in dexterity as measured by task testing. The authors demonstrate that DBS can be an effective treatment modality for disabling tremor after resection of a midbrain cavernous angioma.

Pallidal deep brain stimulation for longstanding severe generalized dystonia in Hallervorden-Spatz syndrome. Case report.

Generalized dystonia is one of the most disabling movement disorders. Ablative stereotactic surgery such as pallidotomy has been performed for medically refractory dystonia. Recently, deep brain stimulation (DBS) has appeared as an alternative to ablative procedures. Nevertheless, there have been few published reports detailing improvement in dystonia with DBS. This 36-year-old man with Hallervorden-Spatz syndrome suffered from intractable primary generalized dystonia for 28 years. He was completely dependent for activities of daily living and wheelchair bound because of continuous severe dystonic movements in the face, tongue, neck, trunk, and upper and lower extremities while at rest. The Burke-Fahn-Marsden (BFM) Dystonia Rating Scale score was 112 (maximum 120 points). Bilateral DBS of the globus pallidus internus was performed and resulted in marked improvement in motor functioning and dystonic symptoms with a significant reduction in disability. The BFM score improved to 22.5 points (80% improvement) at 3 months postsurgery and the patient's dystonia was still well suppressed 1 year after surgery. Bilateral pallidal stimulation is an effective and safe treatment for intractable generalized dystonia in Hallervorden-Spatz syndrome, even if the disability is severe and longstanding.

Deep brain stimulation for movement disorders: morbidity and mortality in 109 patients.

OBJECT: Deep brain stimulation (DBS) has been advocated as a more highly effective and less morbidity-producing alternative to ablative stereotactic surgery in the treatment of medically intractable movement disorders. Nevertheless, the exact incidence of morbidity and mortality associated with the procedure is not well known. In this study the authors reviewed the surgical morbidity and mortality rates in a large series of DBS operations. METHODS: The authors retrospectively analyzed surgical complications in their consecutive series of 179 DBS implantations in 109 patients performed by a single surgical team at one center between July 1998 and April 2002. The mean follow-up period was 20 months. There were 16 serious adverse events related to surgery in 14 patients (12.8%). There were two perioperative deaths (1.8%), one caused by pulmonary embolism and the second due to aspiration pneumonia. The other adverse events were two pulmonary embolisms, two subcortical hemorrhages, two chronic subdural hematomas, one venous infarction, one seizure, four infections, one cerebrospinal fluid leak, and one skin erosion. The incidence of permanent sequelae was 4.6% (five of 109 patients). The incidence of device-related complications, such as infection or skin erosion, was also 4.6% (five of 109 patients). CONCLUSIONS: There is a significant incidence of adverse events associated with the DBS procedure. Nevertheless, DBS is clinically effective in well-selected patients and should be seriously considered as a treatment option for patients with medically refractory movement disorders.

Bilateral stimulation of the subthalamic nucleus in patients with Parkinson disease: a study of efficacy and safety.

OBJECT: Palliative neurosurgery has reemerged as a valid therapy for patients with advanced Parkinson disease (PD) that is complicated by severe motor fluctuations. Despite great enthusiasm for long-term deep brain stimulation (DBS) of the subthalamic nucleus (STN), existing reports on this treatment are limited. The present study was designed to investigate the safety and efficacy of bilateral stimulation of the STN for the treatment of PD. METHODS: In 12 patients with severe PD, electrodes were stereotactically implanted into the STN with the assistance of electrophysiological conformation of the target location. All patients were evaluated preoperatively during both medication-off and -on conditions, as well as postoperatively at 3, 6, and 12 months during medication-on and -off states and stimulation-on and -off conditions. Tests included assessments based on the Unified Parkinson's Disease Rating Scale (UPDRS) and timed motor tests. The stimulation effect was significant in patients who were in the medication-off state, resulting in a 47% improvement in the UPDRS Part III (Motor Examination) score at 12 months, compared with preoperative status. The benefit was stable for the duration of the follow-up period. Stimulation produced no additional benefit during the medication-on state, however, when compared with patient preoperative status. Significant improvements were made in reducing dyskinesias, fluctuations, and duration of off periods. CONCLUSIONS: This study demonstrates that DBS of the STN is an effective treatment for patients with advanced, medication-refractory PD. Deep brain stimulation of the STN produced robust improvements in motor performance in these severely disabled patients while they were in the medication-off state. Serious adverse events were common in this cohort; however, only two patients suffered permanent sequelae.

Thalamic deep brain stimulation for posttraumatic action tremor.

We report a case of thalamic deep brain stimulation (DBS) for treatment of posttraumatic tremor. An 18-year-old right-handed man developed a disabling and medically refractory action tremor in the right upper extremity 9 months after sustaining diffuse axonal injury in a motor vehicle collision. DBS of the left ventral intermediate nucleus of the thalamus (Vim) suppressed the tremor without complication and should be considered as an option for the management of intractable posttraumatic tremor.