Pronouns reactivate conceptual representations in human hippocampal neurons.

During discourse comprehension, every new word adds to an evolving representation of meaning that accumulates over consecutive sentences and constrains the next words. To minimize repetition and utterance length, languages use pronouns, like the word "she," to refer to nouns and phrases that were previously introduced. It has been suggested that language comprehension requires that pronouns activate the same neuronal representations as the nouns themselves. We recorded from individual neurons in the human hippocampus during a reading task. Cells that were selective to a particular noun were later reactivated by pronouns that refer to the cells' preferred noun. These results imply that concept cells contribute to a rapid and dynamic semantic memory network that is recruited during language comprehension.

White matter abnormalities in gene-positive myoclonus-dystonia.

Myoclonus-dystonia is an autosomal dominantly inherited movement disorder clinically characterized by myoclonic jerks and dystonic movements of the upper body. Functional imaging and structural gray matter imaging studies in M-D suggest defective sensorimotor integration and an association between putaminal volume and severity of dystonia, possibly because of neuronal plasticity. As we expect changes in the connections between the cortical and subcortical regions, we performed a combination of white matter voxel-based morphometry (wVBM) and diffusion tensor imaging (DTI) to detect macro- and microstructural white matter changes, respectively, in DYT-11 mutations carriers (M-D). Sixteen clinically affected DYT-11 mutation carriers and 18 control subjects were scanned with 3-Tesla MRI to compare white matter volume, fractional anisotropy, and mean diffusivity between groups. In DYT11 mutation carriers, increased white matter volume and FA and decreased mean diffusivity were found in the subthalamic area of the brain stem, including the red nucleus. Furthermore, decreased mean diffusivity was found in the subgyral cortical sensorimotor areas. The white matter changes found in the subthalamic area of the brain stem, connecting the cerebellum with the thalamus, are compatible with the hypothesis that abnormal function in M-D involves a network that includes the cerebellum, brain stem, and basal ganglia. Whether these changes are causative or an effect of M-D requires further study.

Severity of dystonia is correlated with putaminal gray matter changes in myoclonus-dystonia.

BACKGROUND: Myoclonus-dystonia (M-D) is an autosomal dominantly inherited movement disorder characterized by myoclonic jerks and dystonic postures or movements. Morphometric studies have been performed in other, mainly heterogenous, types of dystonia producing conflicting results. However, all these studies agree on abnormalities in sensorimotor structures, mainly in the basal ganglia. We aimed to study gray matter (GM) volumes in sensorimotor brain structures with magnetic resonance imaging (MRI) in a genetically homogeneous form of dystonia, M-D. METHODS: Twenty-five clinically affected DYT11 mutation carriers (MC) and 25 matched control subjects were studied using T1-weighted 3D anatomical images of the entire brain, obtained with a 3.0 Tesla MRI. MC were clinically scored using the Burke Fahn Marsden dsytonia rating scale (BFMDRS) and the unified myoclonus rating scale (UMRS). GM volumes in sensorimotor cortices and basal ganglia of patients and controls were compared, and multiple regression analyses were used to correlate the GM volumes of patients with the clinical rating scales BFMDRS and UMRS. RESULTS: No significant differences were found between groups, but dystonia severity in MC was strongly correlated with increased GM volume in bilateral putamina. CONCLUSIONS: This study provides further evidence for the involvement of putamina as important motor structures in the pathophysiology of (myoclonus-) dystonia. Changes in these structures are associated with the severity of dystonia.

Normal cortical excitability in Myoclonus-Dystonia--a TMS study.

OBJECTIVE: The aim of the present study is to investigate cortical excitability in patients with DYT 11 positive Myoclonus-Dystonia (M-D), using transcranial magnetic stimulation (TMS). METHODS: Silent period, motor evoked potential (MEP) recruitment curve, short interval intracortical inhibition (SICI), intracortical facilitation (ICF) and short interval intracortical facilitation (SICF), with short interstimulus intervals (ISIs) ranging from 1.2 to 3.2 ms, were studied in 15 DYT 11-positive M-D patients and their matched controls. In four patients and matched controls peripheral double pulse electrical nerve stimulation was performed. RESULTS: All TMS parameters of cortical excitability were normal compared to healthy controls. In the SICF protocol we observed more variable and polyphasic MEPs in M-D patients. Cross-covariance analysis of MEP area revealed a significant correlation difference at ISI 2.2 and 2.8 ms. This increased variability was not seen in other TMS protocols or with peripheral nerve stimulation. CONCLUSIONS: In contrast with other types of dystonia, no changes in cortical excitability were found in DYT 11 patients. Our findings suggest that M-D is both clinically and pathophysiologically a separate entity from other dystonic disorders. Polyphasic MEPs during the SICF protocol in M-D patients could reflect central neuron membrane instability. Application of the SICF protocol in other patient groups has to prove its value in movement disorders.