Influence of the frequency parameter on extracellular glutamate and gamma-aminobutyric acid in substantia nigra and globus pallidus during electrical stimulation of subthalamic nucleus in rats

High-frequency stimulation (HFS) of the subthalamic nucleus (STN) proves to be an efficient treatment for alleviating motor symptoms in Parkinson's disease (PD). However, the mechanisms of HFS underlying these clinical effects remain unknown. Using intracerebral microdialysis, we previously reported that HFS induces, in normal rats, a significant increase of extracellular glutamate (Glu) in the globus pallidus (GP in rats or GPe in primates) and the substantia nigra pars reticulata (SNr), whereas gamma-aminobutyric acid (GABA) was increased only in the SNr. Bradykinesia can be improved by STN stimulation in a frequency-dependent manner, a plateau being reached around 130 Hz. The aim of the present study was to determine whether neurochemical changes are also frequency dependent. Electrical STN stimulation was applied at various frequencies (10, 60, 130, and 350 Hz) in normal rats. The results show that, for Glu, the amplitude of increase detected in GP and SNr is maximal at 130 Hz and is maintained at 350 Hz. No modifications of GABA were observed in GP whatever the frequency applied, whereas, in SNr, GABA increased from 60 to 350 Hz. Our results provide new neurochemical data implicating STN target structures in deep-brain-stimulation mechanisms.     

Acute low frequency dorsal subthalamic nucleus stimulation improves verbal fluency in Parkinson's disease

BackgroundParkinson's disease (PD) is a common neurodegenerative disorder that results in movement-related dysfunction and has variable cognitive impairment. Deep brain stimulation (DBS) of the dorsal subthalamic nucleus (STN) has been shown to be effective in improving motor symptoms; however, cognitive impairment is often unchanged, and in some cases, worsened particularly on tasks of verbal fluency. Traditional DBS strategies use high frequency gamma stimulation for motor symptoms (∼130 Hz), but there is evidence that low frequency theta oscillations (5–12 Hz) are important in cognition.MethodsWe tested the effects of stimulation frequency and location on verbal fluency among patients who underwent STN DBS implantation with externalized leads. During baseline cognitive testing, STN field potentials were recorded and the individual patients’ peak theta frequency power was identified during each cognitive task. Patients repeated cognitive testing at five different stimulation settings: no stimulation, dorsal contact gamma (130 Hz), ventral contact gamma, dorsal theta (peak baseline theta) and ventral theta (peak baseline theta) frequency stimulation.ResultsAcute left dorsal peak theta frequency STN stimulation improves overall verbal fluency compared to no stimulation and to either dorsal or ventral gamma stimulation. Stratifying by type of verbal fluency probes, verbal fluency in episodic categories was improved with dorsal theta stimulation compared to all other conditions, while there were no differences between stimulation conditions in non-episodic probe conditions.ConclusionHere, we provide evidence that dorsal STN theta stimulation may improve verbal fluency, suggesting a potential possibility of integrating theta stimulation into current DBS paradigms to improve cognitive outcomes.     

Basal ganglia neural responses during behaviorally effective deep brain stimulation of the subthalamic nucleus in rats performing a treadmill locomotion test

Deep brain stimulation (DBS) of the subthalamic nucleus (STN) is an effective treatment for Parkinson's disease (PD). In spite of proven therapeutic success, the mechanism underlying the benefits of DBS has not been resolved. A multiple-channel single-unit recording technique was used in the present study to investigate basal ganglia (BG) neural responses during behaviorally effective DBS of the STN in a rat model of PD. Rats underwent unilateral dopamine (DA) depletion by injection of 6-hydroxyDA (6-OHDA) into one side of the medial forebrain bundle and subsequently developed a partial akinesia, which was assessed during the treadmill locomotion task. High frequency stimulation (HFS) of the STN restored normal treadmill locomotion behavior. Simultaneous recording of single unit activity in the striatum (STR), globus pallidus (GP), substantia nigra pars reticulata (SNr), and STN revealed a variety of neural responses during behaviorally effective HFS of the STN. Predominant inhibitory responses appeared in the STN stimulation site. Nearly equal numbers of excitatory and inhibitory responses were found in the GP and SNr, whereas more rebound excitatory responses were found in the STR. Mean firing rate did not change significantly in the STR, GP, and SNr, but significantly decreased in both sides of STN during DBS. A decrease in firing rate in the contralateral side of STN provides neural substrate for the clinical observation that unilateral DBS produces bilateral benefits in patients with PD. In addition to the firing rate changes, a decrease in burst firing was observed in the GP and STN. The present study indicates that DBS induces complex modulations of the BG circuit and further suggests that BG network reorganization, rather than a simple excitation or inhibition, may underlie the therapeutic effects of DBS in patients with PD.     

Pedunculopontine nucleus deep brain stimulation changes spinal cord excitability in Parkinson’s disease patients

Bilateral peduncolopontine nucleus (PPN) and subthalamic nucleus (STN) deep brain stimulation (DBS) was performed in six-advanced Parkinson’s disease (PD) patients. We report the effect of both PPN-DBS (25 Hz) and STN-DBS (185 Hz) on patient spinal reflex excitability by utilizing the soleus-Hoffman reflex (HR) threshold. Compared to controls (n = 9), patients showed an increase of HR-threshold, which was scarcely affected by levodopa, but significantly reduced by DBS. In particular, we found that PPN-DBS alone, or plus STN-DBS induced a complete recovery of HR-threshold up to control values. The HR-threshold changes, although do not allow to investigate the contribution of specific intraspinal pathways, suggest that PPN may play a key-role in modulating spinal excitability in PD possibly by improving the basal ganglia-brainstem descending system activity.     

帕金森病脑深部电刺激术治疗的术后药物调整与程控配合

目的分析丘脑底核-脑深部电刺激术(STN-DBS)治疗帕金森病患者的术后程控工作及相关情况,为STN-DBS术后刺激参数的设置、药物的调整提供参考依据。方法病例选自2005年3月至2006年12月在北京天坛医院接受双侧STN-DBS植入术治疗的57例帕金森病患者。分析手术前后药物的用量和调整情况,评估不同刺激参数对震颤、运动徐缓和僵直等PD运动症状的改善作用。结果与术前相比PD患者DBS术后服用多巴胺类药物的剂量明显减少,术前平均707.59mg,术后平均253.62mg,平均减少63%,其中8例不再服用左旋多巴类药物。刺激频率为10Hz时无治疗作用,130Hz以上时症状可得到显著改善。除3例发生对侧肢体痉挛性收缩外,频率达到185Hz时能够获得最佳治疗效果。电压为2V-3V时可较好的改善运动,并随着电压值的增加治疗作用逐渐增强。结论本研究证实STN-DBS是一种安全、有效的治疗帕金森病的方法,STN-DBS能够显著减少左旋多巴类药物用量及药物引起的异动症、运动波动等并发症的发生。刺激电压是术后程控的主要调节参数。     

Frequency matters: beta‐band subthalamic nucleus deep‐brain stimulation induces Parkinsonian‐like blink abnormalities in normal rats

The synchronized beta‐band oscillations in the basal ganglia‐cortical networks in Parkinson's disease (PD) may be responsible for PD motor symptoms or an epiphenomenon of dopamine loss. We investigated the causal role of beta‐band activity in PD motor symptoms by testing the effects of beta‐frequency subthalamic nucleus deep‐brain stimulation (STN DBS) on the blink reflex excitability, amplitude, and plasticity in normal rats. Delivering 16 Hz STN DBS produced the same increase in blink reflex excitability and impairment in blink reflex plasticity in normal rats as occurs in rats with 6‐hydroxydopamine lesions and patients with PD. These deficits were not an artifact of STN DBS because, when these normal rats received 130 Hz STN DBS, their blink characteristics were the same as without STN DBS. To demonstrate that the blink reflex disturbances with 16 Hz STN DBS were frequency specific, we tested the same rats with 7 Hz STN DBS, a theta‐band frequency typical of dystonia. In contrast to beta stimulation, 7 Hz STN DBS exaggerated the blink reflex plasticity as occurs in focal dystonia. Thus, without destroying dopamine neurons or blocking dopamine receptors, frequency‐specific STN DBS can be used to create PD‐like or dystonic‐like symptoms in a normal rat.     

Selective deep brain stimulation in the substantia nigra reduces myoclonus in progressive myoclonic epilepsy: a novel observation and short review of the literature

We report the case of a patient suffering from pharmacotherapy‐resistant bilateral progressive myoclonic epilepsy (PME) showing a beneficial response upon selective deep brain stimulation (DBS) of the substantia nigra pars reticulata. As an individual experimental therapeutic approach, we implanted DBS electrodes in the transitional zone between the subthalamic nucleus (STN) and the substantia nigra pars reticulata (SNr). Electrode placement allowed for a selective stimulation of either the STN, SNr, or both targets. Postoperatively, we observed a moderate subjective and objective improvement in positive and negative myoclonus by high‐frequency DBS of the STN/SNr transitional zone. However, a systematic exploration of different stimulation settings revealed that monopolar stimulation of the substantia nigra alone was more effective than high‐frequency monopolar DBS of either the motor STN (monopolar) or stimulation of both targets (STN/SNr). This observation confirms earlier findings showing that patients with PME benefit from high‐frequency DBS. However, in contrast to previous reports stimulating the STN/SNr transitional zone, our patient showed the most significant effect upon selective stimulation of the SNr. We propose that in patients undergoing DBS for myoclonus, at least one electrode contact should be placed in the SNr allowing for selective monopolar stimulation of this target.     

Levodopa response in long-term bilateral subthalamic stimulation for Parkinson's disease.

Subthalamic nucleus deep brain stimulation (STN-DBS) is effective in advanced Parkinson's disease (PD), but its effects on the levodopa response are unclear. We studied the levodopa response after long-term STN-DBS, STN-DBS efficacy and predictive value of preoperative levodopa response to long-term DBS benefit in 33 PD patients with bilateral STN-DBS. Patients were assessed using the Unified Parkinson's Disease Rating Scale preoperatively (with and without medications) and postoperatively (without medications or stimulation, with only medications or stimulation, and with both medications and stimulation). Levodopa response significantly decreased postoperatively by 31.1% at 3 years and 32.3% at 5 years, possibly related to the reduction in medication requirement, direct STN stimulation effect or PD progression. STN-DBS alone significantly improved motor scores (37.2% at 3 years and 35.1% at 5 years) and activities of daily living scores (27.1% at 3 years and 19.2% at 5 years). Anti-PD drugs were significantly reduced by 47.9% at 3 years and 39.8% at 5 years. However, the magnitude of the preoperative response to levodopa did not predict DBS benefit at 3 and 5 years.     

丘脑底核电刺激对大鼠黑质网状部及苍白球细胞外神经递质的影响

目的 通过电刺激正常及癫痫大鼠丘脑底核(STN),研究黑质网状部(SNr)及苍白球(GP)细胞外液中谷氨酸(Glu)、γ-氨基丁酸(GABA)的变化,探讨电刺激治疗癫痫的机制.方法 正常大鼠和癫痫大鼠各加只,将刺激电极植入一侧STN,分别用130 Hz和260 Hz进行刺激,同时在同侧的SNr和GP收集细胞外液,用高压液相色谱法检测其Glu和GABA的含量.结果 癫痫大鼠SNr的GABA基础值明显高于正常大鼠.电刺激使两组SNr的GABA明显升高.130 Hz和260 Hz刺激明显增高两组GP和SNr的Glu含量,但130 Hz的更显著.结论 SNr细胞外GABA升高在STN电刺激治疗中起重要作用.电刺激增加了GP细胞的活动,STN电刺激治疗癫痫机制不能单纯解释为"功能的毁损".     

Effective inhibition of substantia nigra by deep brain stimulation fails to suppress tonic epileptic seizures

Experimental and clinical data suggest that high-frequency deep brain stimulation (DBS) of different subcortical structures can be used to control or modulate epileptic seizures. Recent studies showed that DBS of the substantia nigra reticulata (SNr) in rats has an anticonvulsant effect on forebrain clonic seizures. The aim of this study was to determine whether DBS of SNr could also suppress tonic epileptic seizures evoked in hindbrain structures. DBS with high frequency often mimics the effects of surgical ablation of a particular area of the brain. However, the optimal parameters of DBS stimulation to induce ablation-like effects on seizures are not well defined. Consequently, in the first experiment we examined the effects of different stimulation frequencies (80, 130, 260 and 390 Hz) on neuronal activation induced in SNr, using c-fos immunocytochemistry. The results showed that the stimulation of the SNr with 80 Hz has no inhibitory effect while stimulation with 130, 260 and 390 Hz produced a remarkable suppressive effect compared with the control unstimulated side. The aim of the second experiment was to determine whether bilateral inhibition of SNr with DBS could suppress tonic seizures induced by electric shock. Statistical analysis showed that the mean tonic seizure scores following SNr stimulation with either 130 or 260 Hz were not significantly different from scores following the application of the electrode without current. The data suggest that DBS of the SNr produces neuronal inhibition but fails to suppress tonic seizures. We conclude, therefore, that DBS of SNr with frequencies used in this study might not be effective for treatment of patients who suffer from tonic epileptic seizures.     

Subthalamic local field potentials after seven-year deep brain stimulation in Parkinson's disease

Studies describing subthalamic (STN) local field potentials (LFPs) recorded during deep brain stimulation (DBS) in patients with Parkinson's disease (PD), within the first month after DBS electrode implant, show that DBS modulates specific STN oscillations: whereas low-frequency (LF) oscillations (2-7Hz) increase, beta oscillations (8-30Hz) variably decrease. No data show whether LFPs remain stable for longer than one month after DBS surgery. Having long-term information is essential especially for use as a long-term feedback control signal for adaptive DBS systems. To evaluate how STN activity behaves years after prolonged chronic stimulation in PD we studied STN LFPs at rest without DBS and during ongoing DBS, in 11 parkinsonian patients 7years (7.54±1.04) after STN electrode implantation for DBS (hyperchronic group) and in 16 patients 3days after STN electrode implantation (acute group). STN LF and beta-band LFPs recorded at rest at 7years contained almost the same information as those recorded at 3days. STN recordings showed similar LFP responses to DBS in the acute and hyperchronic stages: whereas during ongoing DBS the LF power band increased for the whole population, beta activity decreased only in nuclei with significant beta activity at baseline. The LF/beta power ratio in all nuclei changed in both study groups, suggesting that this variable might be an even more informative marker of PD than the single LF and beta bands. Because STN LFP activity patterns and STN LFP responses to DBS stay almost unchanged for years after DBS electrode implantation they should provide a consistent feedback control signal for adaptive DBS.     

Persistent synaptic inhibition of the subthalamic nucleus by high frequency stimulation

BackgroundDeep brain stimulation (DBS) provides symptomatic relief in a growing number of neurological indications, but local synaptic dynamics in response to electrical stimulation that may relate to its mechanism of action have not been fully characterized.ObjectiveThe objectives of this study were to (1) study local synaptic dynamics during high frequency extracellular stimulation of the subthalamic nucleus (STN), and (2) compare STN synaptic dynamics with those of the neighboring substantia nigra pars reticulata (SNr).MethodsTwo microelectrodes were advanced into the STN and SNr of patients undergoing DBS surgery for Parkinson's disease (PD). Neuronal firing and evoked field potentials (fEPs) were recorded with one microelectrode during stimulation from an adjacent microelectrode.ResultsInhibitory fEPs could be discerned within the STN and their amplitudes predicted bidirectional effects on neuronal firing (p = .013). There were no differences between STN and SNr inhibitory fEP dynamics at low stimulation frequencies (p > .999). However, inhibitory neuronal responses were sustained over time in STN during high frequency stimulation but not in SNr (p < .001) where depression of inhibitory input was coupled with a return of neuronal firing (p = .003).InterpretationPersistent inhibitory input to the STN suggests a local synaptic mechanism for the suppression of subthalamic firing during high frequency stimulation. Moreover, differences in the resiliency versus vulnerability of inhibitory inputs to the STN and SNr suggest a projection source- and frequency-specificity for this mechanism. The feasibility of targeting electrophysiologically-identified neural structures may provide insight into how DBS achieves frequency-specific modulation of neuronal projections.     

80 Hz versus 130 Hz subthalamic nucleus deep brain stimulation: Effects on involuntary movements

BackgroundSubthalamic Nucleus Deep Brain Stimulation (STN-DBS) represents a valid therapeutic option for advanced Parkinson's disease (PD), leading to a significant amelioration of motor fluctuations and levodopa-induced involuntary movements (IM). This study address the issue of whether stimulation frequency may influence the control of IM in STN-DBS treated patients, comparing the effects of 80 Hz and 130 Hz STN-DBS frequencies in 10 parkinsonian patients with residual IM (dyskinesia in 6 cases and dystonia in 4 cases).MethodsPatients were evaluated by means of the Rush Dyskinesias Rating Scale (blinded-video analysis) and Unified Parkinson's Disease Rating Scale at 4 different time-points: baseline, shortly after the switch of stimulation frequency from 130 Hz to 80 Hz, after 1 month and 12 months of chronic 80 Hz stimulation.ResultsIM improved in most subjects after the switch of stimulation frequency: dyskinesias improved in 6/6 subjects and dystonic features in 3/4 subjects after one month of 80 Hz stimulation. However, the 130 Hz STN stimulation was restored in 4 subjects during the following months, because of a gradual worsening of parkinsonian symptoms. A sustained efficacy on motor features and IM was observed with 80 Hz stimulation frequency in the remaining patients.ConclusionsIn this limited cohort of STN-DBS patients, we observed an improvement of residual IM after the switch of stimulation frequency from 130 Hz to 80 Hz. However, a moderate worsening of parkinsonian symptoms was observed in a portion of patients, requiring to return at 130 Hz STN-DBS.     

Frequency-dependent reciprocal modulation of verbal fluency and motor functions in subthalamic deep brain stimulation

BACKGROUND: High-frequency deep brain stimulation (DBS) of the subthalamic nucleus (STN) improves motor functions in those with Parkinson disease but may worsen frontal functions such as verbal fluency (VF). In contrast, low-frequency DBS leads to deterioration of motor functions. It is not known whether low-frequency STN DBS also has an effect on frontal functions. OBJECTIVE: To examine whether low-frequency STN DBS in contrast to high-frequency STN DBS has a positive effect on frontal functions on the basis of VF test results. DESIGN: A double-blind randomized crossover experiment to compare performance in 4 VF subtests and motor performance at 10 Hz, 130 Hz, and no stimulation. SETTING: University hospitals in Düsseldorf and Cologne, Germany. PATIENTS: Twelve patients with Parkinson disease 3 months or more after bilateral electrode implantation into the STN. MAIN OUTCOME MEASURE: Mean number of words in VF at different stimulation frequencies. RESULTS: The VF was significantly better at 10 Hz (48.3 words) compared with 130 Hz and showed a nonsignificant trend toward worsening at 130 Hz (42.3 words) compared with no stimulation (43.8 words). These results were consistent across all subtests. CONCLUSIONS: The study provides evidence of a beneficial effect of low-frequency (10 Hz) STN DBS on VF, which may be caused by activating neural pathways projecting to the frontal cortex. In addition, the study reproduces the negative effect of therapeutic high-frequency STN DBS on VF. The study results provide evidence for a frequency-dependent modulation of cognitive circuits involving the STN.     

Effects of Subthalamic Deep Brain Stimulation With Different Frequencies in a Parkinsonian Rat Model

ObjectiveSubthalamic deep brain stimulation (STN-DBS) could be an effective alternative treatment for patients with Parkinson’s disease (PD). However, the mechanisms of deep brain stimulation (DBS) at different frequencies are still unclear. In this study, diffusion tensor imaging (DTI) was used to detect parameter changes in different regions of rat brains after DBS, and rat exercise capacity and brain tissue immunohistochemistry were evaluated.Materials and MethodsThe 6-hydroxydopamine-induced hemi-parkinsonian rat models were made and divided into four groups: a control group, sham group, low-frequency group, and high-frequency group. Low-frequency (30 Hz) and high-frequency (130 Hz) DBS were given to the STN in rats. First, an open-field experiment was used to evaluate changes in exercise performance. Then, the DTI was used to measure parameter changes in the substantia nigra (SN). Finally, immunohistochemistry was used to analyze the expression of tyrosine hydroxylase (TH), NeuN, and α-synuclein (α-syn) in the SN in the rats.ResultsThere were significant differences in movement distance changes between the high-frequency stimulation (HFS) group and low-frequency stimulation (LFS) group, the HFS group and Ctrl group, and the Sham group and Ctrl group (all p < 0.05) after one week of stimulation. In the HFS group, the fractional anisotropy value of the SN was significantly higher than that of the other groups (p < 0.05), and the apparent diffusion coefficient and radial diffusion coefficient values were significantly lower than those of the other groups (p < 0.01). Immunohistochemical analysis showed that the integral optical density values of SN TH staining (p < 0.01) and NeuN staining (p < 0.05) in the HFS group were both significantly higher than those in the other groups.ConclusionSTN-HFS (130 Hz) and sham operation for one week can significantly improve the exercise performance of PD rats. The exercise performance of PD rats in LFS group (30 Hz) is worse compared with HFS group (130 Hz). HFS plays a role in neuroprotection and improvement of exercise performance of PD rats. Moreover, DTI can be used as an effective technique to assess the therapeutic effects and severity of PD.     

Subthalamic nucleus stimulation in Parkinson''s disease: Postoperative CT–MRI fusion images confirm accuracy of electrode placement using intraoperative multi-unit recording

Deep brain stimulation (DBS) of the subthalamic nucleus (STN) is increasingly used to treat advanced Parkinson's disease (PD). The optimal method for targeting the STN before implanting the definitive DBS electrode is still a matter of debates. Beside methods of direct visualization of the nucleus based on stereotactic magnetic resonance imaging (MRI), the most often used technique for targeting STN consists in recording single-cell activity along exploratory tracks of 10-15mm in length, centered on the theoretical or MRI-defined target coordinates. Single-unit recordings with a microelectrode present various drawbacks. They are time-consuming if correctly performed and a single-cell precision is probably superfluous, taking into account the size of the implanted electrode. In this study, we present an original method of recording and quantification of a multi-unit signal recorded intraoperatively with a semi-microelectrode for targeting the STN. Twelve patients with advanced PD have been included and assessed clinically before and one year after bilateral STN-DBS electrode implantation guided by multi-unit electrophysiological recordings. After one year of chronic stimulation, all patients showed a marked clinical improvement. The motor score of the unified Parkinson's disease rating scale decreased by more than 57% and the required levodopa-equivalent daily dose by 59.5% in on-stimulation off-medication condition compared to off-stimulation off-medication condition. The accuracy of STN-DBS lead placement was confirmed on postoperative computed tomography (CT) scans, which were fused to preoperative T2-weighted MRI. The boundaries of the STN were easily determined by an increase in multi-unit signal amplitude, which was observed on average from 0.492mm below the rostral border of the STN down to 0.325mm above its caudal border. Signal amplitude significantly increased at the both rostral and caudal STN margins (P<0.05) and the level of neuronal activity easily distinguished inside from outside the nucleus. This study showed that STN boundaries could be adequately determined on the basis of intraoperative multi-unit recording with a semi-microelectrode. The accuracy of our method used for positioning DBS electrodes into the STN was confirmed both on CT-MRI fusion images and on the rate of therapeutic efficacy.     

Aggressive behavior as a rare side effect of subthalamic stimulation in Parkinson’s disease

Although deep brain stimulation (DBS) has a well-established position in the treatment of Parkinson’s disease (PD), it may be accompanied by different side effects including behavioral changes. We present a patient with advanced PD after bilateral stimulation of the subthalamic nucleus (STN) who developed attacks of aggressive behavior. The patient with a 12 year history of PD underwent the procedure of DBS with one-stage bilateral stereotactic approach using the Leksel G stereotactic frame. For STN identification microrecording technique was applied (5 microelectrodes). Four weeks after surgery STN stimulation was switched on. With increasing the amplitude of stimulation on the right (active contacts 1 and 2) the patient experienced transient episodes of aggression. Change of stimulation mode led to withdrawal of all side effects. We hypothesize that aggression episodes in the patient were caused by stimulation of limbic circuit probable within STN although we cannot exclude simultaneous stimulation of neighboring structures. Aggression episodes are rare side effect of STN-DBS, nevertheless they may be expected in more posteromedial placement of the electrode within STN. The presented case extends the evidence for non-motor functions of STN and highlights its role as an integrating structure within the basal ganglia system.     

Low frequency subthalamic stimulation and event-related potentials in Parkinson disease

BackgroundHigh frequency (130 Hz) subthalamic Deep-Brain-Stimulation (STN-DBS) optimally improves cardinal motor symptoms in Parkinson disease (PD). Low stimulation frequencies (60–80 Hz) improve axial symptoms in some patients and, according to preliminary evidences, may also have a beneficial effect on the cognitive component of motor planning.ObjectiveTo analyze the configuration of the P300 component of cortical event-related auditory potentials (ERPs), a reliable index of attentive cognitive functions, at different stimulation frequencies in STN-DBS in PD patients.Methods12 PD patients underwent ERPs recordings using a standard oddball auditory paradigm with STN-DBS at 60 Hz, 80 Hz, 130 Hz, and OFF-stimulation, applied in a randomized double-blind sequence. ERPs analysis considered the peak amplitude and latency of the P300 components at midline electrode positions (Fz, Cz, Pz).ResultsP300 latency over Cz and Pz electrodes significantly increased with STN-DBS at 130 Hz compared to OFF-stimulation. P300 latency was also significantly increased, though to a lesser degree, over Pz electrode with stimulation at 80 Hz. No significant P300 latency modifications were detected at 60 Hz stimulation compared to OFF-stimulation condition. P300 amplitude did not change significantly for any of the stimulation conditions tested.ConclusionsLow frequency STN-DBS is associated with minor modifications of P300 latency compared to conventional stimulation at 130 Hz, possibly suggesting that 60 and 80 Hz may have less interference with attentive and cognitive processes in PD patients.     

多通道微电极记录在帕金森病脑深部电刺激定位中的作用

目的丘脑底核(STN)是帕金森病(PD)脑深部电刺激(DBS)治疗的主要靶点,使用多通道微电极记录可以准确地发现STN的感觉运动区,提高治疗精准度,提高DBS治疗效果;但多通道微电极记录的方法和风险目前介绍的比较少。现通过10例帕金森病STN-DBS手术中应用多通道微电极记录的方法,探讨多通道微电极记录的精准定位作用与风险。方法 2012年10月至2013年5月10例帕金森病患者在STNDBS手术中,应用多通道微电极记录(4~5个通道),同步使用评分法记录,结合宏电极刺激结果,选择最终置入刺激电极的通道,比较术前预设的放置靶点与最终放置靶点的不同,测量通道的长度。结果不同的通道显示了不同的神经元放电模式以及其放电的强度与长度。比较最后电极植入通道与术前的预设中心靶点显示:左侧STN:放置中心位置6例,非中心4例,其中前方2例,外侧1例,内侧1例;右侧STN:中心位置5例,非中心5例,其中外侧4例,内侧1例,STN感觉运动区的通道长度:左侧STN感觉运动区信号长度为(4.85±1)mm(3~6 mm),右侧STN感觉运动区信号长度为(4.83±0.7)mm(4~6 mm)。10例患者手术中未见出血并发症。结论 10例患者中选择预设靶点即中心靶点的比例只有50%~60%,有40%~50%的患者最终放置植入电极的位置与预设的靶点不同。多通道微电极记录可以覆盖整个STN,通过记录其电信号并分析比较,可以准确显示出STN的运动区域,选择最佳的通道植入电极,提高DBS治疗的效果;未见明显的出血并发症。因此多通道微电极记录是DBS手术中一种可以提高精准定位,同时也非常安全有效监测的方法。     

Intra-operative STN DBS attenuates the prominent beta rhythm in the STN in Parkinson's disease

Power spectra from local field potentials (LFPs) recorded post-operatively from the deep brain stimulation (DBS) macroelectrode show prominence of the beta rhythm (11-30 Hz) in untreated Parkinson's disease (PD). Dopaminergic medication and movement attenuate this beta band in PD. In this pilot study of six sides in four patients, we recorded LFPs from the DBS electrode in untreated PD patients in the operating room. In all cases, there was a peak in the time-frequency spectrogram in the beta frequency range when the patients were at rest, which was associated with attenuation in the same range with movement. The actual frequency range and the strength of the beta peak varied among cases. In two patients, intra-operative constraints permitted recording of LFPs at rest, before and immediately after subthalamic nucleus (STN) DBS. In both patients we documented that STN DBS caused a significant attenuation in power in the beta band at rest that persisted for 15-25 s after DBS had been turned off (P < 0.01). From one case, our data suggest that the beta rhythm attenuation was most prominent within the STN itself. This study shows for the first time that STN DBS attenuates the power in the prominent beta band recorded in the STN of patients with PD. These pilot findings raise the interesting possibility of using this biomarker for closed loop DBS or neuromodulation.