Showing papers by "B.K. Park published in 1991"

Carbamazepine-hypersensitivity: assessment of clinical and in vitro chemical cross-reactivity with phenytoin and oxcarbazepine.

Abstract: 1. Seven patients clinically diagnosed as being hypersensitive to carbamazepine and one patient hypersensitive to both carbamazepine and oxcarbazepine have been identified. They have been compared with a control group (hereafter referred to as 'control subjects') comprising five patients on chronic carbamazepine therapy without adverse effects and 12 healthy volunteers who have never been exposed to anticonvulsants. 2. An in vitro cytotoxicity assay employing mononuclear leucocytes as target cells has been used first, to determine the ability of 10 different human livers to bioactivate carbamazepine to a cytotoxic metabolite, and secondly, to compare the cell defences of carbamazepine-hypersensitive patients and control subjects to oxidative drug metabolites generated by a murine microsomal system, using a blinded protocol. 3. With human liver microsomes, the metabolism-dependent cytotoxicity of carbamazepine increased with increasing microsomal protein concentration. At a protein concentration of 2 mg per incubation, the cytotoxicity of carbamazepine with human liver microsomes (n = 10 livers) increased from 7.2 +/- 0.8% (baseline) to 16.4 +/- 2.1% (with NADPH; P = 0.002). 4. In the presence of phenobarbitone-induced mouse microsomes and NADPH, the mean increase in cytotoxicity above the baseline with carbamazepine was significantly greater (P less than 0.001) for the cells from the carbamazepine-hypersensitive patients (7.9 +/- 0.8%) than from control subjects (2.6 +/- 0.3%). 5. In the presence of phenobarbitone-induced mouse microsomes and NADPH, there was no significant difference in cytotoxicity between the cells from carbamazepine hypersensitive patients and from control subjects in the presence of either phenytoin or oxcarbazepine.(ABSTRACT TRUNCATED AT 250 WORDS)

Direct and metabolism-dependent toxicity of sulphasalazine and its principal metabolites towards human erythrocytes and leucocytes.

Abstract: 1. The role of metabolites in sulphasalazine-mediated toxicity has been investigated in vitro by the use of human red blood cells and mononuclear leucocytes as target cells, with methaemoglobin formation and cytotoxicity respectively, being the defined toxic end-points. 2. Of the metabolites of sulphasalazine investigated, only sulphapyridine was bioactivated by human liver microsomes in the presence of NADPH to a metabolite which caused marked methaemoglobinaemia and a small, but statistically significant degree of mononuclear leucocyte cell death. 3. Methaemoglobinaemia was inhibited by ketoconazole but not by ascorbic acid (100 microM), glutathione (500 microM) and N-acetylcysteine (50 microM). In contrast, ascorbic acid and the thiols afforded complete protection for mononuclear leucocytes. 4. Sulphapyridine (100 microM) was converted in vitro to a metabolite (metabolite conversion 6.8 +/- 0.3%), the retention time of which on h.p.l.c. corresponded to synthetic sulphapyridine hydroxylamine. The half-life of sulphapyridine hydroxylamine in phosphate buffer (pH 7.4) was found to be 8.1 min. 5. In the absence of microsomes and NADPH, sulphapyridine hydroxylamine caused a concentration-dependent (10-500 microM) increase in methaemoglobinaemia (2.9%-24.4%) and cytotoxicity (5.4%-51.4%), whereas sulphasalazine, sulphapyridine, 5-hydroxy sulphapyridine and 5-aminosalicylic acid had no effect.

The effect of preincubation with cimetidine on the N-hydroxylation of dapsone by human liver microsomes.

Abstract: We have examined the ability of cimetidine to inhibit the oxidative metabolism and hence haemotoxicity of dapsone in vitro, using a two compartment system in which two Teflon chambers are separated by a semi-permeable membrane. Compartment A contained a drug metabolizing system (microsomes prepared from human or rat liver +/- NADPH), whilst compartment B contained human red cells. Preincubation (30 min) of human liver microsomes with cimetidine (0-1000 microM) and NADPH prior to the addition of dapsone (100 microM) and NADPH (1 mM) resulted in a concentration-dependent decrease in the concentrations of dapsone hydroxylamine (from 179 +/- 47 to 40 +/- 6 ng) in compartment B. This reduction of hydroxylamine metabolite was reflected in the concentration-dependent reduction in methaemoglobin measured (from 7.1 +/- 0.7 to 3.5 +/- 1.5%) in parallel experiments. Preincubation of microsomes with cimetidine in the absence of NADPH had no effect. The effect of cimetidine pretreatment on dapsone-dependent methaemoglobin was confirmed using microsomes prepared from a further three sources of human liver, as well as from rat liver.