Electrical stimulation-evoked dopamine release in the primate striatum.

BACKGROUND: Primate studies demonstrate that high-frequency electrical stimulation (HFS) of the caudate can enhance learning. Importantly, in these studies, stimulation was applied following the execution of behavior and the effect persisted into subsequent trials, suggesting a change in plasticity rather than a momentary facilitation of behavior. OBJECTIVES/METHODS: Although the mechanism of HFS-enhanced learning is not understood, evidence suggests that dopamine plays a critical role. Therefore, we used in vivo amperometry to evaluate the effects of HFS on striatal dopamine release in the anesthetized primate. While this does not directly examine dopamine during learning, it provides insight with relation to dopamine dynamics during electrical stimulation and specifically between different stimulation parameters and striatal compartments. RESULTS: We demonstrate that HFS results in significantly more dopamine release in the striatum compared to low-frequency stimulation. In addition, electrical stimulation operates differentially on specific neuronal elements, as the parameters for dopamine release are different for the caudate, putamen and medial forebrain bundle. CONCLUSIONS: While not direct evidence, these data suggest that HFS evokes significant dopamine release which may play a role in stimulation-enhanced learning. Moreover, these data suggest a means to modulate extracellular dopamine with a high degree of temporal and spatial precision for either research or clinical applications.

Characterizing the spiking dynamics of subthalamic nucleus neurons in Parkinson's disease using generalized linear models.

Accurately describing the spiking patterns of neurons in the subthalamic nucleus (STN) of patients suffering from Parkinson's disease (PD) is important for understanding the pathogenesis of the disease and for achieving the maximum therapeutic benefit from deep brain stimulation (DBS). We analyze the spiking activity of 24 subthalamic neurons recorded in Parkinson's patients during a directed hand movement task by using a point process generalized linear model (GLM). The model relates each neuron's spiking probability simultaneously to factors associated with movement planning and execution, directional selectivity, refractoriness, bursting, and oscillatory dynamics. The model indicated that while short-term history dependence related to refractoriness and bursting are most informative in predicting spiking activity, nearly all of the neurons analyzed have a structured pattern of long-term history dependence such that the spiking probability was reduced 20-30 ms and then increased 30-60 ms after a previous spike. This suggests that the previously described oscillatory firing of neurons in the STN of Parkinson's patients during volitional movements is composed of a structured pattern of inhibition and excitation. This point process model provides a systematic framework for characterizing the dynamics of neuronal activity in STN.

Using point process models to describe rhythmic spiking in the subthalamic nucleus of Parkinson's patients.

Neurological disease is often associated with changes in firing activity in specific brain areas. Accurate statistical models of neural spiking can provide insight into the mechanisms by which the disease develops and clinical symptoms manifest. Point process theory provides a powerful framework for constructing, fitting, and evaluating the quality of neural spiking models. We illustrate an application of point process modeling to the problem of characterizing abnormal oscillatory firing patterns of neurons in the subthalamic nucleus (STN) of patients with Parkinson's disease (PD). We characterize the firing properties of these neurons by constructing conditional intensity models using spline basis functions that relate the spiking of each neuron to movement variables and the neuron's past firing history, both at short and long time scales. By calculating maximum likelihood estimators for all of the parameters and their significance levels, we are able to describe the relative propensity of aberrant STN spiking in terms of factors associated with voluntary movements, with intrinsic properties of the neurons, and factors that may be related to dysregulated network dynamics.

Subthalamic nucleus discharge patterns during movement in the normal monkey and Parkinsonian patient.

The pathophysiology of Parkinson disease (PD) is characterized by derangements in the discharge rates, bursting patterns, and oscillatory activity of basal ganglia (BG) neurons. In this study, subthalamic nucleus (STN) neuronal activity patterns in humans with PD were compared with that in the normal monkey during performance of similar volitional movements. Single-unit STN recordings were collected while PD patients and animals moved a joystick in the direction of targets presented on a monitor. When discharge rates in all PD human and normal monkey neurons were compared, no significant differences were observed. However, when neurons were classified by peri-movement response type (i.e., excited, inhibited, or unresponsive to movement) statistical differences were demonstrated - most significantly among PD excited neurons. Analysis of burst activity demonstrated inter- and intra-burst activities were greater in the PD human compared to the monkey irrespective of neuronal response type. Moreover, simultaneously recorded neurons in the human demonstrated consistent oscillatory synchronization at restricted frequency bands, whereas synchronized oscillatory neurons in the monkey were not restricted to distinct frequencies. During movement, discharge and burst rates were positively correlated, independent of subject or neuronal response type; however, rates and oscillatory activity were more strongly correlated in the PD human than the normal monkey. Interestingly, across all domains of analysis, STN neurons in PD demonstrated reduced response variability when compared to STN neurons in the normal monkey brain. Thus, the net effect of PD may be a reduction in the physiological degrees of freedom of BG neurons with diminished information carrying capacity.

From symphony to cacophony: pathophysiology of the human basal ganglia in Parkinson disease.

Despite remarkable advances, the relationship between abnormal neuronal activity and the clinical manifestations of Parkinson disease (PD) remains unclear. Numerous hypotheses have emerged to explain the relationship between neuronal activity and symptoms such as tremor, rigidity and akinesia. Among these are the antagonist balance hypothesis wherein increased firing rates in the indirect pathway inhibits movement; the selectivity hypothesis wherein loss of neuronal selectivity leads to an inability to select or initiate movements; the firing pattern hypothesis wherein increased oscillation and synchronization contribute to tremor and disrupt information flow; and the learning hypothesis, wherein the basal ganglia are conceived as playing an important role in learning sensory-motor associations which is disrupted by the loss of dopamine. Deep brain stimulation (DBS) surgery provides a unique opportunity to assess these different ideas since neuronal activity can be directly recorded from PD patients. The emerging data suggest that the pathophysiologic changes include derangements in the overall firing rates, decreased neuronal selectivity, and increased neuronal oscillation and synchronization. Thus, elements of all hypotheses are present, emphasizing that the loss of dopamine results in a profound and multifaceted disruption of normal information flow through the basal ganglia that ultimately leads to the signs and symptoms of PD.

Experience with microelectrode guided subthalamic nucleus deep brain stimulation.

OBJECTIVE: Subthalamic deep brain stimulation (DBS) has rapidly become the standard surgical therapy for medically refractory Parkinson disease. However, in spite of its wide acceptance, there is considerable variability in the technical approach. This study details our technique and experience in performing microelectrode recording (MER) guided subthalamic nucleus (STN) DBS in the treatment of Parkinson disease. METHODS: Forty patients underwent surgery for the implantation of 70 STN DBS electrodes. Stereotactic localization was performed using a combination of magnetic resonance and computed tomographic imaging. We used an array of three microelectrodes, separated by 2 mm, for physiological localization of the STN. The final location was selected based on MER and macrostimulation through the DBS electrode. RESULTS: The trajectory selected for the DBS electrode had an average pass through the STN of 5.6 +/- 0.4 mm on the left and 5.7 +/- 0.4 mm on the right. The predicted location was used in 42% of the cases but was modified by MER in the remaining 58%. Patients were typically discharged on the second postoperative day. Eighty-five percent of patients were sent home, 13% required short-term rehabilitation, and one patient required long-term nursing services. Seven complications occurred over 4 years. Four patients suffered small hemorrhages, one patient experienced a lead migration, one developed an infection of the pulse generator, and one patient suffered from a superficial cranial infection. CONCLUSION: Simultaneous bilateral MER-guided subthalamic DBS is a relatively safe and well-tolerated procedure. MER plays an important role in optimal localization of the DBS electrodes.

Deep brain stimulation of the anterior internal capsule for the treatment of Tourette syndrome: technical case report.

OBJECTIVE AND IMPORTANCE: Medical treatment of Tourette syndrome is often ineffective or is accompanied by debilitating side effects, therefore prompting the need to evaluate surgical therapies. CLINICAL PRESENTATION: We present the case of a 37-year-old woman with severe Tourette syndrome since the age of 10 years. Her symptoms included frequent vocalizations and severe head and arm jerks that resulted in unilateral blindness. Trials of more than 40 medications and other therapies had failed to relieve the tics. INTERVENTION: We implanted bilateral electrodes in the anterior limb of the internal capsule, terminating in the vicinity of the nucleus accumbens. At 18-month follow-up, optimal stimulation continued to lower her tic frequency and severity significantly. CONCLUSION: Our findings suggest that stimulation of the anterior internal capsule may be a safe and effective procedure for the treatment of Tourette syndrome.

Multimodality treatment of trigeminal neuralgia.

Most trigeminal neuralgia (TN) studies focus on a single strategy, microvascular decompression (MVD) or percutaneous rhizotomy (PR). We use a multimodality approach to TN. We perform MVD on patients younger than 70 years and PR on older patients or those where MVD has failed. We performed a chart review of the procedures for TN over the past 3 years and used a questionnaire for long-term follow-up. The questionnaire asked patients to rate their pre- and postoperative pain, outcome, and medication changes. Seventy-four procedures (40 MVDs and 34 PRs) were performed on 67 patients. Twenty patients had undergone previous procedures. 93% of the patients had significant initial pain relief. Over a 1.2-year mean follow-up, 51% of the patients had complete pain relief while 27% had a substantial improvement. There were no deaths and 5 complications. Our results suggest that a multimodality approach to TN yields excellent results with minimal complications.

Visually guided movements suppress subthalamic oscillations in Parkinson's disease patients.

There is considerable evidence that abnormal oscillatory activity in the basal ganglia contributes to the pathogenesis of Parkinson's disease. However, little is known regarding the relationship of oscillations to volitional movements. Our goal was to evaluate the dynamics of oscillatory activity at rest and during movement. We performed microelectrode recordings from the subthalamic nucleus (STN) of patients undergoing deep brain stimulation surgery. During recordings, the patients used a joystick to guide a cursor to one of four targets on a monitor. We recorded 184 cells and 47 pairs of cells in 11 patients. At rest, 26 cells (14%) demonstrated significant oscillatory activity, with a mean frequency of 18 Hz. During movement, this oscillatory activity was either reduced or completely abolished in all of the cells. At rest, 18 pairs (38%) of cells in five patients exhibited synchronized oscillatory activity, with a mean frequency of 15 Hz. In 17 of the 18 pairs, both of the cells exhibited oscillations, and, in one pair, only one of the cells was oscillatory. These synchronized oscillations were also significantly decreased with movement. There was a strong inverse correlation between firing rates and oscillatory activity. As the firing rates increased with movement, there was a decrease in oscillatory activity. These findings suggest that visually guided movements are associated with a dampening and desynchronization of oscillatory activity in STN neurons. One possible explanation for these observations is that the increased cortical drive associated with movement preparation and execution leads to a transient dampening of STN oscillations, hence facilitating movement.