The European journal of neuroscience
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Unilateral lengthening contractions provide a greater stimulus for neuromuscular adaptation than shortening contractions in the active and non-active contralateral homologous muscle, although little is known of the potential mechanism. Here we examined the possibility that corticospinal and spinal excitability vary in a contraction-specific manner in the relaxed right flexor carpi radialis (FCR) when humans perform unilateral lengthening and shortening contractions of the left wrist flexors at the same absolute force. Corticospinal excitability in the relaxed right FCR increased more during lengthening than shortening at 80% and 100% of maximum voluntary contraction (MVC). ⋯ The amplitude of the Hoffman reflex in the relaxed right FCR decreased during and remained depressed for 20 s after lengthening and shortening of the left wrist flexors. We discuss the possibility that instead of the increased afferent input, differences in the descending motor command and activation of brain areas that link function of the motor cortices during muscle lengthening vs. shortening may cause the contraction-specific modulation of ipsilateral motor cortical output. In conclusion, ipsilateral motor cortex responses to transcranial magnetic stimulation are contraction-specific; unilateral lengthening and shortening contractions reduced contralateral spinal excitability, but uniquely modulated ipsilateral corticospinal excitability and the networks involved in intracortical and interhemispheric connections, which may have clinical implications.
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Psychiatric and neurological diseases combined represent a considerable social and economic burden in Europe. A recent study conducted by the European Brain Council (EBC) quantified the 'cost and burden' of major brain diseases in Europe, amounting to €386bn per year. Considering that these costs will increase exponentially in the years to come due to ageing of the European population, it is necessary to act now in order to curb this increase and possibly reverse the trend. ⋯ The present document represents an update elaborated to reflect changes in research priorities and advances in brain research that have taken place since 2006. The same approach and format have been used here as in the previous version. Multinational and multidisciplinary teams have once again come together to express their views, not only on the current strengths in European research, but also on what needs to be done in priority, hoping that this update will inspire policy makers and stakeholders in directing funding for research in Europe.
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Diffuse axonal injury (DAI) is the predominant effect of severe traumatic brain injury and contributes significantly to neurological deficits. However, it is difficult to diagnose or characterize non-invasively with conventional imaging. Our study provides significant validation of a visual and statistical diffusion tensor imaging (DTI) technique as compared with pathological and electron microscopic study in a rat DAI model at multiple predilection sites and time points following trauma. ⋯ Although anatomical T2-weighted magnetic resonance images showed no abnormal signals in microscopic lesions, we detected and characterized axonal injury directly by DTI at each time point. These results demonstrate that DTI has significant potential as a non-invasive tool with which to quantitatively diagnose and evaluate microstructural injury in the experimental and clinical assessment of DAI. This method can assist in accurate evaluation of the extent of axonal injury, detection of severe predilection foci, determination of approximate time of injury, and monitoring of the pathogenic condition at the early post-injury stage.
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Several brain regions, including the primary and secondary somatosensory cortices (SI and SII, respectively), are functionally active during the pain experience. Both of these regions are thought to be involved in the sensory-discriminative processing of pain and recent evidence suggests that SI in particular may also be involved in more affective processing. In this study we used MEG to investigate the hypothesis that frequency-specific oscillatory activity may be differentially associated with the sensory and affective components of pain. ⋯ These data provide novel evidence of functional diversity within SI, indicating a role in attentional and sensory aspects of pain processing. In SII, oscillatory changes were predominantly stimulus-related, indicating a role in encoding the characteristics of the stimulus. We therefore provide objective evidence of functional heterogeneity within SI and functional segregation between SI and SII, and suggest that the temporal and frequency dynamics within cortical regions may offer valuable insights into pain processing.