Indication of surgical therapy for Parkinson's disease

We review the current status of surgical treatment of Parkinson's disease (PD). The advantages of deep brain stimulation (DBS) over ablative surgery include reversibility and controllability of stimulation. In addition, DBS carries a smaller risk of side effects, especially when employed bilaterally. DBS of the thalamus is useful to control tremor which is unresponsive to medication. DBS of the globus pallidus internus (GPi) or the subthalamic nucleus (STN) is useful to control wearing off of motor symptoms which is difficult to manage with medication alone. DBS of STN and GPi improves motor function mainly during the off-period. DBS of STN attenuates levodopa-induced dyskinesia through reduction of dopa requirement, whereas DBS of GPi attenuates dopa-induced dyskinesia directly. DBS of STN is also useful to control symptoms of PD in patients who are intolerant to dopa. However, DBS of either STN or GPi cannot reverse advanced symptoms of PD, which are unresponsive to dopa.     

Network modulation by the subthalamic nucleus in the treatment of Parkinson's disease

Deep brain stimulation of the subthalamic nucleus (STN DBS) has become an accepted tool for the treatment of Parkinson's disease (PD). Although the precise mechanism of action of this intervention is unknown, its effectiveness has been attributed to the modulation of pathological network activity. We examined this notion using positron emission tomography (PET) to quantify stimulation-induced changes in the expression of a PD-related covariance pattern (PDRP) of regional metabolism. These metabolic changes were also compared with those observed in a similar cohort of patients undergoing STN lesioning. We found that PDRP activity declined significantly (P < 0.02) with STN stimulation. The degree of network modulation with DBS did not differ from that measured following lesioning (P = 0.58). Statistical parametric mapping (SPM) revealed that metabolic reductions in the internal globus pallidus (GPi) and caudal midbrain were common to both STN interventions (P < 0.01), although declines in GPi were more pronounced with lesion. By contrast, elevations in posterior parietal metabolism were common to the two procedures, albeit more pronounced with stimulation. These findings indicate that suppression of abnormal network activity is a feature of both STN stimulation and lesioning. Nonetheless, these two interventions may differ metabolically at a regional level.     

Patient-specific analysis of the relationship between the volume of tissue activated during DBS and verbal fluency

Deep brain stimulation (DBS) for the treatment of advanced Parkinson's disease involves implantation of a lead with four small contacts usually within the subthalamic nucleus (STN) or globus pallidus internus (GPi). While generally safe from a cognitive standpoint, STN DBS has been commonly associated with a decrease in the speeded production of words, a skill referred to as verbal fluency. Virtually all studies comparing presurgical to postsurgical verbal fluency performance have detected a decrease with DBS. The decline may be attributable in part to the surgical procedures, yet the relative contributions of stimulation effects are not known. In the present study, we used patient-specific DBS computer models to investigate the effects of stimulation on verbal fluency performance. Specifically, we investigated relationships of the volume and locus of activated STN tissue to verbal fluency outcome. Stimulation of different electrode contacts within the STN did not affect total verbal fluency scores. However, models of activation revealed subtle relationships between the locus and volume of activated tissue and verbal fluency performance. At ventral contacts, more tissue activation inside the STN was associated with decreased letter fluency performance. At optimal contacts, more tissue activation within the STN was associated with improved letter fluency performance. These findings suggest subtle effects of stimulation on verbal fluency performance, consistent with the functional nonmotor subregions/somatotopy of the STN.     

Subthalamic GAD gene transfer in Parkinson disease patients who are candidates for deep brain stimulation

This gene transfer experiment is the first Parkinson's Disease (PD) protocol to be submitted to the Recombinant DNA Advisory Committee. The principal investigators have uniquely focused their careers on both pre-clinical work on gene transfer in the brain and clinical expertise in management and surgical treatment of patients with PD. They have extensively used rodent models of PD for proof-of-principle experiments on the utility of different vector systems. PD is an excellent target for gene therapy, because it is a complex acquired disease of unknown etiology (apart from some rare familial cases) yet it is characterized by a specific neuroanatomical pathology, the degeneration of dopamine neurons of the substantia nigra (SN) with loss of dopamine input to the striatum. This pathology results in focal changes in the function of several deep brain nuclei, which have been well-characterized in humans and animal models and which account for many of the motor symptoms of PD. Our original approaches, largely to validate in vivo gene transfer in the brain, were designed to facilitate dopamine transmission in the striatum using an AAV vector expressing dopamine-synthetic enzymes. Although these confirmed the safety and potential efficacy of AAV, complex patient responses to dopamine augmenting medication as well as poor results and complications of human transplant studies suggested that this would be a difficult and potentially dangerous clinical strategy using current approaches. Subsequently, we and others investigated the use of growth factors, including GDNF. These showed some encouraging effects on dopamine neuron survival and regeneration in both rodent and primate models; however, uncertain consequences of long-term growth factor expression and question regarding timing of therapy in the disease course must be resolved before any clinical study can be contemplated. We now propose to infuse into the subthalamic nucleus (STN) recombinant AAV vectors expressing the two isoforms of the enzyme glutamic acid decarboxylase (GAD-65 and GAD-67), which synthesizes the major inhibitory neurotransmitter in the brain, GABA. The STN is a very small nucleus (140 cubic mm or 0.02% of the total brain volume, consisting of approximately 300,000 neurons) which is disinhibited in PD, leading to pathological excitation of its targets, the internal segment of the globus pallidus (GPi) and substantia nigra pars reticulata (SNpr). Increased GPi/SNpr outflow is believed responsible for many of the cardinal symptoms of PD, i.e., tremor, rigidity, bradykinesia, and gait disturbance. A large amount of data based on lesioning, electrical stimulation, and local drug infusion studies with GABA-agonists in human PD patients have reinforced this circuit model of PD and the central role of the STN. Moreover, the closest conventional surgical intervention to our proposal, deep brain stimulation (DBS) of the STN, has shown remarkable efficacy in even late stage PD, unlike the early failures associated with recombinant GDNF infusion or cell transplantation approaches in PD. We believe that our gene transfer strategy will not only palliate symptoms by inhibiting STN activity, as with DBS, but we also have evidence that the vector converts excitatory STN projections to inhibitory projections. This additional dampening of outflow GPi/SNpr outflow may provide an additional advantage over DBS. Moreover, of perhaps the greatest interest, our preclinical data suggests that this strategy may also be neuroprotective, so this therapy may slow the degeneration of dopaminergic neurons. We will use both GAD isoforms since both are typically expressed in inhibitory neurons in the brain, and our data suggest that the combination of both isoforms is likely to be most beneficial. Our preclinical data includes three model systems: (1) old, chronically lesioned parkinsonian rats in which intraSTN GAD gene transfer results not only in improvement in both drug-induced asymmetrical behavior (apomorphine symmetrical rotations), but also in spontaneous behaviors. In our second model, GAD gene transfer precedes the generation of a dopamine lesion. Here GAD gene transfer showed remarkable neuroprotection. Finally, we carried out a study where GAD-65 and GAD-67 were used separately in monkeys that were resistant to MPTP lesioning and hence showed minimal symptomatology. Nevertheless GAD gene transfer showed no adverse effects and small improvements in both Parkinson rating scales and activity measures were obtained. In the proposed clinical trial, all patients will have met criteria for and will have given consent for STN DBS elective surgery. Twenty patients will all receive DBS electrodes, but in addition they will be randomized into two groups, to receive either a solution containing rAAV-GAD, or a solution which consists just of the vector vehicle, physiological saline. Patients, care providers, and physicians will be blind as to which solution any one patient receives. All patients, regardless of group, will agree to not have the DBS activated until the completion and unblinding of the study. Patients will be assessed with a core clinical assessment program modeled on the CAPSIT, and in addition will also undergo a preop and several postop PET scans. At the conclusion of the study, if any patient with sufficient symptomatic improvement will be offered DBS removal if they so desire. Any patients with no benefit will simply have their stimulators activated, which would normally be appropriate therapy for them and which requires no additional operations. If any unforeseen symptoms occur from STN production of GABA, this might be controlled by blocking STN GABA release with DBS, or STN lesioning could be performed using the DBS electrode. Again, this treatment would not subject the patient to additional invasive brain surgery. The trial described here reflects an evolution in our thinking about the best strategy to make a positive impact in Parkinson Disease by minimizing risk and maximizing potential benefit. To our knowledge, this proposal represents the first truly blinded, completely controlled gene or cell therapy study in the brain, which still provides the patient with the same surgical procedure which they would normally receive and should not subject the patient to additional surgical procedures regardless of the success or failure of the study. This study first and foremost aims to maximally serve the safety interests of the individual patient while simultaneously serving the public interest in rigorously determining in a scientific fashion if gene therapy can be effective to any degree in treating Parkinson's disease.     

脑慢性深部电刺激治疗难治性帕金森病及特发性震颤

目的 应用脑慢性深部电刺激 (DBS)治疗难治性帕金森病 (PD)及特发性震颤 (ET),并对其疗效作出评价。方法 对 6例 PD患者及 2例 ET患者采用磁共振导向立体定向及术中电生理验证方法。将刺激电极分别植入丘脑腹中间核及丘脑底核,并同期植入刺激发生器。结果 6例患者术后获得了显著的疗效,震颤完全消失,肌张力恢复正常,步态、姿势明显改善,未出现任何并发症。结论 DBS作为目前最理想的手术方法治疗药物难治性 PD、 ET,具有极少副作用、可逆转性的优点,能完全控制震颤,明显改善肌张力障碍、步态、姿势等运动障碍。     

The effects of high frequency subthalamic stimulation on balance performance and fear of falling in patients with Parkinson's disease

Background  

Balance impairment is one of the most distressing symptoms in Parkinson's disease (PD) even with pharmacological treatment (levodopa). A complementary treatment is high frequency stimulation in the subthalamic nucleus (STN). Whether STN stimulation improves postural control is under debate. The aim of this study was to explore the effects of STN stimulation alone on balance performance as assessed with clinical performance tests, subjective ratings of fear of falling and posturography.     

The new Parkinson's disease drugs

The purpose of the new drugs for Parkinson's disease is control of the long-term levodopa treatment syndromes, especially wearing-off phenomenon and dyskinesia. Therefore, they show long T1/2. Most of them are classified into dopamine agonists. Others are monoamine oxidase B inhibitor and cathecole-o-methyltransferase inhibitor. Marketed dopamine agonists are bromocriptine, pergolide, talipexole, and cabergoline in Japan. Except talipexole, they are all ergot alkaloid derivatives. Their affinity for dopamine receptor is D2 group, and their T1/2 are longer than levodopa. Bromocriptine is an oldest dopamine agonist. Other 3 drugs and bromocriptine had made each other double blinded cross over trial previously. The result of double blinded studies show that their efficacy for PD treatment were equal, 40-50% patients with PD. However, in clinical usage, some difference is observed as described below. Efficacy of pergolide is strong compared with bromocriptine; however, pergolide is easy to arise dyskinesia. Talipexole is strong in the hypnosis effect. As for cabergoline, it takes long time to show medical effect, so that it is expected to control wearing-off phenomenon. Monoamine oxidase B inhibitor, Selegiline, is useful as an economizer effect to levodopa. As for the cathechole-o-methyltransferase inhibitor (COMT-I) will be make double-blinded trial in future. The efficacy for PD treatment of COMT-I is prolonged levodopa effect for PD, so that wearing-off phenomenon will be controlled. To use these drugs successfully is important with the treatment of PD. In the future, the development of the cause therapy in addition to the systematic therapy is wanted.     

Frequency-correlated decreases of motor cortex activity associated with subthalamic nucleus stimulation in Parkinson's disease

According to the classical model of basal ganglia organization, deep brain stimulation (DBS) in the subthalamic nucleus (STN) for the treatment of Parkinson's disease (PD) blocks overactive excitatory projections to inhibitory basal ganglia output structures. This would release the break on thalamofrontal neurons alleviating the poverty of movement, the hallmark of PD. Such parallels to a functional lesion certainly simplify the mechanism of STN DBS. Here, we applied parametric analyses of H2(15)O positron emission tomography (PET) scans at rest while systematically varying stimulation frequency in 6 patients with STN DBS for akinetic PD. A strong positive correlation of rCBF to increasing stimulation frequency was detected around the STN bilaterally. More importantly, we show that gradual increases in STN stimulation frequency are tightly correlated with decreases in motor cortex activity. This demonstrates an active modulation of resting activity within the subcortical stimulation target and within motor cortex by STN DBS. Rather than a possible downstream effect, we propose to consider the tight correlations between DBS frequency and motor cortex activity in the context of an upstream modulation of direct efferents to the STN from primary motor and premotor cortices.     

Topography of cortical and subcortical connections of the human pedunculopontine and subthalamic nuclei

Deep brain stimulation (DBS) of the subthalamic nucleus (STN) is the most common surgical therapy for Parkinson' s disease (PD). DBS of the pedunculopontine nucleus (PPN) is emerging as a promising surgical therapy for PD as well. In order to better characterize these nuclei in humans, we determined the anatomical connections of the PPN and STN and the topography of these connections using probabilistic diffusion tractography. Diffusion tractography was carried out in eight healthy adult subjects using diffusion data acquired at 1.5 T MRI (60 directions, b=1000 s/mm(2), 2 x 2 x 2 mm(3) voxels). The major connections that we identified from single seed voxels within STN or PPN were present in at least half the subjects and the topography of these connections within a 36-voxel region surrounding the initial seed voxel was then examined. Both the PPN and STN showed connections with the cortex, basal ganglia, cerebellum, and down the spinal cord, largely matching connections demonstrated in primates. The topography of motor and associative brain areas in the human STN was strikingly similar to that shown in animals. PPN Topography has not been extensively demonstrated in animals, but we showed significant topography of cortical and subcortical connections in the human PPN. In addition to demonstrating the usefulness of PDT in determining the connections and topography of small grey matter structures in vivo, these results allow for inference of optimal DBS target locations and add to our understanding of the role of these nuclei in PD.     

Speech motor program maintenance,but not switching,is enhanced by left-hemispheric deep brain stimulation in Parkinson's disease

Speech reaction time (SRT) was measured in a response priming protocol in 12 participants with Parkinson's disease (PD) and hypokinetic dysarthria “on” and “off” left-hemispheric deep brain stimulation (DBS). Speech preparation was measured during speech motor programming in two randomly ordered speech conditions: speech maintenance and switching. Double blind testing was completed in participants with DBS of globus pallidus pars interna (GPi) (n?=?5) or subthalamic nucleus (STN) (n?=?7). SRT was significantly faster in the maintenance vs switch task, regardless of DBS state. SRT was faster in the speech maintenance task “on” stimulation, while there was no difference in speech switching “on” and “off” DBS. These data suggest that left-hemispheric DBS may have differential effects on aspects of speech preparation in PD. It is hypothesized that speech maintenance improvements may result from DBS-induced cortical enhancements, while the lack of difference in switching may be related to inhibition deficits mediated by the right-hemisphere. Alternatively, DBS may have little influence on the higher level motor processes (i.e., motor planning) which it is believed the switch task engaged to a greater extent than the maintenance task.     

深部脑电刺激治疗帕金森病的FDGPET研究

目的研究双侧丘脑底核慢性电刺激术对晚期帕金森病患者脑局部糖代谢的影响及作用机制.方法对7例进行双侧STN DBS的晚期帕金森病患者,在术前和术后1个月电刺激条件下,分别进行18F-脱氧葡萄糖(18F-FDG)PET显像和UPDRS评分,通过SPM进行数据分析.结果 7例患者临床症状明显改善,同时FDG PET显像提示双侧豆状核、脑干、顶枕部、运动前区(BA6)及扣带回的脑代谢增加,而前额叶底部及海马的脑代谢减少(P<0.05).结论双侧STN DBS可使PD患者临床症状改善.FDG PET可作为PD进行STN治疗适应证选择的方法之一.     

Free-living energy expenditure reduced after deep brain stimulation surgery for Parkinson's disease

Background: The clinical picture in Parkinson’s disease (PD) is characterized by bradykinesia, rigidity, resting tremor and postural instability. In advanced stages of the disease, many patients will experience reduced efficacy of medication with fluctuations in symptoms and dyskinesias. Surgical treatment with deep brain stimulation in the subthalamic nucleus (STN‐DBS) is now considered the gold standard in fluctuating PD. Many patients experience a gain of weight following the surgery. The aim of this study was to identify possible mechanisms, which may contribute to body weight gain in patients with PD following bilateral STN‐DBS surgery. Methods: Ten patients with PD were studied before bilateral STN‐DBS surgery, and seven patients were studied again 3 and 12 months postoperatively. Clinical examination and resting metabolic rate with and without medical treatment was measured before and after STN‐DBS. Furthermore, free‐living energy expenditure, body composition, energy intake, peak oxygen consumption, maximal workload and leisure time physical activity were measured before and 3 and 12 months after surgery. Results: The STN‐DBS operated patients had a significant weight gain of 4·7 ± 1·6 kg (mean ± SE) 12 months postoperatively, and the weight gain was in the fat mass. The free‐living energy expenditure decreased postoperatively 13 ± 4% even though the reported dietary intake was reduced. A decreased energy expenditure took place in the non‐resting energy expenditure. The reported daily leisure time activity, peak oxygen consumption and maximal workload were unchanged. Conclusion: The STN‐DBS operated patients have a significant postoperative weight gain, as a result of a decrease in free‐living energy expenditure concomitant with an insufficient decrease in energy intake.     

Deep brain stimulation for advanced Parkinson's disease

Deep brain stimulation (DBS) is a new and promising technique for the treatment of movement disorders. Medically intractable Parkinson's disease (PD) is one of the most common indications for DBS. There are three possible subcortical targets for PD, depending on the symptomatology (i.e., the motor subdivision of the thalamus, the globus pallidus internus, the subthalamic nucleus [STN]). Thalamic stimulation has been well established as a safe and effective treatment for essential tremor and the tremor associated with PD. Globus pallidus internus and STN DBS are being investigated for the treatment of all the cardinal signs of PD. This article describes the pathophysiology of PD, the surgical treatment history of PD, surgical techniques used for DBS implants, and the role the perioperative nurse has in the care of the patients undergoing these procedures.     

Medical treatment of dyskinesia

Dyskinesia and dystonia are common complications of long-term levodopa therapy. Because peak-dose dyskinesia is due to excessive dopaminergic stimulation by anti-parkinsonian drugs, it is solved by reducing the whole dose or by taking frequent small doses of levodopa in order to keep relatively stable serum levels. It may be attenuated by dopamine receptor agonists or amantadine which acts as an N-methyl-D-aspartate (NMDA) receptor agonist. On the other hand, since early morning dystonia is related to the decline in the level of levodopa, it is initially treated by adding a small dose of levodopa in bedtime. Other patterns of dystonia are often treated accordingly to the treatment of wearing-off phenomenon.     

国内脑深部丘脑底核电刺激术治疗帕金森病的meta分析

目的应用meta分析方法,综合评价丘脑底核脑深部电刺激术(STN-DBS)治疗帕金森病(PD)的临床疗效。方法检索国内关于脑深部电刺激术(DBS)治疗PD的研究,对符合纳入标准的文献进行meta分析。结果共纳入9篇文献,总样本量为226例,其中"药物关"状态下对统一帕金森病评分量表(UPDRS)Ⅲ进行评分者226例,对UPDRSⅡ进行评分者159例。"药物开"状态下对UPDRSⅢ进行评分者156例,对UPDRSⅡ进行评分者102例。4种情况下STN-DBS前后合并指标加权均数差(WMD)及其95%CI分别为25.85(16.82~34.88)、17.28(12.37~22.18)、4.29(2.56~6.02)、3.03(0.57~5.48)。meta分析合并结果显示,"药物开"和"药物关"状态下,STN-DBS手术后UPDRSⅢ评分和UPDRSⅡ评分均比手术前显著降低,差异有统计学意义(P0.05)。结论STN-DBS用于治疗PD,能有效改善运动不能、肌肉僵直、步态不稳、姿势平衡性和肌张力障碍、异动症等。     

Probabilistic analysis of activation volumes generated during deep brain stimulation

Deep brain stimulation (DBS) is an established therapy for the treatment of Parkinson's disease (PD) and shows great promise for the treatment of several other disorders. However, while the clinical analysis of DBS has received great attention, a relative paucity of quantitative techniques exists to define the optimal surgical target and most effective stimulation protocol for a given disorder. In this study we describe a methodology that represents an evolutionary addition to the concept of a probabilistic brain atlas, which we call a probabilistic stimulation atlas (PSA). We outline steps to combine quantitative clinical outcome measures with advanced computational models of DBS to identify regions where stimulation-induced activation could provide the best therapeutic improvement on a per-symptom basis. While this methodology is relevant to any form of DBS, we present example results from subthalamic nucleus (STN) DBS for PD. We constructed patient-specific computer models of the volume of tissue activated (VTA) for 163 different stimulation parameter settings which were tested in six patients. We then assigned clinical outcome scores to each VTA and compiled all of the VTAs into a PSA to identify stimulation-induced activation targets that maximized therapeutic response with minimal side effects. The results suggest that selection of both electrode placement and clinical stimulation parameter settings could be tailored to the patient's primary symptoms using patient-specific models and PSAs.     

Adding a dopamine agonist to preexisting levodopa therapy vs. levodopa therapy alone in advanced Parkinson’s disease: a meta analysis

Background: To perform a meta analysis of randomised placebo‐controlled trials evaluating the use of dopamine agonist (DA) or placebo to preexisting levodopa therapy for the treatment of advanced Parkinson’s disease (PD). We focused on clinically important efficacy [Unified Parkinson’s Disease Rating Scale (UPDRS) activities of daily living (ADL) and motor scores as well as change in ‘off’ time and levodopa dose] and safety outcomes (withdrawal because of adverse drug events (ADEs), dyskinesias, hallucinations and mortality). Methods: A systematic literature search was performed between January 1990 and July 2007. The primary outcome measures assessed were the reduction in scores of Unified Parkinson’s Disease Rating Scale (UPDRS) activities of daily living (ADL) and motor scores as well as reduction in ‘off’ time and reductions in levodopa dose from baseline. Safety end‐points were also evaluated. Results: A total of 15 trials (n = 4380 subjects) were included in the meta analysis. Adjunctive DA use resulted in greater improvement as measured by the UPDRS ADL [weighted mean difference (WMD) ?2.20, 95% confidence interval (CI) ?2.64 to ?1.76; p < 0.0001] and motor score reduction (WMD ?5.56, 95% CI ?6.82 to ?4.31; p < 0.0001) as well as reduction in ‘off’ time measured in hours/day (WMD ?1.20, 95% CI ?1.78 to ?0.62; p < 0.0001) and reduction in levodopa dose (WMD ?128.5 mg, 95% CI ?175.0 to ?82.1; p < 0.0001) vs. placebo. Incidence of dyskinesia and hallucinations was higher with DAs [odds ratio (OR) 3.27, 95% CI 2.65–4.03; p < 0.0001] and (OR 3.34, 95% CI 2.44–4.58; p < 0.0001). Non‐ergot DAs were qualitatively better, although both ergot and non‐ergot DAs showed statistically significant improvements in all UPDRS scores. Conclusion: Adjunctive DA use to levodopa is superior to levodopa alone in reducing PD symptoms in patients not controlled with monotherapy. DAs seem especially useful amongst PD patients with wearing‐off phenomenon from levodopa therapy, but can cause some adverse events.     

Thalamic stimulation for parkinsonian tremor: correlation between regional cerebral blood flow and physiological tremor characteristics

We used (15)O-labeled water (H(2)(15)O) positron emission tomography (PET) to study eight Parkinson's disease (PD) patients with unilateral ventral intermediate (Vim) thalamic nucleus deep brain stimulation (DBS) for severe tremor. Triaxial accelerometry (TRIAX) was used during imaging to obtain on-line measures of tremor characteristics. Regional cerebral blood flow (rCBF) scans together with TRIAX recordings were collected in three stimulation conditions (OFF, MID, and ON, corresponding, respectively, to 0%, 50%, and 100% reductions in mean accelerometry signal). Statistical Parametric Mapping (SPM99) revealed significant rCBF reductions during stimulation in the ipsilateral sensorimotor cortex (SMC) and the contralateral cerebellum, as well as concurrent increases in the ipsilateral ventral thalamus (P < 0.05, corrected). Covariate analysis of rCBF with physiological tremor characteristics revealed that tremor acceleration correlated positively with changes in the SMC and supplementary motor cortex ipsilaterally (P < 0.05, uncorrected), and negatively with changes in the ipsilateral cuneus (P < 0.05, corrected). After removing tremor acceleration effects, changes in tremor frequency correlated negatively with changes in the contralateral dentate nucleus and pons (P < 0.05, uncorrected). Our results suggest that Vim DBS for PD tremor modulates the activity of cerebello-thalamo-cortical pathways. Specific tremor characteristics relate to activity in different nodes of this system.     

Effect of D1 and D2 agonists and antagonists on dyskinesia produced by L-dopa in 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine-treated monkeys.

A group of five cynomolgus monkeys was rendered parkinsonian by the toxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine and then treated daily with levodopa until all animals developed evident dyskinesia in the limbs after each dose. At this point, levodopa was replaced by selective D2 and D1 dopamine receptor agonists. All D2 agonists including quinpirole, (+)-4-propyl-9-hydroxynaphthoxazine, bromocriptine, terguride and (-)-3-(3-hydroxyphenyl)-N-n-propylpiperone reproduced the same dyskinesia, the intensity and duration of which was dose-dependent and paralleled the therapeutic effect. One D1 agonist, SFK-38393, was without effect (antiparkinsonian and dyskinetic) whereas another, CY-208243, induced antiparkinsonian at a low dose but also a dyskinetic effect at a higher dose. The effect of the selective agonists were antagonized completely by their corresponding antagonist but partially by the noncorresponding one. The effect of either D1 and D2 agonist was totally suppressed by the dopamine depleting agent alpha-methyl-p-tyrosine, but the effect was restored by a small subthreshold dose of the other (complementary) agonist. Our results thus indicate that dyskinesia cannot be ascribed solely to the D2 or the D1 receptor and that some cooperation between the two receptors appears necessary for their manifestation.     

Treatment of advanced Parkinson's disease

After the advent of levodopa, treatment of Parkinson's disease has changed and the activity of daily life of patients has been remarkably improved; whereas, many patients experience various problems such as wearing-off, dyskinesia, dystonia, neuropsychiatric problems, and dysautonomia. Especially, wearing-off and dyskinesia emerge with the change of absorptional pattern of levodopa and could be solved by regulating the timing and the dose of it. Recently, some new drugs for Parkinson's disease have been available and we physician have a wide choice of them. It is important to make a careful choice of and manipulate of doses of drugs after understanding daily life of each patient enough.