Abnormal Processing (abnormal + processing)

Distribution by Scientific Domains
Medical Sciences75%

Selected Abstracts

Migraine Pain and Nociceptor Activation,Where Do We Stand?

HEADACHE, Issue 5 2010
Dan Levy PhD
The mechanisms underlying the genesis of migraine pain remain enigmatic largely because of the absence of any identifiable cephalic pathology. Based on numerous indirect lines of evidence, 2 nonmutually exclusive hypotheses have been put forward. The first theorizes that migraine pain originates in the periphery and requires the activation of primary afferent nociceptive neurons that innervate cephalic tissues, primarily the cranial meninges and their related blood vessels. The second maintains that nociceptor activation may not be required and that the headache is promoted primarily as a result of abnormal processing of sensory signals in the central nervous system. This paper reviews the evidence leading to these disparate theories while siding with the primacy of nociceptor activation in the genesis migraine headache. The paper further examines the potential future use of established human models of migraine for addressing the origin of migraine headache. [source]

Role of the somatosensory system in primary dystonia

MOVEMENT DISORDERS, Issue 6 2003
Michele Tinazzi MD
Abstract The pathophysiology of dystonia is still not fully understood, but it is widely held that a dysfunction of the corticostriatal,thalamocortical motor circuits plays a major role in the pathophysiology of this syndrome. Although the most dramatic symptoms in dystonia seem to be motor in nature, marked somatosensory perceptual deficits are also present in this disease. In addition, several lines of evidence, including neurophysiological, neuroimaging and experimental findings, suggest that both motor and somatosensory functions may be defective in dystonia. Consequently, abnormal processing of the somatosensory input in the central nervous system may lead to inefficient sensorimotor integration, thus contributing substantially to the generation of dystonic movements. Whether somatosensory abnormalities are capable of triggering dystonia is an issue warranting further study. Although it seems unlikely that abnormal somatosensory input is the only drive to dystonia, it might be more correlated to the development of focal hand than generalized dystonia because local somesthetic factors are more selectively involved in the former than in the latter where, instead it seems to be a widespread deficit in processing sensory stimuli of different modality. Because basal ganglia and motor areas are heavily connected not only with somatosensory areas, but also with visual and acoustic areas, it is possible that abnormalities of other sensory modalities, such as visual and acoustic, may also be implicated in the pathophysiology of more severe forms of primary dystonia. Further studies have to be addressed to the assessment of the role of sensory modalities and their interaction on the pathophysiology of different forms of primary dystonia. © 2003 Movement Disorder Society [source]

Dystonia: A disorder of motor programming or motor execution?

MOVEMENT DISORDERS, Issue 6 2002
Petr Ka, ovský MD
Abstract For some time, dystonia has been seen as purely a motor disorder. Relatively novel concepts published approximately 10 years ago also presumed that in the development of dystonic dyskinesias, only motor behaviour was abnormal. Neurophysiological observations of various types of dystonic disorders, which were performed using sophisticated electromyography, polymyography, H-reflex examination, long-latency reflex, etc., as well as new insights into the behaviour of dystonia, have urged the inclusion of sensory (particularly somatosensory) mechanisms into the pathophysiological background of dystonia. The major role has been considered to be played by abnormal proprioceptive input by means of the Ia proprioceptive afferents, with the source of this abnormality found in the abnormal processing of muscle spindle afferent information. However, neurophysiological investigations have also provided evidence that the abnormality in the central nervous system is located not only at the spinal and subcortical level, but also at the cortical level; specifically, the cortical excitability and intracortical inhibition have been revealed as abnormal. This evidence was revealed by SEP recordings, paired transcranial magnetic stimulation recordings, and BP and CNV recordings. The current concept of dystonic movement connects the abnormal function of somatosensory pathways and somatosensory analysers with the dystonic performance of motor action, which is based on the abnormality of sensorimotor integration. © 2002 Movement Disorder Society [source]

Synthesis and Pharmacological Evaluation of 8- and 9-Substituted Benzolactam-V8 Derivatives as Potent Ligands for Protein Kinase,C, a Therapeutic Target for Alzheimer's Disease

CHEMMEDCHEM, Issue 3 2006
Ulrich
Abstract A central element in the pathophysiology of Alzheimer's disease (AD) is the formation of amyloid plaques, which result from abnormal processing of the amyloid precursor protein (APP). The processing of APP is largely provided by three key enzymes, namely the ,-, ,-, and ,-secretases. As the latter two contribute to the formation of neurotoxic A, fragments while ,-secretase does not, a decrease in the amyloidogenic products can be brought about either by inhibition of the ,- and ,-secretases or through the activation of ,-secretase. It is now known that the activation of protein kinase,C (PKC) enhances ,-secretase activity and therefore represents a possible target for the development of agents urgently needed for the treatment of this devastating neurodegenerative disorder. In the present study, new benzolactam-V8-based PKC activators were synthesized and tested for their binding affinity toward PKC,. All compounds tested showed binding values in the nanomolar concentration range. In accordance with previous publications, 9-substitution dramatically increased PKC binding affinity in comparison with the corresponding 8-substituted analogues. In addition to the location of the side chain on the aromatic ring, the binding affinities of these benzolactams were found to depend on the orientation, length, and electronic properties of this appendage. An interesting decrease in binding affinity was found for the 9-thienyl analogue 13, suggesting adverse electronic interactions of the sulfur atom with PKC or parts of the cellular membrane. [source]