Brain structural connectome in relation to PRRT2 mutations in paroxysmal kinesigenic dyskinesia.

This study explored the topological characteristics of brain white matter structural networks in patients with Paroxysmal Kinesigenic Dyskinesia (PKD), and the potential influence of the brain network stability gene PRRT2 on the structural connectome in PKD. Thirty-five PKD patients with PRRT2 mutations (PKD-M), 43 PKD patients without PRRT2 mutations (PKD-N), and 40 demographically-matched healthy control (HC) subjects underwent diffusion tensor imaging. Graph theory and network-based statistic (NBS) approaches were performed; the topological properties of the white matter structural connectome were compared across the groups, and their relationships with the clinical variables were assessed. Both disease groups PKD-M and PKD-N showed lower local efficiency (implying decreased segregation ability) compared to the HC group; PKD-M had longer characteristic path length and lower global efficiency (implying decreased integration ability) compared to PKD-N and HC, independently of the potential effects of medication. Both PKD-M and PKD-N had decreased nodal characteristics in the left thalamus and left inferior frontal gyrus, the alterations being more pronounced in PKD-M patients, who also showed abnormalities in the left fusiform and bilateral middle temporal gyrus. In the connectivity characteristics assessed by NBS, the alterations were more pronounced in the PKD-M group versus HC than in PKD-N versus HC. As well as the white matter alterations in the basal ganglia-thalamo-cortical circuit related to PKD with or without PRRT2 mutations, findings in the PKD-M group of weaker small-worldness and more pronounced regional disturbance show the adverse effects of PRRT2 gene mutations on brain structural connectome.

The DYT6 Dystonia Protein THAP1 Regulates Myelination within the Oligodendrocyte Lineage.

The childhood-onset motor disorder DYT6 dystonia is caused by loss-of-function mutations in the transcription factor THAP1, but the neurodevelopmental processes in which THAP1 participates are unknown. We find that THAP1 is essential for the timing of myelination initiation during CNS maturation. Conditional deletion of THAP1 in the CNS retards maturation of the oligodendrocyte (OL) lineage, delaying myelination and causing persistent motor deficits. The CNS myelination defect results from a cell-autonomous requirement for THAP1 in the OL lineage and is recapitulated in developmental assays performed on OL progenitor cells purified from Thap1 null mice. Loss of THAP1 function disrupts a core set of OL maturation genes and reduces the DNA occupancy of YY1, a transcription factor required for OL maturation. These studies establish a role for THAP1 transcriptional regulation at the inception of myelination and implicate abnormal timing of myelination in the pathogenesis of childhood-onset dystonia.

[THE INFLUENCE OF A COMBINATION OF MODERN DRUGS NUCLEINAT AND ALFAGIN ON THE CONCENTRATION OF CIRCULATING IMMUNE COMPLEXES AND THEIR MOLECULAR COMPOSITION IN THE SERUM OF PATIENTS WITH IRRITABLE BOWEL SYNDROME ON THE BACKGROUND OF NEUROCIRCULATORY DYSTONIA IN COMPLEX MEDICAL REHABILITATION].

The effect of the combination nucleinat and alfagin in a complex of medical rehabilitation at the level of circulating immune complexes (CIC) in serum of patients and their molecular composition with irritable bowel syndrome (IBS), against neurocirculatory dystonia (NeD). It is established that the combination of nucleinat and alfagin in medical rehabilitation of patients with this comorbid disorders contributes to the normalization of the total concentration of the CEC and their molecular composition, which indicates the validity of the application of the pathogenesis combinations of drugs in complex medical rehabilitation of patients with lBS against NCD.

Thalamic involvement in paroxysmal kinesigenic dyskinesia: a combined structural and diffusion tensor MRI analysis.

Alteration of basal ganglia-thalamocortical circuit has been hypothesized to play a role in the pathophysiology underlying paroxysmal kinesigenic dyskinesia (PKD). We investigated macrostructural and microstructural changes in PKD patients using structural and diffusion tensor magnetic resonance imaging (MRI) analyses. Twenty-five patients with idiopathic PKD and 25 control subjects were prospectively studied on a 3T magnetic resonance (MR) scanner. Cortical thickness analysis was used to evaluate cortical gray matter (GM) changes, and automated volumetry and shape analysis were used to assess volume changes and shape deformation of the subcortical GM structures, respectively. Tract-based spatial statistics (TBSS) was used to evaluate white matter integrity changes in a whole-brain manner, and region-of-interest (ROI) analysis of diffusion tensor metrics was performed in subcortical GM structures. Compared to controls, PKD patients exhibited a reduction in volume of bilateral thalami and regional shape deformation mainly localized to the anterior and medial aspects of bilateral thalami. TBSS revealed an increase in fractional anisotropy (FA) of bilateral thalami and right anterior thalamic radiation in patients relative to controls. ROI analysis also showed an increase in FA of bilateral thalami in patients compared to controls. We have shown evidence for thalamic abnormalities of volume reduction, regional shape deformation, and increased FA in patients with PKD. Our novel findings of concomitant macrostructural and microstructural abnormalities in the thalamus lend further support to previous observations indicating causal relationship between a preferential lesion in the thalamus and development of PKD, thus providing neuroanatomical basis for the involvement of thalamus within the basal ganglia-thalamocortical pathway in PKD.

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.

Engineering animal models of dystonia.

Dystonia is a neurological disorder characterized by abnormal involuntary movements that are prolonged and often cause twisting and turning. Several genetically modified worms, fruit flies, and rodents have been generated as models of genetic dystonias, in particular DYT1, DYT11, and DYT12 dystonias. Although these models do not show overt dystonic symptoms, the rodent models exhibit motor deficits in specialized behavioral tasks, such as the rotarod and beam-walking tests. For example, in a rodent model of DYT12 dystonia, which is generally stress triggered, motor deficits are observed only after the animal is stressed. Moreover, in a rodent model of DYT1 dystonia, the motor and electrophysiological deficits can be rescued by trihexyphenidyl, a common anticholinergic medication used to treat dystonic symptoms in human patients. Biochemically, the DYT1 and DYT11 animal models also share some similarities to patients, such as a reduction in striatal D2 dopamine receptor and binding activities. In addition, conditional knockout mouse models for DYT1 and DYT11 dystonia demonstrate that loss of the causal dystonia-related proteins in the striatum leads to motor deficits. Interestingly, loss of the DYT1 dystonia causal protein in Purkinje cells shows an improvement in motor performance, suggesting that gene therapy targeting of the cerebellum or intervention in its downstream pathways may be useful. Finally, recent studies using DYT1 dystonia worm and mouse models led to a potential novel therapeutic agent, which is currently undergoing clinical trials. These results indicate that genetic animal models are powerful tools to elucidate the pathophysiology and to further develop new therapeutics for dystonia.

Dystonia with brain manganese accumulation resulting from SLC30A10 mutations: a new treatable disorder.

BACKGROUND: The first gene causing early-onset generalized dystonia with brain manganese accumulation has recently been identified. Mutations in the SLC30A10 gene, encoding a manganese transporter, cause a syndrome of hepatic cirrhosis, dystonia, polycythemia, and hypermanganesemia. METHODS: We present 10-year longitudinal clinical features, MRI data, and treatment response to chelation therapy of the originally described patient with a proven homozygous mutation in SLC30A10. RESULTS: The patient presented with early-onset generalized dystonia and mild hyperbilirubinemia accompanied by elevated whole-blood manganese levels. T1-sequences in MRI showed hyperintensities in the basal ganglia and cerebellum, characteristic of manganese deposition. Treatment with intravenous disodium calcium edetate led to clinical improvement and reduction of hyperintensities in brain imaging. CONCLUSIONS: We wish to highlight this rare disorder, which, together with Wilson's disease, is the only potentially treatable inherited metal storage disorder to date, that otherwise can be fatal as a result of complications of cirrhosis. © 2012 Movement Disorder Society.

Cerebellothalamocortical connectivity regulates penetrance in dystonia.

Dystonia is a brain disorder characterized by sustained involuntary muscle contractions. It is typically inherited as an autosomal dominant trait with incomplete penetrance. While lacking clear degenerative neuropathology, primary dystonia is thought to involve microstructural and functional changes in neuronal circuitry. In the current study, we used magnetic resonance diffusion tensor imaging and probabilistic tractography to identify the specific circuit abnormalities that underlie clinical penetrance in carriers of genetic mutations for this disorder. This approach revealed reduced integrity of cerebellothalamocortical fiber tracts, likely developmental in origin, in both manifesting and clinically nonmanifesting dystonia mutation carriers. In these subjects, reductions in cerebellothalamic connectivity correlated with increased motor activation responses, consistent with loss of inhibition at the cortical level. Nonmanifesting mutation carriers were distinguished by an additional area of fiber tract disruption situated distally along the thalamocortical segment of the pathway, in tandem with the proximal cerebellar outflow abnormality. In individual gene carriers, clinical penetrance was determined by the difference in connectivity measured at these two sites. Overall, these findings point to a novel mechanism to explain differences in clinical expression in carriers of genes for brain disease.

Frontotemporal and striatal SPECT abnormalities in myoclonus-dystonia: phenotypic and pathogenetic considerations.

BACKGROUND AND PURPOSE: Myoclonus-dystonia (MD) is a rare movement disorder characterized by myoclonic jerks, dystonia and a variety of psychiatric symptoms. Neuroimaging and electrophysiologic studies have not been able to detect any specific central nervous system abnormality. We report for the first time a well-characterized case with MD and abnormal brain perfusion imaging using single photon emission computed tomography (SPECT) with (99m)Tc-ethyl cysteinate dimer (ECD). A review of the literature on the phenotypic and pathogenetic considerations for MD is also presented. METHODS: To better define the functional regional central nervous system involvement in MD, we conducted a brain perfusion SPECT with (99m)Tc-ECD in a patient diagnosed with typical disease. RESULTS: Analysis of the SPECT data revealed significantly reduced regional cerebral blood flow (rCBF) in both temporal lobes (left > right and medial > lateral). Reduced rCBF was also observed in both frontal lobes and the right caudate nucleus. CONCLUSIONS: Our findings of reduced frontotemporal and striatal rCBF in the absence of other neuroimaging and electrophysiologic findings correlate well with the clinical manifestations in our patient and suggest possible functional/metabolic involvement of these areas in the etiopathogenesis of MD.

Decreased density of amygdaloid parvalbumin-positive interneurons and behavioral changes in dystonic hamsters (Mesocricetus auratus).

The dtsz hamster represents a model of primary paroxysmal nonkinesiogenic dyskinesia in which dystonic episodes can be induced by stress and anxious stimuli. This disease is regarded as a basal ganglia disorder. In fact, a deficit of striatal interneurons could play a key role in the pathophysiology in dystonic hamsters. Because the involvement of limbic structures cannot be excluded so far, the density of parvalbumin-immunoreactive (PV+) interneurons was determined in the basolateral amygdala in the present study. Compared with nondystonic hamsters, the density of PV+ interneurons was moderately decreased in the dtsz mutant. The functional consequence of this finding was examined by behavioral analyses. Examinations in the elevated plus maze and in a modified open field failed to disclose an enhanced anxiety-related behavior in dtsz hamsters (Mesocricetus auratus). A lower acoustic startle response and a stronger habituation in mutant hamsters than in controls correlated with a decreased body weight. Interestingly, prepulse inhibition was absent in mutant hamsters. The latter finding suggests a disturbed sensorimotor gating that can be related to alterations in both the basal ganglia nuclei and in limbic structures.

Effects of GPi stimulation on human thalamic neuronal activity.

OBJECTIVE: Determine the effects of globus pallidus interna (GPi) deep brain stimulation (DBS) on ventral oralis posterior nucleus of the thalamic (Vop) neuronal activity. METHODS: Microelectrode recordings in Vop during high frequency DBS GPi in a patient with dystonia. RESULTS: Twelve (48%) of 25 neurons in five locations neurons decreased their average discharge frequency, 2 (8%) increased and 11(44%) demonstrated no overall change. The patterns of responses were complex with periods of increase and decreased activity. All neurons were inhibited for the time period 3.5-5ms following the DBS pulse. Eighty-eight percent of neurons showed brief but highly consistent increases in the first 1ms following stimulation, 52% showed increased activities from 1.5 to 3ms. Twenty-four percent of neurons increased activity following inhibition. CONCLUSIONS: These findings are consistent with DBS activation of GPi axons to Vop and probable antidromic activation of Vop axons. SIGNIFICANCE: The physiological effects of DBS are far more complicated and will escape any theory that does not address the mechanisms of DBS as stimulation of a complex network of interactions. Further, the findings of post-inhibitory rebound increased raises questions about the role in inhibition in the current concepts of basal ganglia physiology.

A dominant bursting electromyograph pattern in dystonic conditions predicts an early response to pallidal stimulation.

Although chronic pallidal deep brain stimulation (DBS) is effective in the treatment of medically intractable dystonia, there is no way of predicting the variations in clinical outcome, partly due to our limited understanding of the pathophysiological mechanisms underlying this condition. We recorded electromyographic (EMG) activity from the most severely affected muscle groups in seven dystonia patients before and after pallidal DBS. Patient EMG recordings could be classified into two groups: one consisting of patients who at rest demonstrated a dominant low frequency component of activity on power spectral analysis (ranging from 2 to 5 Hz), and one group in which this dominant pattern was absent. Early postoperative improvements (within 2-3 days) were observed in the former group, whereas the latter group benefited more gradually (over several months). Analysis of EMG activity may provide a sensitive means of identifying dystonic patients who are likely to be most responsive to functional neurosurgical intervention.

Symmetrical thalamic calcifications in a monozygotic twin: case report and literature review.

We report the occurrence of symmetrical thalamic calcifications (STC) in one of a pair of monozygotic twins born at term without evidence of pre- or peri-natal asphyxia. STC is known to be an extremely rare condition in infants. Judging from the few cases reported in the literature, the clinical presentation is very severe: low Apgar score, no spontaneous movements, spasticity or marked hypotonia, impaired suck and swallow, facial diplegia. The prognosis is also very poor. The etiology is still a matter of debate: genetic, infectious, toxic or hypoxic-ischemic insults have been hypothesized. In our case, the presence of the lesion in one of a pair of monozygotic twins would rule out any genetic origin, nor was there any evidence of toxic or infectious disease. The only potential risk factor for fetal damage was hypoxic-ischemic insult related to the twin pregnancy.

Pallidal stimulation for dystonia.

The net output of the basal ganglia is tightly regulated by the activity and balance of driving and inhibitory circuitry. In pathologic states, disrupted activity in the main outflow nucleus, the globus pallidus interna (GPi), is relayed to the motor areas of the thalamus and brainstem. The behavior of these targets receiving this disrupted outflow is consequently also disrupted, which in turn produces the profound disturbances in motor function that are characteristic of parkinsonian states and certain forms of dystonia. Therapeutic efforts are directed at reversing or canceling the pathologic basal ganglia output. When drugs are ineffective or have shortcomings, surgical approaches can be considered. It is interesting and paradoxical that elimination of this abnormal activity with destruction of the motor GPi is usually well tolerated and produces little in the way of overt motor deficit. Indeed having no motor pallidum appears to be preferable to having a pallidum generating and transmitting pathologic inputs to down-stream targets. This observation brings into question the mysterious role of the GPi in normal motor function. Nevertheless, bilateral pallidal lesions can be associated with significant adverse effects including speech difficulties and cognitive disturbances. It is for this reason that neurosurgeons have sought to develop surgical procedures that offer the efficacy of selective pallidal lesions but have a better index of safety. With the introduction of DBS to treat first chronic pain and then PD, it became logical to apply DBS to treat dystonia. There is now increasing experience in the use of DBS to treat various forms of dystonia. The initial results suggest that certain primary dystonias can show a strong improvement with GPi DBS.

The effects of frequency in pallidal deep brain stimulation for primary dystonia.

The effect of stimulation frequency for pallidal deep brain stimulation in five patients with either generalized or segmental dystonia was evaluated three to twelve months postoperatively via a randomized, double-blind paradigm. The quality of life and the severity of dystonic symptoms improved by approximately 60% and 43% respectively using a frequency of 130 Hz. Compared with 130 Hz a significant further clinical improvement was observed at frequencies of 180 and 250 Hz, which contrasted with a significant deterioration at lower frequencies (5, 50 Hz) compared to 130 Hz.

Natural history of Oppenheim's dystonia (DYT1) in Israel.

The question of whether a fetus carrying the GAG deletion on the DYT1 gene responsible for Oppenheim's dystonia should be aborted is frequently raised. The objective of this study was to characterize the clinical spectrum and natural course of Oppenheim's dystonia in Israel. Thirty-three patients (19 male) with genetically confirmed Oppenheim's dystonia were evaluated. The Dystonia Rating Scale (maximum score 120) and the Disability Scale (maximum score 30) were used to score severity at the last visit. After a mean of 15.5 +/- 13.8 years of symptoms, the mean Dystonia Rating Scale and Disability Scale scores were 22.7 +/- 14.7 and 7.7 +/- 4.3, respectively. Twenty-one patients (63.6%) have progressed into generalized dystonia. Five patients (15%) are wheelchair bound and three (9%) are using walking aids. All patients have normal cognitive function. Baclofen, trihexyphenidyl, and botulinum toxin were the drugs used. Nine patients (one patient had both) underwent neurosurgical intervention: thalamotomy for six (two bilateral) and pallidotomy for four (three bilateral). The bilateral pallidotomy provided only short-term benefit. The modern treatments combining drugs, botulinum toxin, and functional neurosurgery allow most patients with Oppenheim's dystonia to have independence and a relatively good quality of life.