Impaired Isometric Force Matching in Upper and Lower Limbs Revealed by Quantitative Motor Assessments in Huntington's Disease.

BACKGROUND: Assessment of motor symptoms in Huntington's disease (HD) is based on the Unified-HD-Rating-Scale-Total-Motor-Score (UHDRS-TMS). Its categorical and rater-dependent nature reduces the ability to detect subtle changes and often placebo effects have been observed in trials. We have previously shown that impairments in isometric force matching can be detected by quantitative motor (Q-Motor) assessments of tongue protrusion forces (glossomotography) in HD. OBJECTIVE: We aimed to investigate whether similar impairments in isometric force matching can be detected in tasks assessing hand and foot force coordination and whether correlations with clinical measures and the disease burden score can be found. METHODS: Using a pre-calibrated force transducer, the ability of subjects to generate and maintain isometric forces at different target levels displayed on a monitor was assessed. Target forces applied in the hand were 1.5 and 5 Newton [N] and in feet 1, 5, and 10 N. Subjects with HD (n = 31) and age-matched controls (n = 22) were recruited from the HD out-patient clinic. RESULTS: All paradigms distinguished controls from HD. The static coefficient of variability (%) was the most robust measure across all matching tasks. Correlations with clinical measures, such as the UHDRS-TMS, TFC, and the DBS were found. CONCLUSIONS: Assessment of hand and foot force matching tasks was feasible and provided quantitative objective measures for severity of motor phenotype in HD. Since both upper and lower extremity motor function are relevant for everyday activities, these measures should be further assessed as candidates for developing functionally meaningful quantitative motor tasks.

Quantitative motor assessment of muscular weakness in myasthenia gravis: a pilot study.

BACKGROUND: Muscular weakness in myasthenia gravis (MG) is commonly assessed using Quantitative Myasthenia Gravis Score (QMG). More objective and quantitative measures may complement the use of clinical scales and might detect subclinical affection of muscles. We hypothesized that muscular weakness in patients with MG can be quantified with the non-invasive Quantitative Motor (Q-Motor) test for Grip Force Assessment (QGFA) and Involuntary Movement Assessment (QIMA) and that pathological findings correlate with disease severity as measured by QMG. METHODS: This was a cross-sectional pilot study investigating patients with confirmed diagnosis of MG. Data was compared to healthy controls (HC). Subjects were asked to lift a device (250 and 500 g) equipped with electromagnetic sensors that measured grip force (GF) and three-dimensional changes in position and orientation. These were used to calculate the position index (PI) and orientation index (OI) as measures for involuntary movements due to muscular weakness. RESULTS: Overall, 40 MG patients and 23 HC were included. PI and OI were significantly higher in MG patients for both weights in the dominant and non-dominant hand. Subgroup analysis revealed that patients with clinically ocular myasthenia gravis (OMG) also showed significantly higher values for PI and OI in both hands and for both weights. Disease severity correlates with QIMA performance in the non-dominant hand. CONCLUSION: Q-Motor tests and particularly QIMA may be useful objective tools for measuring motor impairment in MG and seem to detect subclinical generalized motor signs in patients with OMG. Q-Motor parameters might serve as sensitive endpoints for clinical trials in MG.

Digitomotography in Parkinson's disease: a cross-sectional and longitudinal study.

Motor symptoms in Parkinson's disease (PD) are usually assessed with semi-quantitative tests such as the Unified PD Rating Scale (UPDRS) which are limited by subjectivity, categorical design, and low sensitivity. Particularly bradykinesia as assessed e.g. with speeded index finger tapping exhibits low validity measures. This exploratory study set out to (i) assess whether force transducer-based objective and quantitative analysis of motor coordination in index finger tapping is able to distinguish between PD patients and controls, and (ii) assess longitudinal changes. Sixteen early-stage and 17 mid-stage PD patients as well as 18 controls were included in the cross-sectional part of the study; thirteen, 16 and 16 individuals of the respective groups agreed in a reassessment 12 months later. Frequency, force, rhythmicity, regularity and laterality of speeded and metronome paced tapping were recorded by digitomotography using a quantitative motor system ("Q-Motor"). Analysis of cross-sectional data revealed most consistent differences between PD patients and controls in variability of tap performance across modalities assessed. Among PD patients, variability of taps and the ability to keep a given rhythm were associated with UPDRS motor and finger tapping scores. After 12 months, laterality parameters were reduced but no other parameters changed significantly. This data suggests that digitomotography provides quantitative and objective measures capable to differentiate PD from non-PD in a small cohort, however, the value of the assessment to track PD progression has to be further evaluated in larger cohorts of patients.

Quantitative motor assessment of dyskinesias in Parkinson's disease.

Although Levodopa-induced dyskinesias (LID) are one of the most compromising complications of dopaminergic treatment in Parkinson's disease (PD), there is no widely accepted assessment tool available that evaluates LID quantitatively. This is of relevance as objective assessment may help to facilitate proof-of-concept studies with novel treatments and thus eventually contribute to better patient care. PD patients were asked to perform a grip-lift task as well as tapping tasks assessed with the "Q-Motor" system. PD patients were separated into three groups according to their modified abnormal involuntary movement scale (M-AIMS)-score: PD patients without dyskinesias (PD(LID-) n = 17), with slight dyskinesias (PD(LID+) n = 15) and with severe dyskinesias (PD(LID++) n = 15). An explorative analysis to identify measures detecting LID was performed with 5 PD(LID-) and 5 PD(LID++) patients; these measures were then used in the remaining patients to assess the accuracy of the system to differentiate LID. The measures "Orientation-Index" and "Position-Index" of the grip-lift task differed significantly between the explorative cohorts. Using these two parameters for the differentiation of the remaining cohorts, the area under the ROC curve (AUC) yielded 0.809 for the differentiation of PD(LID-) vs. PD(LID++), 0.852 for the differentiation of PD(LID-) vs. PD(LID+) patients, and 0.830 for the differentiation of PD(LID+) and PD(LID++). The "Orientation-Index" and "Position-Index" of the Q-Motor assessment are sensitive, easy to apply and non-invasive measures for the objective assessment of manifestation and severity of LID.

Neural correlates of impaired emotion processing in manifest Huntington's disease.

The complex phenotype of Huntington's disease (HD) encompasses motor, psychiatric and cognitive dysfunctions, including early impairments in emotion recognition. In this first functional magnetic resonance imaging study, we investigated emotion-processing deficits in 14 manifest HD patients and matched controls. An emotion recognition task comprised short video clips displaying one of six basic facial expressions (sadness, happiness, disgust, fear, anger and neutral). Structural changes between patients and controls were assessed by means of voxel-based morphometry. Along with deficient recognition of negative emotions, patients exhibited predominantly lower neural response to stimuli of negative valences in the amygdala, hippocampus, striatum, insula, cingulate and prefrontal cortices, as well as in sensorimotor, temporal and visual areas. Most of the observed reduced activity patterns could not be explained merely by regional volume loss. Reduced activity in the thalamus during fear correlated with lower thalamic volumes. During the processing of sadness, patients exhibited enhanced amygdala and hippocampal activity along with reduced recruitment of the medial prefrontal cortex. Higher amygdala activity was related to more pronounced amygdala atrophy and disease burden. Overall, the observed emotion-related dysfunctions in the context of structural neurodegeneration suggest both disruptions of striatal-thalamo-cortical loops and potential compensation mechanism with greater disease severity in manifest HD.

Altered resting-state connectivity in Huntington's disease.

Huntington's disease (HD) is an autosomal dominantly inherited neurodegenerative disorder characterized by motor, cognitive, and psychiatric symptoms. Using resting-state fMRI (rs-fMRI) we investigated the functional integrity of resting-state networks (RSN) in HD. 17 HD and 19 matched control participants were examined at a 3 Tesla MR scanner. After controlling for structural degeneration by means of voxel-based morphometry, task-free rs-fMRI data were analyzed using Independent Component Analysis (ICA) and a dual-regression approach in the context of genetic and clinical parameters. Further, we evaluated HD-related differences in interregional connectivity between networks. RSN analysis showed a significant increase in intrinsic functional connectivity in the HD sample compared with controls, including the thalamus, striatum, prefrontal, premotor, and parietal maps. A subset of the Default Mode Network (DMN) was also affected. In the HD cohort, motor impairment correlated with higher network connectivity in mainly motor and parietal cortices. Deteriorating total functional capacity was additionally associated with higher connectivity in the striatum, thalamus, insular and frontal areas. This pattern of increased activity in intrinsic functional networks might suggest a reduced ability of intra-network differentiation with clinical disease progression in HD. Finally, results showed reduced long-range connectivity between parietal ICA components in HD compared to controls, indicating impaired functional coupling between interregional networks in HD. Our data demonstrates that functional connectivity is profoundly altered in HD, both within and between RSN. Rs-fMRI analysis may provide additional valuable insights into neuronal dysfunctions beyond HD-related structural degeneration and disruptions of functional circuits in HD.

Intrathecal saline infusion: an emergency procedure in a patient with spontaneous intracranial hypotension.

BACKGROUND: Spontaneous intracranial hypotension (SIH) is a neurologic condition with the prototypical symptom of orthostatic headache. We report a dramatic case of SIH with life-threatening bilateral hygroma and uncal herniation. METHODS: Case report. RESULTS: A 44-year-old male patient presenting with orthostatic headache and double vision was diagnosed with SIH. Diagnostic imaging showed meningeal enhancement and bilateral hygroma. A conservative treatment regime was initiated. The patient's condition rapidly deteriorated with progressive loss of consciousness. Cranial MRI showed beginning uncal herniation. As an emergency treatment measure, an intracranial pressure (ICP) probe was inserted and intrathecal lumbal saline infusion was initiated. This led to a stabilization of ICP and allowed further diagnostics and treatment. CONCLUSION: Intrathecal lumbal saline infusion in combination with ICP monitoring can be a life-saving treatment option in unstable SIH patients.

Increased brain tissue sodium concentration in Huntington's Disease - a sodium imaging study at 4 T.

The neuropathological hallmark of the autosomal dominantly inherited, neurodegenerative disorder Huntington's disease is progressive striatal loss starting several years prior to symptom manifestation. Magnetic resonance (MR) imaging has been widely used to detect altered structure in premanifest and early Huntington's disease. Given that neurodegeneration is likely preceded by substantial neuronal dysfunction, we used in vivo sodium MR imaging, which has been shown to be sensitive to cell death and viability, to investigate cellular and metabolic integrity of Huntington's disease brain tissue. We studied a total of thirteen healthy controls and thirteen Huntington's disease gene carriers (11 manifest and 2 premanifest). The manifest Huntington's disease group was subdivided into stages 1 and 2 according to their Total Functional Capacity scores. Clinical total motor and cognitive scores, as well as calibrated sodium and T1-weighted MR images were obtained with a 4 T Siemens MR scanner. Sodium images were acquired by means of a constant time imaging technique with an ultra-short "echo time". T1-weighted MR images were further analysed with voxel-based morphometry. The absolute total sodium concentration and grey matter values were measured in several Huntington's disease-specific and also non-specific areas. Statistical analysis of variance and Pearson correlation were applied. In Huntington's disease subjects, we found an increase of total sodium concentration of the entire brain compared to controls. Increased total sodium concentration values were found in structurally affected, but also in some non-affected, regions. The highest total sodium concentration values were found in the bilateral caudate, which was associated with caudate grey matter atrophy and CAG repeat length. In all Huntington's disease subjects we further found a profound increase of total sodium concentration in the putamen, pallidum, thalamus, hippocampus, insula, precuneus and occipital cortex compared to controls. No change of total sodium concentration was observed in the amygdala, pre- and postcentral gyrus, frontal and temporal cortices or in the cerebellum. This is the first in vivo sodium MR imaging study carried out on a 4 T MR scanner in Huntington's disease gene carriers demonstrating a significant enhancement in sodium concentration in the bilateral striatum, a key region in Huntington's disease, and also in other disease-related atrophic areas. Sodium MR imaging may provide a deeper insight into the pathophysiological mechanisms of tissue degeneration in Huntington's disease, presenting potential to detect changes preceding neurodegeneration.

Inducing huntingtin inclusion formation in primary neuronal cell culture and in vivo by high-capacity adenoviral vectors expressing truncated and full-length huntingtin with polyglutamine expansion.

BACKGROUND: Huntington's disease (HD) is an inherited autosomal dominant neurodegenerative disease caused by the expansion of a CAG trinucleotide repeat in exon 1 of the huntingtin (htt) gene. Vector-mediated delivery of N-terminal fragments of mutant htt has been used to study htt function in vitro and to establish HD models in rats. Due to the large size of the htt cDNA vector-mediated delivery of full-length htt has not been achieved so far. METHODS: High-capacity adenoviral (HC-Ad) vectors were generated expressing mutant and wild-type versions of N-terminal truncated and full-length htt either in vitro in primary neuronal cells or in the striatum of mice. RESULTS: In vitro these vectors were used for transduction of primary neuronal cells isolated from E17 mouse embryos. Expression of mutant htt resulted in the formation of htt inclusions, a surrogate marker of the HD pathology. Kinetics of generation and localization of htt inclusions differed between truncated and full-length htt carrying identical mutations. Following injection into the striatum vector-mediated expression of mutant truncated htt led to prominent accumulation of htt inclusions in cell nuclei, while inclusions formed upon expression of mutant full-length htt localized to the cytoplasm. CONCLUSIONS: These results indicate that HC-Ad vector-mediated in vitro and in vivo delivery of truncated and full-length mutant htt results in prominent inclusion formation in neuronal cells but in different cell compartments. These vectors will be useful tools for studying HD and may be used to generate large animal HD models.

High-capacity adenoviral vector-mediated reduction of huntingtin aggregate load in vitro and in vivo.

Huntington's disease (HD) is an autosomal dominant neurodegenerative disease caused by the expansion of a CAG trinucleotide repeat in exon 1 of the huntingtin (htt) gene. Emergence and progression of HD depend on continuous expression of mutant Huntingtin protein (Htt). Therefore, blocking expression of mutant Htt might be a promising therapeutic strategy. We generated a high-capacity adenoviral (HC-Ad) vector expressing a short hairpin RNA (shRNA) targeted to exon 1 of the htt gene. In vitro, this vector efficiently inhibited Htt expression in neuronal and nonneuronal cell lines. In addition, the number of Htt-immunoreactive (IR) aggregates, a hallmark of HD pathology, was significantly reduced after gene transfer with this vector. Importantly, the attenuation of aggregate formation by shRNA was observed in vivo after stereotaxic injection into the striatum of mouse models of HD. The vector was tested in two models: the R6/2 transgenic mouse model and a mouse model based on the local injection of an adenoviral vector expressing a truncated version of mutant Htt. In both models an efficient reduction in mutant Htt aggregate load measured by decreased Htt-IR aggregate formation was observed. Our results support the further development of shRNA for HD therapy.

Time of transplantation and cell preparation determine neural stem cell survival in a mouse model of Huntington's disease.

Cell replacement therapies for neurodegenerative diseases, using multipotent neural stem cells (NSCs), require above all, a good survival of the graft. In this study, we unilaterally injected quinolinic acid (QA) into the striatum of adult mice and transplanted syngeneic NSCs of enhanced green fluorescent protein-transgenic mice into the lesioned striatum. The injection of QA leads to an excitotoxic lesion with selective cell death of the medium sized spiny neurons, the same cells that are affected in Huntington's disease. In order to investigate the best timing of transplantation for the survival of donor cells, we transplanted the stem cells at 2, 7 and 14 days after injury. In addition, the influence of graft preparation prior to transplantation, i.e., intact neurospheres versus dissociated cell suspension on graft survival was investigated. By far the best survival was found with the combination of early transplantation (i.e., 2 days after QA-lesion) with the use of neurospheres instead of dissociated cell suspension. This might be due to the different states of host's astrocytic and microglia activation which we found to be moderate at 2, but pronounced at 7 and 14 days after QA-lesion. We also investigated brain derived neurotrophic factor (BDNF)-expression in the striatum after QA-lesion and found no significant change in BDNF protein-level. We conclude that already the method of graft preparation of NSCs for transplantation, as well as the timing of the transplantation procedure strongly affects the survival of the donor cells when grafted into the QA-lesioned striatum of adult mice.