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Query: UMLS:C0848771 (
neurological disability
)
928
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Axonal degeneration within the spinal cord contributes substantially to
neurological disability
in multiple sclerosis (MS). Thus neuroprotective therapies that preserve axons, so that they maintain their integrity and continue to function, might be expected to result in improved neurological outcome.
Sodium
channels are known to provide a route for
sodium
influx that can drive calcium influx, via reverse operation of the Na+/Ca2+ exchanger, after injury to axons within the CNS, and sodium channel blockers have been shown to protect CNS axons from degeneration after experimental anoxic, traumatic, and nitric oxide (NO)-induced injury. In this study, we asked whether phenytoin, which is known to block
sodium
channels, can protect spinal cord axons from degeneration in mice with experimental allergic encephalomyelitis (EAE), which display substantial axonal degeneration and clinical paralysis. We demonstrate that the loss of dorsal corticospinal tract (63%) and dorsal column (cuneate fasciculus; 43%) axons in EAE is significantly ameliorated (corticospinal tract: 28%; cuneate fasciculus: 17%) by treatment with phenytoin. Spinal cord compound action potentials (CAP) were significantly attenuated in untreated EAE, whereas spinal cords from phenytoin-treated EAE had robust CAPs, similar to those from phenytoin-treated control mice. Clinical scores in phenytoin-treated EAE at 28 days were significantly improved (1.5, i.e., minor righting reflex abnormalities) compared with untreated EAE (3.8, i.e., near-complete hindlimb paralysis). Our results demonstrate that phenytoin has a protective effect in vivo on spinal cord axons, preventing their degeneration, maintaining their ability to conduct action potentials, and improving clinical status in a model of neuroinflammation.
...
PMID:Phenytoin protects spinal cord axons and preserves axonal conduction and neurological function in a model of neuroinflammation in vivo. 1290 34
Multiple Sclerosis is the most common inflammatory demyelinating disease of the central nervous system and is the leading cause of non traumatic
neurological disability
in young adults. In recent years it has become increasingly evident that axonal degeneration is a key player in the pathogenesis of disability in MS but the mechanisms that lead to axonal damage are not fully understood. It seems likely that the causes of axonal damage vary at different stages of the disease and several theories have evolved that address the mechanisms leading to axonal loss in the acute stages of demyelination. There has been relatively little attention given to investigation of the mechanisms involved in chronic axonal loss in the progressive stages of MS. We propose a hypothesis that mitochondria play a key role in this chronic axonal loss. Following demyelination there is redistribution of
sodium
channels along the axon and mitochondria are recruited to the demyelinated regions to meet the increased energy requirements necessary to maintain conduction. The mitochondria present within the chronically demyelinated axons will be functioning at full capacity. The axon may well be able to function for many years due to these adaptive mechanisms but we propose that eventually, despite antioxidant defences, free radical damage will accumulate and mitochondrial function will become compromised. ATP concentration within the axon will decrease and the effect on axonal function will be profound. The actual cause of cell death could be due to a number of mechanisms related to mitochondrial dysfunction including failure of ionic homeostasis, calcium influx, mitochondrial mediated cell death or impaired axonal transport. Whatever the cause of axonal loss our hypothesis is that mitochondria are central to this process. We explore steps to test this hypothesis and discuss the possible therapeutic approaches which target the mitochondrial mechanisms that may contribute to chronic axonal loss.
...
PMID:Mitochondrial dysfunction plays a key role in progressive axonal loss in Multiple Sclerosis. 1569 81
Multiple sclerosis (MS), an inflammatory demyelinating disease, is a major cause of
neurological disability
in young adults in the developed world. Although the progressive
neurological disability
that most patients with MS eventually experience results from axonal degeneration, little is known about the mechanisms of axonal injury in MS. Accumulating evidence suggests that the increased energy demand of impulse conduction along excitable demyelinated axons and reduced axonal ATP production induce a chronic state of virtual hypoxia in chronically demyelinated axons. In response to such a state, key alterations that contribute to chronic necrosis of axons might include mitochondrial dysfunction (due to defective oxidative phosphorylation or nitric oxide production),
Na+
influx through voltage-gated
Na+
channels and axonal AMPA receptors, release of toxic Ca2+ from the axoplasmic reticulum, overactivation of ionotropic and metabotropic axonal glutamate receptors, and activation of voltage-gated Ca2+ channels, ultimately leading to excessive stimulation of Ca2+-dependent degradative pathways. The development of neuroprotective therapies that target these mechanisms might constitute effective adjuncts to currently used immune-modifying agents.
...
PMID:Virtual hypoxia and chronic necrosis of demyelinated axons in multiple sclerosis. 1923 38
Counteracting the progressive
neurological disability
caused by neuronal and axonal loss is the major unmet clinical need in multiple sclerosis therapy. However, the mechanisms underlying irreversible neuroaxonal degeneration in multiple sclerosis and its animal model experimental autoimmune encephalomyelitis (EAE) are not well understood. A long-standing hypothesis holds that the distribution of voltage-gated
sodium
channels along demyelinated axons contributes to neurodegeneration by increasing neuroaxonal
sodium
influx and energy demand during CNS inflammation. Here, we tested this hypothesis in vivo by inserting a human gain-of-function mutation in the mouse Na
V
1.2-encoding gene
Scn2a
that is known to increase Na
V
1.2-mediated persistent
sodium
currents. In mutant mice, CNS inflammation during EAE leads to elevated neuroaxonal degeneration and increased disability and lethality compared with wild-type littermate controls. Importantly, immune cell infiltrates were not different between mutant EAE mice and wild-type EAE mice. Thus, this study shows that increased neuronal Na
V
1.2 activity exacerbates inflammation-induced neurodegeneration irrespective of immune cell alterations and identifies Na
V
1.2 as a promising neuroprotective drug target in multiple sclerosis.
...
PMID:Activity of Na
V
1.2 promotes neurodegeneration in an animal model of multiple sclerosis. 2788 51
