21 research outputs found
Modafinil for multiple sclerosis fatigue: does it work?
UNLABELLED: Modafinil is sometimes used in the clinical setting for treating multiple sclerosis (MS) fatigue, despite conflicting and disappointing results from clinical trials. OBJECTIVE: We audited the patient perceived effectiveness of modafinil when used in clinical practice in a carefully selected group of patients with typical MS fatigue. METHODS: All MS patients commenced on modafinil for fatigue in the Oxford MS clinic were identified retrospectively, and the patient perceived benefit, side effects and decision on continuation of therapy at 1 month was obtained from the medical notes. Additionally all patients were subsequently interviewed, up to 5 years after treatment initiation. RESULTS: Surprisingly, 69% patients with fatigue also suffered excessive daytime sleepiness, and this subgroup found modafinil more beneficial. There was a better response against excessive daytime sleepiness than fatigue. The benefit against fatigue or sleepiness was generally sustained (median 1 year). CONCLUSION: This suggests that modafinil may be useful, particularly when MS fatigue is associated with sleepiness. The relationship between fatigue and excessive daytime sleepiness is poorly understood and needs to be better defined before appropriate measures of the most clinically relevant outcomes can be selected for clinical trials. Outcome measures used in previous clinical trials have not properly evaluated the effects of modafinil
AChR phosphorylation and indirect inhibition of AChR function in seronegative MG.
BACKGROUND: Approximately 10% to 20% of patients with autoimmune MG do not have antibodies to the acetylcholine receptor (AChR), so-called seronegative MG (SNMG). IgG antibodies from up to 70% of SNMG patients bind to the muscle-specific receptor tyrosine kinase, MuSK. The plasmas and non-IgG fractions from SNMG patients (and some with AChR antibodies) also contain a factor, perhaps an IgM antibody, that inhibits AChR function, but it is not clear how this factor acts and whether it is related to the MuSK IgG antibodies. METHODS: The authors studied 12 unselected SNMG plasmas and their non-IgG fractions; seven were positive for MuSK IgG antibodies. Ion flux assays, electrophysiology, phosphorylation, and kinase assays were used to look at mechanisms of action. RESULTS: Eight of the 12 plasmas and their non-IgG fractions inhibited AChR function, but the inhibitory activity was transient and did not correlate with the presence of MuSK IgG antibodies. Two of three plasmas added outside of a cell-attached patch pipette inhibited AChR function within the patch, and these two plasmas also increased AChR phosphorylation. CONCLUSIONS: The authors propose that a plasma factor(s) in SNMG patients, distinct from MuSK IgG antibodies, binds to a muscle membrane receptor and activates a second messenger pathway leading to AChR phosphorylation and reduced AChR function. Identifying the target for this factor should lead to improved diagnosis of MG in MuSK antibody-negative patients and may provide new insights into the function of the neuromuscular junction and pathophysiological mechanisms in MG
Sickness behaviour is induced by a peripheral CXC-chemokine also expressed in multiple sclerosis and EAE.
Non-CNS chemokine production may contribute to previously unrecognised components of Multiple Sclerosis (MS) pathology. Here we show that IL-8, a neutrophil chemoattractant, is significantly increased in serum from individuals with MS, and that the rodent homolog of IL-8 (CXCL1) is expressed in the liver in experimental autoimmune encephalomyelitis (EAE), a rodent model of MS. The hepatic expression of CXCL1 in EAE is accompanied by neutrophil recruitment to the liver, and we show that this recruitment is a feature of post mortem liver tissue from MS patients, which is a previously unrecognised phenomenon. We speculated that the presence of peripheral CXC-chemokine expression might contribute to the sickness behaviours associated with MS, which are a significant contributor to morbidity. Peripheral, but not central, administration of CXCL1 to Wistar rats inhibited spontaneous activity in the open field and burrowing behaviour in a dose-dependent manner (5-45 microg). The expression of CXCL1 by the liver and the recruitment of neutrophils can be modelled by the intracerebral injection of IL-1beta. Here, we found that interferon-beta (IFN-beta) pretreatment significantly inhibited hepatic CXCL1 production and neutrophil recruitment to the liver induced by the microinjection of IL-1beta into the brain. Thus while the mechanism by which IFN-beta therapy suppresses disease in MS remains unclear, the data presented here suggests that the inhibition of hepatic chemokine synthesis may be a contributing factor