Development of dapsone toxicity in patients with inflammatory dermatoses: activity of acetylation and hydroxylation of dapsone as risk factors

BACKGROUND

Alternative independent routes of dapsone metabolism include N-hydroxylation to the hydroxylamine, a potentially toxic metabolite, by cytochrome P450 enzymes and acetylation to a nontoxic metabolite by N-acetyltransferase. Potentially, therefore, the relative extents of these two routes in an individual could determine the occurrence of adverse reaction with dapsone therapy.

METHODS

Phenotypic activity of these two routes of metabolism was assessed in 18 patients receiving longterm dapsone therapy for inflammatory dermatoses and was related to the development of dapsone toxicity. N-Hydroxylation was assessed by the dapsone recovery ratio, a ratio of dapsone hydroxylamine to the sum of hydroxylamine and dapsone in 8-hour urine, whereas N-acetylation was assessed by the acetylation ratio, a ratio of monoacetyldapsone to dapsone in 8-hour plasma sample after an oral dose of dapsone.

RESULTS

There was wide intersubject variation in both the acetylation ratio and the dapsone recovery ratio, but both phenotypic measures remained stable within individuals. The dapsone recovery ratio showed a tendency toward being lower in fast than in slow acetylators, but this was not statistically significant. There was an inverse relationship between acetylation and hydroxylation (r = -0.69; P < .005) at steady state that was not apparent after the first dose. Neurotoxicity developed in two subjects and hemolytic anemia developed in two subjects. Plasma levels of dapsone in these four subjects were similar to those in subjects who showed no toxicity. All four were slow acetylators and three were rapid hydroxylators, consistent with the toxic nature of dapsone hydroxylamine.

CONCLUSIONS

These observations are consistent with what is known about the toxicity profile of dapsone metabolites and suggest that assessing N-acetylation and N-hydroxylation capacities can help to identify subjects at increased risk of a toxic response. This approach of assessing the phenotypic measures of drug-metabolizing activity to predict adverse reaction may also apply to other drugs with metabolic-based adverse effects.

Pharmacokinetics of trimetrexate and dapsone in AIDS patients with Pneumocystis carinii pneumonia

The objective of this study was to determine the pharmacokinetics of trimetrexate and dapsone in AIDS patients with moderate to severe pneumocystis pneumonia. Trimetrexate, leucovorin, and dapsone were administered for 21 +/- 3 days in the following doses: trimetrexate glucuronate, 45 mg/m2; leucovorin, 20 mg/m2; and dapsone, 100 mg daily. The pharmacokinetics of trimetrexate, dapsone, and dapsone's metabolite, monoacetyldapsone, were determined at three separate periods over the course of treatment. Serial blood samples were obtained over 24 hours after dosing and analyzed for trimetrexate, dapsone, and monoacetyldapsone, and pharmacokinetic parameters were determined. The mean parameters obtained for the early, mid-, and late collection periods were the following: trimetrexate: t1/2 = 8.29, 9.15, 10.00 hr; AUC = 16.85, 22.38, 24.49 mg.hr/l; CI = 5.58, 4.14, 3.96 l/hr, respectively. DDS: t1/2 = 14.99, 16.59, 15.13 hr; AUC = 30.60, 35.29, 36.08 mg.hr/l; CI = 3.82, 3.49, 3.01 l/hr, respectively. Monoacetyldapsone: t1/2 = 20.25, 18.66, 16.32 hr; AUC = 24.05, 24.06, 23.86 mg.hr/l, respectively. No statistically significant changes in pharmacokinetics for trimetrexate or dapsone were observed over the 21 +/- 3 day course of treatment. The results suggest that there are no major interactions between trimetrexate and dapsone when administered together in acutely ill patients.

Lessons to be learned: a case study approach: prolonged methaemoglobinaemia due to inadvertent dapsone poisoning; treatment with methylene blue and exchange transfusion

The authors present a case of methaemoglobinaemia of acute onset, with an unusually protracted course. The long persistence of this disorder led to a search for the cause which was eventually traced to medication with dapsone. The latter was found to be inappropriately being taken by the patient instead of an antispasmodic that had been prescribed for a spinal condition; this was because the tablets had been incorrectly labelled and dispensed in a pharmacy. The patient took increasing doses of the presumed 'antispasmodic' tablets as they seemed to lack clinical effect, thus further exacerbating the toxic consequences. Moreover, the patient brought his wrongly labelled tablets into hospital and was allowed to use them there, contrary to normal hospital policy. As treatment for the methaemoglobinaemia both bolus and continuous infusions of methylene blue were used, which probably contributed to the severe haemolysis which followed. Furthermore, the development of a rare side effect of dapsone toxicity, namely that of a sensorimotor neuropathy, is reported.

Penetration of dapsone into cerebrospinal fluid of patients with AIDS

It has been proposed that dapsone in combination with pyrimethamine could be used for prophylaxis of both Pneumocystis carinii pneumonia and encephalitis due to Toxoplasma gondii. Ten patients with AIDS undergoing lumbar puncture for diagnostic purposes were studied in order to assess the penetration of dapsone into CSF. Blood and CSF samples were obtained between 3 and 72 h following administration. Six patients had received oral dapsone for at least 1 month at the dosage regimen of 100 mg twice of three times weekly and four patients had received a single oral 100 mg dose. Dapsone concentration in CSF ranged from 0.013 to 0.296 mg/L while concentrations in plasma ranged from 0.018 to 1.231 mg/L. The CSF:plasma concentration ratio ranged from 0.21 to 2.01. The MIC of dapsone in combination with pyrimethamine against T. gondii is unknown, and further data are required to confirm whether the CSF concentrations of dapsone found in our study are sufficient to inhibit T. gondii growth in patients infected with human immunodeficiency virus (HIV). The high interpatient variability of dapsone CSF concentrations warrants further studies in selected categories of patients with HIV infection.

Chlorproguanil/dapsone for uncomplicated Plasmodium falciparum malaria in young children: pharmacokinetics and therapeutic range

The disposition of chlorproguanil/dapsone (one daily dose for 3 d of 1.2 and 2.4 mg/kg respectively) has been studied in young children with Plasmodium falciparum malaria, to provide data complementary to a clinical trial of this drug combination. Unbound concentrations of chlorcycloguanil (the active metabolite of chlorproguanil) and dapsone in clinical samples have been related to the unbound drug concentrations which produced defined outcomes in tests in vitro of drug efficacy and toxicity. Twelve children with uncomplicated malaria were treated: all cleared parasitaemia within 72 h and made uneventful recoveries. After the first dose of chlorproguanil/dapsone the maximum unbound chlorcycloguanil concentration in clinical samples (19 ng/mL [about 60 nM]) was 2 orders of magnitude above the 50% inhibitory concentration (IC50) value for this drug against the K39 stain of P. falciparum, while falling 2 orders of magnitude below its IC50 against human bone marrow cells; the maximum unbound dapsone concentration in clinical samples (160 ng/mL [about 645 nM]) was 10-fold higher than its IC50 against the K39 strain. However, because of the rapid elimination of chlorproguanil from the body (half-life 12.6 +/- 6.3 h), the minimum fractional inhibitory concentrations of unbound chlorcycloguanil/dapsone against the K39 strain were probably exceeded for no more than 6 d. These data, together with the clinical trial, will be helpful in deciding whether current chlorproguanil/dapsone doses are optimal for the treatment of falciparum malaria.

Penetration of dapsone into pulmonary lining fluid of human immunodeficiency virus type 1-infected patients

We studied the penetration of dapsone into the epithelial lining fluid (ELF) of sixteen human immunodeficiency virus type 1-infected patients who had received the drug at a dose of 100 mg twice weekly as primary prophylaxis for Pneumocystis carinii pneumonia. Bronchoscopy, bronchoalveolar lavage (BAL), and venipuncture were performed for each patient at a specific time after administration of the last dose of dapsone. Dapsone concentrations in plasma and BAL were determined by high-performance liquid chromatography. The apparent volume of ELF recovered by BAL was determined by using urea as an endogenous marker. The mean concentrations of dapsone in ELF at 2 h (five patients), 4 h (three patients), 12 h (two patients), 24 h (three patients), and 48 h (three patients) were 0.95, 0.70, 1.55, 0.23, and 0.45 mg/liter, respectively, while concentrations in plasma were 1.23, 0.79, 1.31, 0.83, and 0.18 mg/liter, respectively. Dapsone concentrations in ELF were 76, 79, 115, 65, and 291% of those observed in plasma at the same times, respectively. These data show that dapsone is well distributed into ELF and that a twice-weekly 100-mg prophylactic regimen results in sustained concentrations in this compartment.

A rapid, specific, and sensitive method for the determination of acetylation phenotype using dapsone

An original, simple, specific, and rapid high-performance liquid chromatography assay for the determination of dapsone and monoacetyldapsone in human plasma is presented. The procedure consists of extracting the drugs and the internal standard (phenacetin) from 1 mL plasma with ethyl ether at alkaline pH. A liquid chromatograph equipped with a reversed-phase 5-microm C8 analytical column was used. The drugs were eluted with a mixture of water and methanol (70:30, v/v). Flow rate and wavelength were set at 1 mL/min and 286 nm, respectively. The precision, linearity, and limit of quantitation of the method were within acceptable limits. The method was considered adequate and has been used for the determination of the acetylator phenotype in population studies.

High-performance liquid chromatography determination of pyrimethamine, dapsone, monoacetyldapsone, sulfadoxine, and N-acetyl-sulfadoxine after rapid solid-phase extraction

A solid-phase extraction procedure and a corresponding high-performance liquid chromatographic technique based on methods previously published by Edstein et al. (Edstein M. Quantification of antimalarial drugs. I. Simultaneous measurement of sulphadoxine, N4acetylsulphadoxine and pyrimethamine in human plasma. J Chromatogr 1984;305:502-7; Edstein M. Quantification of antimalarial drugs. II. Simultaneous measurement of dapsone, monoacetyldapsone and pyrimethamine in human plasma. J Chromatogr 1984;307:426-31) were developed for simultaneous determination of either dapsone (DDS), monoacetyldapsone (MADDS), and pyrimethamine (PYR) or sulfadoxine (SDX), N-acetyl-sulfadoxine (NAS) and pyrimethamine in plasma. Solid-phase extraction was achieved using C-18 extraction columns. An ionpair chromatography was performed on a C-18 analytical column (mu Bondapak C-18, 300 x 3.9 mm I.D.). Gradient elution with methanol, acetonitrile, PIC B6 reagent (1-hexanesulphonic acid), and water as mobile phase was applied. Ultraviolet detection was done at 210 nm for PYR, at 254 nm for SDX and NAS, and at 295 nm for DDS and MADDS. The extraction recoveries averaged 92.1% for PYR, 87.6% for DDS, 87.5% for MADDS, 91.2% for SDX, and 92.4% for NAS. The limit of quantification using 1.0-ml plasma samples was 15 ng/ml for PYR, DDS, MADDS, NAS, and 25 ng/ml for SDX (precision < 15%).

Combined dapsone and clofazimine intoxication

We report clinical findings and pharmacokinetic data regarding a combined dapsone and clofazimine intoxication in a man, who ingested 50 tablets of dapsone (100 mg) 20 capsules of clofazimine (100 mg) and two tablets of rifampicin (600 mg). Oral administration of activated charcoal (50 grams) and sodium sulphate (20 grams) after gastric lavage resulted in an elimination half-life in plasma of 11.1 and 10.8 h for dapsone and its main metabolite, monoacetyldapsone, respectively. A rapid initial decrease of the plasma concentration of clofazimine was observed after gastric lavage and administration of activated charcoal and sodium sulphate. 15 h after this treatment, clofazimine plasma levels remained relatively constant. Dapsone-induced methaemoglobinaemia (48% at admission) was treated successfully with methylene blue.

The effect of acetylation and deacetylation on the disposition of dapsone and monoacetyl dapsone hydroxylamines in human erythrocytes in-vitro

The fates of both dapsone and monoacetyl hydroxylamine have been studied in terms of acetylation and deacetylation within the human erythrocyte in-vitro. A comparison between the two metabolites showed equipotency in methaemoglobin generation at 15 min, although the monoacetyl derivative was the more rapid haemoglobin oxidizer. Within the erythrocytes, both dapsone and monoacetyl hydroxylamines were found to undergo acetylation, deacetylation and diacetylation. Of the inhibitors of acetylation studied, folate caused an increase in methaemoglobin formation associated with both metabolites, which led to a rise in both acetylated and non-acetylated amine formation. Amethopterin was associated with a rise in hydroxylamine mediated methaemoglobin formation which coincided with a fall in acetylated products. It is possible that the hydroxylamines undergo erythrocytic processes of acetylation and deacetylation before methaemoglobin-mediated reduction to their respective amines.

Measurement of physiological concentrations of dapsone and its monoacetyl metabolite: a miniaturised assay for liquid or filter paper-absorbed samples

A modification of existing HPLC assay methods is described for the measurement of dapsone and monoacetyldapsone in 50-microliter samples of plasma and whole blood. This method, in particular the use of small sample volumes dried onto filter paper strips, is applicable to multi-sample clinical and pharmacokinetic studies in children with malaria, who are often anaemic, and where sample volume must be kept to a minimum. Basified samples were extracted into 5 ml of ethyl acetate-tert.-butylmethyl ether (1:1, v/v), chromatographed on a mu BondapaK C18, 10-micron column with water-acetonitrile-glacial acetic acid (81:17.5:5, v/v) containing 2 g/l l-octanesulphonic acid as the mobile phase and detected at 274 nm.

Effects of the antacids in didanosine tablets on dapsone pharmacokinetics

OBJECTIVE

To investigate 1) the effects of the magnesium-aluminum antacids in didanosine tablets on dapsone absorption in healthy volunteers and 2) the effects of the antacid formulation of active didanosine tablets on dapsone pharmacokinetics in patients seropositive for human immunodeficiency virus (HIV).

DESIGN

Two separate, randomized, two-period, two-treatment, crossover studies with a 21-day washout period between treatments.

SETTING

Clinical investigation unit of a university hospital.

PARTICIPANTS

Six healthy men and six HIV-positive men.

MEASUREMENTS

Serial dapsone plasma concentrations were measured when dapsone, 100 mg, was administered alone and with either the third of four doses of didanosine placebo tablets (group 1) or the 27th of 28 doses of active didanosine tablets (group 2). In each study, pharmacokinetic variables were determined using noncompartmental methods and compared by analysis of variance.

RESULTS

When dapsone was administered alone, pharmacokinetic variables did not significantly differ from those with dapsone given in either combination (P > 0.10 for all comparisons).

CONCLUSIONS

Didanosine, antacids, and other excipients in the currently used didanosine chewable tablets did not significantly affect plasma concentrations of dapsone.

A case of acute dapsone poisoning: toxicological data and review of the literature

A case of nonfatal, acute poisoning following the ingestion of an undetermined amount of dapsone (DDS) in a 49-year-old woman is presented. The clinical features were dyspnea and deep cyanosis. Methemoglobinemia was 39.0% on admission. DDS was identified and quantitated in blood samples taken on the third day (sample A) and fifth day (sample B) in the hospital using a high-performance liquid chromatographic technique with diode-array detection. DDS concentrations were 26.99 and 8.40 micrograms/mL in samples A and B, respectively. Results are discussed in the light of an extensive review of the literature (1950-1993) available on DDS poisonings.

Pharmacokinetics of dapsone in human immunodeficiency virus-infected children

Dapsone, administered at various doses and schedules, has been proven to be a safe and effective alternative to trimethoprim-sulfamethoxazole for prevention of Pneumocystis carinii pneumonia (PCP) in adults with human immunodeficiency virus (HIV) infection. Dapsone is also recommended by the Centers for Disease Control for PCP prophylaxis in HIV-infected children. However, the suggested dosage regimen is based upon clinical experience with children with leprosy and dermatitis herpetiformis rather than pharmacokinetic and pharmacodynamic data obtained from the target patient population. In order to determine a rational dosage regimen that could be tested in clinical studies aimed at the evaluation of dapsone for the prevention of PCP in HIV-infected children, we studied the pharmacokinetics of dapsone following a 2-mg/kg of body weight oral dose in twelve HIV-positive children aged 9 months to 9 years. Plasma was collected at the following times after dapsone administration: 0, 2, 4, 6, 12, 24, 48, 72, and 96 h. The levels of dapsone in plasma were determined by high-performance liquid chromatography. Data were analyzed by noncompartmental methods. Expressed as means +/- standard deviations (ranges), the pharmacokinetic parameters were as follows: peak concentration in plasma, 1.12 +/- 0.48 (0.44 to 1.81) mg/liter; time to peak concentration in plasma, 3.8 +/- 1.3 (2 to 6) h; half-life at elimination phase, 24.2 +/- 7.1 (14.4 to 35.0) h; clearance from plasma divided by bioavailability (CL/F), 1.15 +/- 0.67 (0.37 to 2.63) ml/min/kg; and volume of distribution divided by bioavailability (V/F), 2.25 +/- 1.20 (1.00 to 4.57) liters/kg. Oral CL correlated negatively with age (r = 0.614 and P = 0.034), as did V (r = 0.631 and P = 0.028). As a consequence of the high interindividual variability in growth retardation, pharmacokinetic parameters correlated with measures of body development better than they did with age (e.g., for CL/F to height, r = 0.765 and P = 0.004, and for V/F to height, r = 0.748 and P = 0.005). Since oral CL from plasma and V were positively and highly correlated (r = 0.898 and P = 0.0001), a lower absolute F may be the cause, in part, of higher values for CL/F and V/F in smaller children. The results of this study warrant the testing of a 2-mg/kg dose of dapsone administered twice or thrice weekly to HIV-infected children. The monitoring of drug levels in plasma and dosage adjustment may be necessary for smaller children.

High-performance liquid chromatography determination of dapsone, monoacetyldapsone, and pyrimethamine in filter paper blood spots

A high-performance liquid chromatography method for the simultaneous analysis of dapsone (DDS), the major metabolite of DDS, monoacetyldapsone (MADDS), and pyrimethamine (PYR) was modified for capillary blood samples obtained by finger prick and dried on filter paper. Limit of quantitation using 150 microliters whole blood dried on filter paper was found to be 20 ng/ml for DDS and PYR and 15 ng/ml for MADDS (precision < 15%). The clinically relevant concentrations of DDS are 50-2,000 ng/ml and for PYR 25-150 ng/ml. No interference from several drugs were observed. The accuracy of the filter paper method and the original whole-blood method was almost comparable. Standardization could therefore be obtained by the more simple whole-blood method. Dried filter paper samples stored at 19-22 degrees C were stable for months and for 2 weeks stored at 35 degrees C. The concentrations of simultaneously collected capillary blood and conventional venous blood samples correlated well. The present method using capillary blood dried on filter paper is reliable, simple, sensitive, and applicable in the field with limited technical facilities.

Evaluation of effects of altered gastric pH on absorption of dapsone in healthy volunteers

A prospective, randomized, crossover study was performed with seven healthy volunteers to address the effect of increased gastric pH on dapsone absorption. Subjects were randomized to receive a single 100-mg dose of dapsone or a single 100-mg dose of dapsone in addition to 30 ml of a high potency antacid 1 h before dapsone administration and hourly thereafter for a total of 10 doses. Dapsone concentrations in serum were measured periodically for 48 h. No statistical differences between the two regimens were noted when mean dapsone maximal initial concentrations, times to peak, and areas under the curve were compared. These data suggest that an increase in gastric pH has little or no effect on the absorption of dapsone in healthy subjects.

Dapsone N-acetylation, metoprolol alpha-hydroxylation, and S-mephenytoin 4-hydroxylation polymorphisms in an Indonesian population: a cocktail and extended phenotyping assessment trial

We examined dapsone N-acetylation and metoprolol alpha-hydroxylation and S-mephenytoin 4-hydroxylation phenotypings using the respective test probes (dapsone and racemic metoprolol and mephenytoin) administered separately and in a cocktail manner to an Indonesian subject group (n = 30). After ascertaining that the separate and cocktail phenotyping tests of the probe drugs correlated with each other (all rs values > 0.84; p < 0.001), the cocktail phenotyping assessment was extended to the other 74 Indonesians. In a total of 104 Indonesians phenotyped with the cocktail test, a visual antimode was apparent only in the dapsone N-acetylation and S-mephenytoin 4-hydroxylation polymorphisms: the frequencies of slow acetylators and poor hydroxylators were 43.3% (95% confidence interval, 33.7% to 52.8%) and 15.4% (95% confidence interval, 8.5% to 22.3%), respectively. The distribution histogram and probit plots of the metabolic ratio of metoprolol gave no clear evidence for bimodality, and therefore no poor alpha-hydroxylator of metoprolol was considered to exist in the present sample size. The findings indicate that the Indonesian subjects have a greater incidence of slow acetylator phenotype compared with Japanese and Chinese, as well as a frequency of poor metabolizer phenotype of S-mephenytoin similar to that of Korean and Chinese subjects. They resemble an African population (Nigerians) in metoprolol alpha-hydroxylation polymorphism, with no apparent antimode derived from white populations.

Levels of dapsone and pyrimethamine in serum during once-weekly dosing for prophylaxis of Pneumocystis carinii pneumonia and toxoplasmic encephalitis

Concentrations of dapsone, monoacetyldapsone, and pyrimethamine were determined in 36 serum samples from human immunodeficiency virus-infected patients on prophylaxis with once-weekly administration of dapsone-pyrimethamine (200 mg of dapsone-75 mg of pyrimethamine). During day 1 after ingestion, median levels of 1,038 ng of dapsone per ml and 356 ng of pyrimethamine per ml were found. During days 6 to 7, the dapsone level fell to < 20 ng/ml in five of nine serum samples, but the pyrimethamine level remained elevated (125 ng/ml). Concurrent, but separately ingested, didanosine administration did not seem to decrease the drug concentrations.

Determination of dapsone in serum and saliva using reversed-phase high-performance liquid chromatography with ultraviolet or electrochemical detection

A simple, extractionless method for the determination of dapsone in serum and saliva is described. Reversed-phase high-performance liquid chromatography is used with UV detection at 295 nm or electrochemical detection at 0.7 V. Diazoxide in buffer is the internal standard for UV detection and practolol for electrochemical detection. Sample preparation is minimal with protein precipitation of serum samples whilst saliva samples are simply diluted with addition of an internal standard. Low-level serum and saliva samples are front-cut on-line with a 3 cm laboratory-made precolumn in the loop position on a standard Valco injection valve. Isocratic separation is achieved on a 250 mm x 4.6 mm I.D. stainless-steel Spherisorb S5 ODS-1 column. The mobile phase for high levels of dapsone is acetonitrile-elution buffer (12:88, v/v) at 2 ml/min and a column temperature of 40 degrees C for both serum and saliva separations. For the low-level assays using electrochemical detection and solid-phase clean-up, the mobile phase is acetonitrile-methanol-elution buffer (9:4:87, v/v/v). The UV and electrochemical detection limits are 25 ng/ml and 200 pg/ml, respectively, in both serum and saliva. This simple method is applicable to the routine monitoring of dapsone levels in serum from leprotic patients and electrochemical detection gives a simple, reliable method for the monitoring of trough values in subjects on anti-malarial prophylaxis.

Oxidative activation of proguanil and dapsone acetylation in Thai soldiers

The prevalence of putative poor metaboliser (PM) phenotypes of proguanil oxidation in Caucasian populations is 3-10%. The PM frequency in Oriental populations is unknown. In this study the plasma metabolic ratios of proguanil and dapsone to their principal metabolites cycloguanil and monoacetyldapsone were determined in Thai soldiers receiving antifolate drug combinations for malaria prophylaxis. The distribution ratio of proguanil to cycloguanil (PROG/CYC) was highly skewed with no evidence of bimodality. Assuming subjects with a PROG/CYC ratio greater than 10 are PMs from studies in Caucasians, the incidence of PMs in the soldiers would be 18% (30 of 170). The mean PROG/CYC ratio for PMs in the Thai soldiers was 31.2 +/- 28.9 (n = 30) compared with 25.5 +/- 2.5 (n = 3) in a study of Caucasians. The corresponding values for putative EMs were 5.4 +/- 2.1 (n = 140) and 2.4 +/- 0.2 (n = 134). Similar to other Oriental populations, Thais were found to be predominantly (76%, 173 of 228) rapid acetylators of dapsone.

Reduction of dapsone hydroxylamine to dapsone during methaemoglobin formation in human erythrocytes in vitro--II. Movement of dapsone across a semipermeable membrane into erythrocytes and plasma

We have used an in vitro two-compartment model, to investigate the ability of dapsone, formed by erythrocyte-mediated detoxification of its hydroxylamine metabolite, to escape the cells and cross a semi-permeable membrane into both plasma and other erythrocytes. Both diethyl dithiocarbamate (DDC) treated and untreated erythrocytes were incubated with dapsone hydroxylamine and dialysed against either fresh cells or plasma. Methaemoglobin was predominantly detectable in compartment A although the presence of low levels of methaemoglobin in compartment B indicated that the hydroxylamine itself had crossed the membrane. In contrast to methaemoglobin disposition, recovery of dapsone was higher (P < 0.05) in compartment B compared with A for all three treatment groups at 30 and 60 min, but not at the remaining time points. Regression analysis of the cumulative recovery of dapsone over 150 min in all three treatment groups for both compartments A and B showed correlation coefficients close to unity. In compartment A, analysis of the mean slopes of the regression lines indicated that, overall, significantly more dapsone was recovered from group 1 (erythrocytes, hydroxylamine and DDC dialysed against untreated red cells) compared with group 3 (erythrocytes and hydroxylamine dialysed against plasma) (0.22 +/- 0.05 vs 0.09 +/- 0.005; P < 0.025). Also in compartment A, significantly more dapsone was recovered from group 2 (erythrocytes and hydroxylamine dialysed against untreated red cells) compared with group 3 (erythrocytes and hydroxylamine dialysed against plasma: 0.16 +/- 0.02 vs 0.09 +/- 0.005). In compartment B, dapsone recovery was significantly greater in group 1 (erythrocytes, hydroxylamine and DDC dialysed against untreated red cells; slope of regression line: 0.59 +/- 0.05) compared with group 2 (erythrocytes and hydroxylamine dialysed against untreated red cells; slope of line: 0.28 +/- 0.02, P < 0.005). In addition, dapsone recovery was significantly greater in group 1 (0.59 +/- 0.05) compared with group 3 (erythrocytes and hydroxylamine dialysed against plasma; 0.21 +/- 0.02, P < 0.005). Dialysis of erythrocytes with dapsone itself over 120 min caused no detectable methaemoglobin formation. The process of erythrocyte-mediated dapsone formation from its hydroxylamine may feasibly occur in vivo and contribute to the systemic persistence and therapeutic effect of dapsone.

Acetylation phenotype and genotype in aboriginal leprosy patients from the north-west region of Western Australia

N-Acetyltransferases (NAT1, NAT2) play an important role in biotransformation of a number of drugs and carcinogens. A polymorphism in the metabolism of such compounds by NAT2 has been known for many years but it is only recently that the underlying molecular genetics has been elucidated. In the present study, we have correlated acetylation phenotype and genotype in a group of 49 Australian Aborigines (26 males and 23 females; mean age = 50.5 yr) from the Derby region of Western Australia. Phenotype was determined using caffeine and genotype by an allele-specific polymerase chain reaction. The percentages of slow and rapid phenotypes were 36.7 and 63.3%, respectively, while the distribution of alleles for the NAT2 gene was 41% for the wildtype and 2, 17 and 40% for the M1, M2 and M3 mutations, respectively. This is the highest proportion of M3 mutations reported for any ethnic population. The observed genotype proportions were not significantly different from those predicted by the Hardy-Weinberg Law (chi 2 = 1.07, p > 0.05). Phenotype was predictable from genotype in 100% of patients. At the time of study, 29 of the Aborigines were receiving acedapsone intramuscularly for control of leprosy. Plasma dapsone concentrations in these patients were similar for both slow (n = 11) and rapid (n = 18) acetylators, suggesting that phenotype is unlikely to influence treatment outcome. The data show that Aborigines have a similar phenotype distribution to that of some Asian populations, but that there are differences in the frequencies of the M1, M2 and M3 mutant alleles.(ABSTRACT TRUNCATED AT 250 WORDS)

Correlation between N-acetyltransferase activity and NAT2 genotype in Chinese males

Eighty-four healthy Chinese male control subjects derived from an occupation-based case-control study of bladder cancer were evaluated for hepatic N-acetyltransferase activity by dapsone and for NAT2 genotype using allele-specific amplification of peripheral leukocyte DNA by the polymerase chain reaction. Fifty-nine percent of the overall variation in acetylation activity was explained by genotype (p < 0.0001). The remaining variation in acetylation was not associated with dapsone N-hydroxylation activity, age, current smoking status, or weight in the study population, or within any genotype subgroup. Although acetylation activity in the homozygous mutant group did not overlap with the other genotype categories, there was moderate overlap in acetylation between the heterozygous mutant and wildtype groups, and substantial variation in acetylation within them. Considering all subjects with the identical NAT2 genotype as phenotypically similar and all subjects with differing NAT2 genotypes as phenotypically distinct may result in misclassification of metabolic risk factors in epidemiological investigations. As such, it would seem prudent, where possible, to collect both acetylation phenotype and NAT2 genotype data, since the advantages and limitations of these two sources of information complement, and serve to assess the accuracy of each other.

Lack of effect of proguanil on the pharmacokinetics of dapsone in healthy volunteers

The multiple-dose kinetics of dapsone (DDS) and its principal metabolite monoacetyldapsone (MADDS) were determined in 6 healthy volunteers after daily administration of low-dose dapsone (10 mg). Comparison with a previous study involving the same volunteers on a daily regimen of proguanil (200 mg) plus dapsone (10 mg) revealed no statistically significant differences in the maximum plasma concentrations, area under the plasma drug concentration curves and elimination half-lives of both DDS and MADDS in the presence of proguanil. Although these findings suggest that proguanil does not alter the pharmacokinetics of DDS and MADDS, the possibility that proguanil affects the disposition of hydroxylated metabolites of dapsone, which appear to mediate dapsone toxicity, cannot be excluded.