Wataru Sako

Bilateral deep brain stimulation of the globus pallidus internus in tardive dystonia

Tardive dystonia is a disabling movement disorder as a consequence of exposure to neuroleptic drugs. We followed 6 patients with medically refractory tardive dystonia treated by bilateral globus pallidus internus (GPi) deep brain stimulation (DBS) for 21 ± 18 months. At last follow‐up, the Burke‐Fahn‐Marsden Dystonia Rating Scale (BFMDRS) motor score improved by 86% ± 14%, and the BFMDRS disability score improved by 80% ± 12%. Bilateral GPi‐DBS is a beneficial therapeutic option for the long‐term relief of tardive dystonia.

Differential involvement of striosome and matrix dopamine systems in a transgenic model of dopa-responsive dystonia

Dopa-responsive dystonia (DRD) is a hereditary dystonia characterized by a childhood onset of fixed dystonic posture with a dramatic and sustained response to relatively low doses of levodopa. DRD is thought to result from striatal dopamine deficiency due to a reduced synthesis and activity of tyrosine hydroxylase (TH), the synthetic enzyme for dopamine. The mechanisms underlying the genesis of dystonia in DRD present a challenge to models of basal ganglia movement control, given that striatal dopamine deficiency is the hallmark of Parkinsons disease. We report here behavioral and anatomical observations on a transgenic mouse model for DRD in which the gene for 6-pyruvoyl-tetrahydropterin synthase is targeted to render selective dysfunction of TH synthesis in the striatum. Mutant mice exhibited motor deficits phenotypically resembling symptoms of human DRD and manifested a major depletion of TH labeling in the striatum, with a marked posterior-to-anterior gradient resulting in near total loss caudally. Strikingly, within the regions of remaining TH staining in the striatum, there was a greater loss of TH labeling in striosomes than in the surrounding matrix. The predominant loss of TH expression in striosomes occurred during the early postnatal period, when motor symptoms first appeared. We suggest that the differential striosome-matrix pattern of dopamine loss could be a key to identifying the mechanisms underlying the genesis of dystonia in DRD.

Subthalamic nucleus deep brain stimulation for camptocormia associated with Parkinson's disease

Camptocormia becomes increasingly recognized as a disabling symptom associated with Parkinsons disease (PD). We here report six patients with advanced PD in whom continuous bilateral stimulation of the subthalamic nucleus produced substantial (mean 78% ± 9.1% of the thoracolumbar angle) improvement of camptocormia along with other motor symptoms.

Metabolic resting-state brain networks in health and disease

Significance We present an innovative approach to evaluate default mode network (DMN) activity in individual subjects using metabolic imaging. After characterizing a distinct set of metabolic resting state networks (RSNs) in healthy subjects, network activity was tracked over time in patients with neurodegenerative disorders, such as Parkinson’s disease and Alzheimer’s disease. We found that the dominant normal metabolic RSN, which corresponded to the DMN, is preserved in early-stage Parkinson’s disease patients. Although significant DMN reductions developed later, these changes were reversible in part by dopamine treatment. This finding contrasts with Alzheimer’s disease, in which DMN loss is rapid and continuous, beginning before clinical diagnosis. Metabolic imaging can provide a versatile, quantitative means of assessing brain disease at the network level. The delineation of resting state networks (RSNs) in the human brain relies on the analysis of temporal fluctuations in functional MRI signal, representing a small fraction of total neuronal activity. Here, we used metabolic PET, which maps nonfluctuating signals related to total activity, to identify and validate reproducible RSN topographies in healthy and disease populations. In healthy subjects, the dominant (first component) metabolic RSN was topographically similar to the default mode network (DMN). In contrast, in Parkinson’s disease (PD), this RSN was subordinated to an independent disease-related pattern. Network functionality was assessed by quantifying metabolic RSN expression in cerebral blood flow PET scans acquired at rest and during task performance. Consistent task-related deactivation of the “DMN-like” dominant metabolic RSN was observed in healthy subjects and early PD patients; in contrast, the subordinate RSNs were activated during task performance. Network deactivation was reduced in advanced PD; this abnormality was partially corrected by dopaminergic therapy. Time-course comparisons of DMN loss in longitudinal resting metabolic scans from PD and Alzheimer’s disease subjects illustrated that significant reductions appeared later for PD, in parallel with the development of cognitive dysfunction. In contrast, in Alzheimer’s disease significant reductions in network expression were already present at diagnosis, progressing over time. Metabolic imaging can directly provide useful information regarding the resting organization of the brain in health and disease.

Which target is best for patients with Parkinson's disease? A meta-analysis of pallidal and subthalamic stimulation

Background There is a growing body of evidence demonstrating that deep brain stimulation (DBS) of globus pallidus internus (GPi DBS) and subthalamic nucleus (STN DBS) are effective treatment for patients with Parkinsons disease (PD). However, it remains controversial whether the best stimulation target for a PD patient is GPi or STN. Methods A computer literature search of PubMed was carried out. We included randomised studies with direct comparison between targets. The outcome of unified PD rating scale (UPDRS) III was expressed as the standardised mean difference (SMD) between targets in baseline to endpoint change. Pooled risk ratio (RR) between targets was also used to assess adverse events. Results Four studies, comprising a total sample size of 502 PD patients (254 GPi DBS, 248 STN DBS), were included in this meta-analysis. The overall effect of GPi DBS on UPDRS III was not significantly different from STN DBS (SMD=0.19, 95% CI −0.2 to 0.58, p=0.34, four studies, n=448). This result was heterogeneous (p=0.03, I2=66%). In terms of adverse events, depression was significantly less frequent in patients with GPi DBS than STN DBS with homogeneous studies (pooled RR=0.53, 95% CI 0.31 to 0.90, p=0.02, three studies, n=479, I2=48%). Conclusions The effect of GPi DBS was similar to STN DBS except for depression, however, only three studies described depression as adverse events. We need additional randomised trials with direct comparison between targets based on unified scoring of adverse events.

Clinicopathologic features of autosomal recessive amyotrophic lateral sclerosis associated with optineurin mutation.

We performed clinicopathological analyses of two amyotrophic lateral sclerosis (ALS) patients with homozygous Q398X optineurin (OPTN) mutation. Clinically, both patients presented signs of upper and lower motor neuron degeneration, but only Patient 1 showed gradual frontal dysfunction and extrapyramidal signs, and temporal lobe and motor cortex atrophy. Neuropathological examination of Patient 1 revealed extensive cortical and spinal motor neuron degeneration and widespread degeneration of the basal ganglia. Bilateral corticospinal tracts exhibited degeneration. Loss of spinal anterior horn cells (AHCs) and gliosis were observed, whereas posterior columns, Clarkes columns, intermediate lateral columns, and the Onufs nucleus were spared. In the brainstem, moderate neuronal loss and gliosis were noted in the hypoglossal and facial motor nuclei. No Bunina bodies were found in the surviving spinal and brainstem motor neurons. Transactivation response (TAR) DNA‐binding protein 43 (TDP‐43)‐positive neuronal and glial cytoplasmic inclusions were observed throughout the central nervous system. The Golgi apparatus in motor neurons of the brainstem and spinal cord was often fragmented. Immunoreactivity for OPTN was not observed in the brain and spinal cord, consistent with nonsense‐mediated mRNA decay of OPTN. The TDP‐43 pathology of Q398X was similar to that of an autosomal dominant E478G mutation. This result suggests that the loss‐of‐function, but not the proteinopathy itself, of OPTN results in TDP‐43 deposits in neuronal and glial cytoplasm and Golgi apparatus fragmentation, leading to multisystem neurodegeneration.

Identification and localization of a neuron-specific isoform of TAF1 in rat brain: implications for neuropathology of DYT3 dystonia.

The neuron-specific isoform of the TAF1 gene (N-TAF1) is thought to be involved in the pathogenesis of DYT3 dystonia, which leads to progressive neurodegeneration in the striatum. To determine the expression pattern of N-TAF1 transcripts, we developed a specific monoclonal antibody against the N-TAF1 protein. Here we show that in the rat brain, N-TAF1 protein appears as a nuclear protein within subsets of neurons in multiple brain regions. Of particular interest is that in the striatum, the nuclei possessing N-TAF1 protein are largely within medium spiny neurons, and they are distributed preferentially, though not exclusively, in the striosome compartment. The compartmental preference and cell type-selective distribution of N-TAF1 protein in the striatum are strikingly similar to the patterns of neuronal loss in the striatum of DYT3 patients. Our findings suggest that the distribution of N-TAF1 protein could represent a key molecular characteristic contributing to the pattern of striatal degeneration in DYT3 dystonia.

Reduced alpha-synuclein in cerebrospinal fluid in synucleinopathies: Evidence from a meta-analysis

Alpha‐synuclein plays a key role in the pathology of synucleinopathies including Parkinsons disease (PD) and multiple system atrophy (MSA). However, whether alpha‐synuclein level in cerebrospinal fluid (CSF) could distinguish synucleinopathies from progressive supranuclear palsy (PSP) is still a contentious issue. A comprehensive literature search yielded nine eligible studies. We expressed the between‐group difference of the concentration of alpha‐synuclein in CSF as the standardized mean difference. The proportion of variation attributable to heterogeneity was computed and expressed as I2. Nine studies involved 537 controls, 843 PD, 130 MSA, and 98 PSP patients. The overall effect of PD on alpha‐synuclein in CSF was significantly different from normal control or disease control (standardized mean difference = –0.67, P < 0.00001). These studies were heterogeneous (I2 = 40%). Alpha‐synuclein in CSF in MSA was significantly reduced relative to controls with heterogeneous studies (standardized mean difference = –0.75, P < 0.0001; I2 = 62%). In contrast, no significant difference of alpha‐synuclein in CSF was observed between PSP and controls with heterogeneous studies (standardized mean difference = –0.28, P = 0.13; I2 = 53%). Alpha‐synuclein in CSF was significantly reduced in synucleinopathies compared with PSP (“PD vs. PSP”: standardized mean difference = –0.38, P = 0.001; “MSA vs. PSP”: standardized mean difference = –0.66, P < 0.00001). The included studies were homogeneous (I2 = 0%). Our study showed that alpha‐synuclein levels in CSF in synucleinopathies was significantly lower than in PSP. This finding provides insights into the pathophysiological difference between synucleinopathies and PSP as well as possibility of development of a tool for differential diagnosis between MSA and PSP using enzyme‐linked immunosorbent assay (ELISA) and similar methods.

Olfactory type G-protein α subunit in striosome-matrix dopamine systems in adult mice

There is a growing body of evidence that striosome-matrix dopamine systems are tightly linked with motor and behavioral brain functions and disorders. In this study, we used an immunohistochemical method to show differential expression of the olfactory type G-protein alpha subunit (Galphaolf) that involves in the coupling of dopamine D1 receptor with adenylyl cyclase in the striatal compartments of adult mice, and observed heightened density of Galphaolf labeling in the striosomes relative to the matrix compartment. Our findings suggest that Galphaolf could be one of the key molecules for controlling differential responses of the striosome and matrix compartments to dopamine D1 receptor signaling in the striatum of adult mice.

Thalamocortical Connectivity Correlates with Phenotypic Variability in Dystonia

Dystonia is a brain disorder characterized by abnormal involuntary movements without defining neuropathological changes. The disease is often inherited as an autosomal-dominant trait with incomplete penetrance. Individuals with dystonia, whether inherited or sporadic, exhibit striking phenotypic variability, with marked differences in the somatic distribution and severity of clinical manifestations. In the current study, we used magnetic resonance diffusion tensor imaging to identify microstructural changes associated with specific limb manifestations. Functional MRI was used to localize specific limb regions within the somatosensory cortex. Microstructural integrity was preserved when assessed in subrolandic white matter regions somatotopically related to the clinically involved limbs, but was reduced in regions linked to clinically uninvolved (asymptomatic) body areas. Clinical manifestations were greatest in subjects with relatively intact microstructure in somatotopically relevant white matter regions. Tractography revealed significant phenotype-related differences in the visualized thalamocortical tracts while corticostriatal and corticospinal pathways did not differ between groups. Cerebellothalamic microstructural abnormalities were also seen in the dystonia subjects, but these changes were associated with genotype, rather than with phenotypic variation. The findings suggest that the thalamocortical motor system is a major determinant of dystonia phenotype. This pathway may represent a novel therapeutic target for individuals with refractory limb dystonia.