N-Acetylcysteine is useful as a mucolytic agent for treatment of chronic bronchitis and other pulmonary diseases complicated by the production of viscous mucus. It is also used as an antidote to paracetamol (acetaminophen) poisoning and found to be effective for the prevention of cardiotoxicity by doxorubicin and haemorrhagic cystitis from oxazaphosphorines. After an oral dose of N-acetylcysteine 200 to 400 mg the peak plasma concentration of 0.35 to 4 mg/L is achieved within 1 to 2 hours. Although the data are conflicting, it appears that the administration of charcoal may interfere with drug absorption, with up to 96% of the drug adsorbed on to the charcoal. Information on absorption in the presence of food or other drugs is not available. The volume of distribution ranges from 0.33 to 0.47 L/kg and protein binding is significant, reaching approximately 50% 4 hours after the dose. Pharmacokinetic information is not available as to whether or not N-acetylcysteine crosses the blood-brain barrier or placenta, or into breast milk. Renal clearance has been reported as 0.190 to 0.211 L/h/kg and approximately 70% of the total body clearance is nonrenal. Following oral administration, reduced N-acetylcysteine has a terminal half-life of 6.25h. Little is known of the metabolism of this agent, although it is believed to be rapidly metabolised and incorporated on to proteins. The major excretory product is inorganic sulphate. Frequently reported side effects are nausea, vomiting and diarrhoea. Biochemical and haematological adverse effects are observed but are not clinically relevant. Drug interactions of clinical significance have been observed with paracetamol, glutathione and anticancer agents.
The quantitative aspects of the disposition in man of 12 antituberculosis drugs [isoniazid, rifampicin, (rifampin), ethambutol, para-aminosalicylic acid, pyrazinamide, streptomycin, kanamycin, ethionamide, cycloserine, capreomycin, viomycin and thiacetazone] are reviewed. Isoniazid appears to be the only agent for which plasma concentrations and clearance are related to hereditary differences in acetylator status and for which there is an appreciable 'first-pass' effect. Recent data cast doubt on the suggestion that isoniazid may be more hepatotoxic for rapid as opposed to slow acetylators. Continuous administration of rifampicin leads to induction of enzymes in the liver with a concomitant decrease in maximum plasma concentrations, the time required to achieve this level, elimination half-life, and area under the plasma concentration-time curve (AUC). Coadministration of para-aminosalicylic acid leads to increases in the serum concentrations and elimination half-life of isoniazid. With a few exceptions, the metabolites of the antituberculosis drugs are devoid of antimicrobial activity; the exceptions are 25-desacetylrifampicin which accounts for approximately 80% of the drug's antimicrobial activity in human bile, the acetylated and glycylated metabolites of para-aminosalicylic acid, and the sulphoxide metabolites of ethionamide. The effect of renal impairment is relatively unimportant for the excretion of isoniazid, rifampicin and para-aminosalicylic acid, but the elimination half-life of streptomycin increases to 100 hours when the blood urea nitrogen level is greater than 100mg/100ml, and ototoxicity is strikingly more frequent. In states of malnutrition, such as kwashiorkor, the protein binding of para-aminosalicylic acid decreases from 15% to essentially zero and in the case of ethionamide and streptomycin binding decreases by 6% and 16% respectively. Of the data concerning age-related effects, most notable are the prolonged elimination half-life of isoniazid in neonates (up to 19.8 hours), and the lower peak serum concentrations of rifampicin in children of one-third to one-tenth those of adults following a similar dose on a weight basis. For kanamycin, the maximum plasma concentration varies inversely with age but is not influenced by birthweight; however, the clearance is directly dependent upon birthweight and postnatal age. For the elderly, age is an insignificant factor for the elimination of isoniazid when compared with young adults of similar acetylator status, and the metabolism of rifampicin may be considered globally unaltered in this age group.(ABSTRACT TRUNCATED AT 400 WORDS)
Corynebacterium minutissimum is the bacteria that leads to cutaneous eruptions of erythrasma and is the most common cause of interdigital foot infections. It is found mostly in occluded intertriginous areas such as the axillae, inframammary areas, interspaces of the toes, intergluteal and crural folds, and is more common in individuals with diabetes mellitus than other clinical patients. This organism can be isolated from a cutaneous site along with a concurrent dermatophyte or Candida albicans infection. The differential diagnosis of erythrasma includes psoriasis, dermatophytosis, candidiasis and intertrigo, and methods for differentiating include Wood's light examination and bacterial and mycological cultures. Erythromycin 250mg four times daily for 14 days is the treatment of choice and other antibacterials include tetracycline and chloramphenicol; however, the use of chloramphenicol is limited by bone marrow suppression potentially leading to neutropenia, agranulocytosis and aplastic anaemia. Further studies are needed but clarithromycin may be an additional drug for use in the future. Where there is therapeutic failure or intertriginous involvement, topical solutions such as clindamycin, Whitfield's ointment, sodium fusidate ointment and antibacterial soaps may be required for both treatment and prophylaxis. Limited studies on the efficacy of these medications exist, however, systemic erythromycin demonstrates cure rates as high as 100%. Compared with tetracyclines, systemic erythromycin has greater efficacy in patients with involvement of the axillae and groin, and similar efficacy for interdigital infections. Whitfield's ointment has equal efficacy to systemic erythromycin in the axillae and groin, but shows greater efficacy in the interdigital areas and is comparable with 2% sodium fusidate ointment for treatment of all areas. Adverse drug effects and potential drug interactions need to be considered. No cost-effectiveness data are available but there are limited data on cost-related treatment issues. A guideline is proposed for the detection, evaluation, treatment and prophylaxis of this cutaneous eruption.
Clofazimine is useful in the treatment of Hansen's disease (leprosy) and some dermatological disorders, and is currently being used in drug regimens for patients with human immunodeficiency viral infections who are also infected with Mycobacterium avium complex. After an oral dose, absorption is variable, but when given in an oil-wax suspension is approximately 70%. Administration with food appears to increase the peak plasma drug concentration and reduce the time to peak level. Data on the volume of distribution and percentage or type of protein binding are not available; however, the drug undergoes extensive tissue distribution. Clofazimine does not cross the blood-brain barrier, but does cross the placenta, and is found in human breast milk. To date 3 urinary metabolites have been identified in man, but their biological activity is unknown. A substantial portion of the unchanged drug is excreted in faeces. The elimination half-life is variable, with values as long as 70 days being quoted in the literature. Frequently reported side effects of clofazimine are hyperpigmentation of the skin and conjunctiva, and abdominal pain. These resolve upon cessation of therapy. Biochemical and haematological adverse effects have been reported, but are generally not clinically relevant. Pharmacokinetic drug interactions of potential clinical significance have been observed with dapsone, oestrogen, rifampicin and vitamin A.
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