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Query: UMLS:C0033774 (
pruritus
)
14,546
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Halofantrine
is an orally administered blood schizontocide which is active against both chloroquine-sensitive and chloroquine-resistant plasmodia. Dose-finding and noncomparative clinical trials have confirmed the efficacy of halofantrine in the treatment of falciparum malaria in areas of chloroquine- and sulfonamide/pyrimethamine-resistant malaria and vivax malaria. However, poor results obtained in patients who failed mefloquine prophylaxis suggest that the efficacy of halofantrine may not extend to mefloquine-resistant P. falciparum, although more studies are needed to confirm this. Data concerning halofantrine in the treatment of P. ovale and P. malariae infections are still limited. One comparative study indicates that halofantrine has an efficacy equivalent to that of mefloquine and may be better tolerated.
Halofantrine
is generally well tolerated in both adults and children, the most common drug-associated effects being abdominal pain,
pruritus
, vomiting, diarrhoea, headache and rash, although it is difficult to distinguish between disease- and treatment-related events. The development of parasite resistance to halofantrine, like other blood schizontocides, is inevitable. Poor absorption resulting in variable peak plasma halofantrine concentrations, and possible cross-resistance with mefloquine, may accelerate the emergence of resistance to halofantrine. Thus, it is of primary importance that halofantrine is used only in areas where chloroquine- and sulfonamide/pyrimethamine-resistance are established in order to preserve and sustain its efficacy. If used with care, halofantrine will provide an important treatment option for falciparum malaria, a widespread parasitic disease associated with considerable morbidity against which the number of effective drugs available is being increasingly compromised by the spread of resistance.
...
PMID:Halofantrine. A review of its antimalarial activity, pharmacokinetic properties and therapeutic potential. 137 21
Halofantrine
is a phenanthrenemethanol antimalarial that is effective against asexual forms of multidrug-resistant Plasmodium falciparum malaria. It has no action on gametocytes or hypnozoites in the liver. The drug is administered as a racemic mixture but the (+)- and (-)-enantiomers show no difference in activity in vitro. Three formulations for oral administration are available for human use, i.e. tablets, capsules and suspension. Toxicity studies in animals suggest that halofantrine has very low toxicity both in short term and long term animal studies, and there has been no evidence of mutagenicity in these studies. Phase I, II and III clinical trials of halofantrine conducted in several tropical countries found the drug to be well tolerated and effective against multidrug-resistant P. falciparum malaria when 500mg was administered every 6 hours for 3 doses. The majority of clinical adverse effects reported, including nausea, vomiting, abdominal pain, diarrhoea, orthostatic hypotension, prolongation of QTc interval,
pruritus
and rash, have been mild and transient. There is wide interindividual variation in halofantrine absorption. The maximal plasma concentration (Cmax) is achieved approximately 6 hours after oral administration. Bioavailability is not dose-proportional for doses over 500mg, but there is a dose-proportional increase in Cmax and area under the plasma concentration-time curve (AUC) for doses between 250 and 500mg. In patients with malaria the bioavailability of halofantrine is decreased. The mean half-life of absorption is 4 hours and Cmax is significantly lower than that obtained in healthy individuals. Furthermore, halofantrine absorption is enhanced when the drug is taken with fatty food. Therefore, halofantrine should be taken with food to ensure optimal absorption in patients with malaria. The terminal elimination half-life is 5 days in patients with malaria.
Halofantrine
is biotransformed in the liver to its major metabolite N-debutyl-halofantrine. Plasma concentrations of this metabolite are observed soon after administration of halofantrine, but in much lower concentrations. The elimination half-life is similar to that of halofantrine. There have been increasing reports of halofantrine treatment failure, particularly in the eastern part of Thailand. The majority of treatment failures have been associated with incomplete drug absorption. The dose-dependent cardiotoxic effects (e.g. cardiac arrhythmia) are a major concern, particularly when the bioavailability of the drug cannot be predicted. Ongoing and future studies should aim at developing more appropriate drug formulation(s) and/or optimising dosage regimens. This will allow therapeutic concentrations to be achieved with minimum adverse effects, particularly cardiotoxicity.
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PMID:Clinical pharmacokinetics of halofantrine. 795 74
Malaria, caused mostly by Plasmodium falciparum and P. vivax, remains one of the most important infectious diseases in the world. Antimalarial drug toxicity is one side of the risk-benefit equation and is viewed differently depending upon whether the clinical indication for drug administration is malaria treatment or prophylaxis. Drug toxicity must be acceptable to patients and cause less harm than the disease itself. Research that leads to drug registration tends to omit two important groups who are particularly vulnerable to malaria--very young children and pregnant women. Prescribing in pregnancy is a particular problem for clinicians because the risk-benefit ratio is often very unclear. The number of antimalarial drugs in use is very small. Despite its decreasing efficacy against P. falciparum, chloroquine continues to be used widely because of its low cost and good tolerability. It remains the drug of first choice for treating P. vivax malaria.
Pruritus
is a common adverse effect in African patients. As prophylaxis, chloroquine is usually combined with proguanil. This combination has good overall tolerability but mouth ulcers and gastrointestinal upset are more common than with other prophylactic regimens. Sulfadoxine/pyrimethamine is well tolerated as treatment and when used as intermittent preventive treatment in pregnant African women. Sulfadoxine/pyrimethamine is no longer used as prophylaxis because it may cause toxic epidermal necrolysis and Stevens Johnson syndrome. Mefloquine remains a valuable drug for prophylaxis and treatment. Tolerability is acceptable to most patients and travellers despite the impression given by the lay press. Dose-related serious neuropsychiatric toxicity can occur; mefloquine is contraindicated in individuals with a history of epilepsy or psychiatric disease. Quinine is the mainstay for treating severe malaria in many countries. Cardiovascular or CNS toxicity is rare, but hypoglycaemia may be problematic and blood glucose levels should be monitored.
Halofantrine
is unsuitable for widespread use because of its potential for cardiotoxicity. There is renewed interest in two old drugs, primaquine and amodiaquine. Primaquine is being developed as prophylaxis, and amodiaquine, which was withdrawn from prophylactic use because of neutropenia and hepatitis, is a potentially good partner drug for artesunate against falciparum malaria. Atovaquone/proguanil is a new antimalarial combination with good efficacy and tolerability as prophylaxis and treatment. The most important class of drugs that could have a major impact on malaria control is the artemisinin derivatives. They have remarkable efficacy and an excellent safety record. They have no identifiable dose-related adverse effects in humans and only very rarely produce allergic reactions. Combining an artemisinin derivative with another efficacious antimalarial drug is increasingly being viewed as the optimal therapeutic strategy for malaria.
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PMID:Antimalarial drug toxicity: a review. 1472 85
