The use of cimetidine as a selective inhibitor of dapsone N-hydroxylation in man.

1. The N-hydroxylation of dapsone is thought to be responsible for the methaemoglobinaemia and haemolysis associated with this drug. We wished to investigate the effect of concurrent administration of cimetidine (400 mg three times per day) on the disposition of a single dose (100 mg) of dapsone in seven healthy volunteers in order to inhibit selectively N-hydroxylation. 2. The AUC of dapsone (31.0 +/- 7.2 micrograms ml-1 h) was significantly increased (P less than 0.001) in the presence of cimetidine (43.3 +/- 8.8 micrograms ml-1 h). 3. Peak methaemoglobin levels observed after dapsone administration (2.5 +/- 0.6%) were significantly (P less than 0.05) reduced in the presence of cimetidine (0.98 +/- 0.35%). 4. The percentage of the dose excreted in urine as the glucuronide of dapsone hydroxylamine was significantly (P less than 0.05) reduced in the presence of cimetidine (34.2 +/- 9.3 vs 23.1 +/- 4.2%). 5. Concurrent cimetidine therapy might reduce some of the haematological side-effects of dapsone.     

The use of cimetidine to reduce dapsone-dependent methaemoglobinaemia in dermatitis herpetiformis patients.

1. We have attempted to reduce dapsone-dependent methaemoglobinaemia formation in six dermatitis herpetiformis patients stabilised on dapsone by the co-administration of cimetidine. 2. In comparison with control, i.e. dapsone alone, methaemoglobinaemia due to dapsone fell by 27.3 +/- 6.7% and 26.6 +/- 5.6% the first and second weeks after commencement of cimetidine administration. The normally cyanotic appearance of the patient on the highest dose of dapsone (350 mg day-1), underwent marked improvement. 3. There was a significant increase in the trough plasma concentration of dapsone (2.8 +/- 0.8 x 10(-5)% dose ml-1) at day 21 in the presence of cimetidine compared with control (day 7, 1.9 +/- 0.6 x 10(-5)% dose ml-1, P less than 0.01). During the period of the study, dapsone-mediated control of the dermatitis herpetiformis in all six patients was unchanged. 4. Trough plasma concentrations of monoacetyl dapsone were significantly increased (P less than 0.05) at day 21 (1.9 +/- 1.0 x 10(-5)% dose ml-1) compared with day 7 (1.6 +/- 0.9 x 10(-5)% dose ml-1:control). 5. Over a 12 h period, 20.6 +/- 8.9% (day 0) of a dose of dapsone was detectable in urine as dapsone hydroxylamine. Significantly less dapsone hydroxylamine was recovered from urine at day 14 (15.0 +/- 8.4) in the presence of cimetidine, compared with day 0 (control: P less than 0.05). 6. The co-administration of cimetidine may be of value in increasing patient tolerance to dapsone, a widely used, effective, but comparatively toxic drug.     

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

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.     

A Dapsone-induced Blood Dyscrasia in the Mouse: Evidence for the Role of an Active Metabolite

In the female mouse, dapsone (50–500 mg kg^?1, p.o.) caused a dose-related methaemoglobinaemia which peaked at 0m?5-1 h with recovery to baseline values occurring by 4h. Cimetidine (100 mg kg^?1, p.o.), a known inhibitor of several hepatic P450 isozymes administered 1 h before dapsone, prevented the methaemoglobinaemia. In-vitro, dapsone required activation by mouse hepatic microsomes to cause methaemoglobin formation in mouse erythrocytes and cytotoxicity to human mononuclear leucocytes. In both instances, the toxic effects were markedly reduced by cimetidine. Daily dosing of mice with dapsone (50 mg kg^?1, p.o.) for 3 weeks induced a blood dyscrasia, characterized by a fall of platelet and white blood cell counts, which was inhibited by cimetidine (100 mg kg^?1, p.o. daily). It is concluded that an active metabolite of dapsone arising from a P450-dependent pathway is involved in the genesis not only of the methaemoglobinaemia but also the blood dyscrasia arising from repeated administration of the drug in this species.     

Dapsone toxicity: Some current perspectives

• 1.1. Dapsone is a potent anti-inflammatory and anti-parasitic compound, which is metabolised by cytochrome P-450 to hydroxylamines, which in turn cause methaemoglobinaemia and haemolysis. However, during the process of methaemoglobin formation, erythrocytes are capable of detoxifying the hydroxylamine to the parent drug, which may either reach the tissues to exert a therapeutic effect or return to the liver and be re-oxidised in a form of systemic cycling. This glutathione-dependent effect, combined with the un-ionised state of the drug at physiological pH, may contribute to its efficacy.
• 2.2. Paradoxically, other aspects of the glutathione-dependent cycling of the hydroxylamine metabolite may contribute to the major adverse reaction of the drug, agranulocytosis. Erythrocytes exposed to the metabolite and repeatedly washed may still release the hydroxylamine in sufficient concentration to kill mononuclear leucocytes in vitro. Thus, erythrocytes may be a conduit for the hydroxylamine to reach the bone marrow to covalently bind to granulocyte precursors, which may trigger an immune response in certain individuals and may lead to the potentially fatal eradication of granulocytes from the circulation.
• 3.3. Attempts to increase patient tolerance to dapsone have been most successful using a metabolic inhibitor to reduce hepatic oxidation of the drug to the hydroxylamine. Methaemoglobin formation in the presence of cimetidine was maintained at 30% below control levels for almost 3 mo, and patients' reported side effects such as headache and lethargy were significantly reduced.
• 4.4. As clinical application of new and safer dapsone analogues is years away, the use of cimetidine provides an immediate route to increasing patient compliance during dapsone therapy, especially in those maintained on dapsone dosages in excess of 200 mg/day.

     

Inhibition of dapsone-induced methaemoglobinaemia by cimetidine in the rat during chronic dapsone administration.

Dapsone undergoes N-acetylation to monoacetyl dapsone as well as N-hydroxylation to a hydroxylamine which is responsible for the haemotoxicity (i.e. methaemoglobinaemia; Met Hb) of the drug. Since dapsone is always given chronically, we have investigated the ability of cimetidine to inhibit Met Hb formation caused by repeated dapsone administration. The drug was given (i.p.) to four groups (n = 6 per group) of male Wistar rats, 300-360 g. Group I received 10 mg kg-1 at 1, 24, 48 and 72 h. Group II received 10 mg kg-1 at 1, 8, 24, 32, 48, 56, 72 and 80 h. Groups III and IV received the drug as for groups I and II, respectively, as well as cimetidine (50 mg kg-1) 1 h before each dose of dapsone. Twice daily dapsone administration (Group II) resulted in a significantly greater (P less than 0.05) Met Hb AUC (757 +/- 135 vs 584 +/- 115% Met Hb h), dapsone AUC (140 +/- 17.5 vs 113 +/- 13.0 micrograms h mL-1) and monoacetyl dapsone AUC (48.2 +/- 18.3 vs 10.8 +/- 4.6 micrograms h mL-1) compared with a single daily dapsone dose (group I). The administration of cimetidine before the once daily dose of dapsone (group III) resulted in a significant (P less than 0.05) fall in Met Hb (302 +/- 179 vs 584 +/- 115% Met Hb h) and an increase in both the dapsone (151 +/- 22.2 vs 113 +/- 13.0 micrograms h mL-1) and monoacetyl dapsone AUC values (33.6 +/- 5.8 vs 10.8 +/- 4.0 micrograms h mL-1) compared with a single daily dose of dapsone (group I).(ABSTRACT TRUNCATED AT 250 WORDS)     

An investigation of the role of metabolism in dapsone-induced methaemoglobinaemia using a two compartment in vitro test system.

1. We have utilized a two compartment system in which two teflon chambers are separated by a semi-permeable membrane in order to investigate the role of metabolism in dapsone-induced methaemoglobinaemia. Compartment A contained a drug metabolizing system (microsomes prepared from human liver +/- NADPH), whilst compartment B contained target cells (human red cells). 2. Incubation of dapsone (1-100 microM) with human liver microsomes (2 mg protein) and NADPH (1 mM) in compartment A (final volume 500 microliters) led to a concentration-dependent increase in the methaemoglobinaemia (15.4-18.9% at 100 microM) compared with control (2.3 +/- 0.4%) detected in the red cells within compartment B. In the absence of NADPH dapsone had no effect. 3. Of the putative dapsone metabolites investigated, only dapsone-hydroxylamine caused methaemoglobin formation in the absence of NADPH (40.6 +/- 6.3% with 100 microM). However, methaemoglobin was also detected when monoacetyl-dapsone, 4-amino-4'-nitro-diphenylsulphone and 4-aminoacetyl-4'-nitro-diphenylsulphone were incubated with human liver microsomes in the presence of NADPH. 4 Dapsone-dependent methaemoglobin formation was inhibited by addition of ketoconazole (1-1000 microM) to compartment A, with IC50 values of 285 and 806 microM for the two liver microsomal samples studied. In contrast, methaemoglobin formation was not inhibited by cimetidine or a number of drugs pharmacologically-related to dapsone. The presence of glutathione or ascorbate (500 microM) did not alter the level of methaemoglobin observed.     

Bioactivation of benzocaine to a methaemoglobin-forming metabolite by rat and human microsomes in vitro

Benzocaine-mediated methaemoglobin-generation was compared with that of dapsone in vitro. Direct incubation of benzocaine with washed human erythrocytes alone at up to 15 mM did not result in significant methaemoglobin formation (0.4 ± 0.1%). With rat microsomes, dapsone-dependent methaemoglobin formation was almost two-fold that of benzocaine at 30 min (56.5 ± 0.7% vs 31.6 ± 2.4% P < 0.005)). Benzocaine-mediated methaemoglobin formation was significantly reduced in the presence of DDC (diethyldithiocarbamate) at the 10 (P < 0.005) and 20 (P < 0.025) min time points. At 30 min, cimetidine reduced benzocaine-mediated methaemoglobin from 34.4 ± 8.7% to less than 3% (P < 0.005). The methaemoglobin forming capacity of dapsone was significantly inhibited at all three time points by both DDC (P < 0.005) and cimetidine (P < 0.005). Incubation of benzocaine with microsomes from five human livers showed that each liver produced methaemoglobin-forming metabolites. No inhibitory effect was seen with DDC, although cimetidine caused a significant reduction (32.8 ± 12.4% overall) in benzocaine-mediated methaemoglobin formation in the four livers tested.     

Inhibition of dapsone-induced methaemoglobinaemia in the rat isolated perfused liver

We have investigated the disposition of dapsone (DDS, 1 mg) in the rat isolated perfused liver in the absence and the presence of cimetidine (3 mg). After the addition of DDS alone to the liver there was a monoexponential decline of parent drug concentrations and rapid formation of DDS-NOH (within 10 min) which coincided with methaemoglobin formation (11.7 +/- 3.0%, mean +/- s.d.) which reached a maximum (22.6 +/- 9.2%) at 1 h. The appearance of monoacetyl DDS (MADDS) was not apparent until 30-45 min. Addition of cimetidine resulted in major changes in the pharmacokinetics of DDS and its metabolites. The AUC of DDS in the presence of cimetidine (1018.8 +/- 267.8 micrograms min mL-1) was almost three-fold higher than control (345.0 +/- 68.1 micrograms min mL-1, P less than 0.01). The half-life of DDS was also prolonged by cimetidine compared with control (117.0 +/- 48.2 min vs 51.2 +/- 22.9, P less than 0.05). The clearance of DDS (3.0 +/- 0.55 mL min-1) was greatly reduced in the presence of cimetidine (1.03 +/- 0.26 mL min-1 P less than 0.01). The AUC0-3h for DDS-NOH (28.3 +/- 21.2 micrograms min mL-1) was significantly reduced by cimetidine (8.1 +/- 3.40 micrograms min mL-1, P less than 0.01). In contrast, there was a marked increase in the AUC0-3h for MADDS (32.7 +/- 25.8 micrograms min mL-1) in the presence of cimetidine (166.0 +/- 26.5 micrograms min mL-1 P less than 0.01). The methaemoglobinaemia associated with DDS was reduced to below 5% by cimetidine. Hence, a shift in hepatic metabolism from bioactivation (N-hydroxylation) to detoxication (N-acetylation) caused by cimetidine, was associated with a fall in methaemoglobinaemia. These data suggest that the combination of DDS with a cytochrome P450 inhibitor might reduce the risk to benefit ratio of DDS.     

Studies on the differential sensitivity between diabetic and non-diabetic human erythrocytes to monoacetyl dapsone hydroxylamine-mediated methaemoglobin formation in vitro

Methaemoglobin generation by monoacetyl dapsone hydroxylamine in non-diabetic and diabetic erythrocytes was investigated in vitro. Methaemoglobin formation in purified haemoglobin isolated from both types of erythrocytes as well as haemolysates from both diabetic and non-diabetic erythrocytes did not differ. Prior to 18 h incubation with 10 and 20 mM glucose diabetic erythrocytes were significantly less sensitive to monoacetyl dapsone-induced methaemoglobinaemia. After pre-incubation the differential was lost although significant change in glutathione concentrations could not be shown between the two cell types. NADH-diaphorase levels measured in diabetics and non-diabetics did not significantly differ. It is possible that diabetic cells display reduced hydroxylamine-mediated methaemoglobin generation due to differences in glutathione metabolism.     

Studies on the toxicity and efficacy of some ester analogues of dapsone in vitro using rat and human tissues

The toxicity and efficacy of a series of 13 anti-tubercular sulphone esters has been evaluated using human and rat tissues. The toxicity studies involved comparison of the esters' ability to generate rat microsomally mediated NADPH-dependent methaemoglobin with that of dapsone. All the compounds formed significantly less methaemoglobin in the 1 compartment studies compared with dapsone itself. The ethyl, propyl, 3-methyl-butyl cyclopentyl esters and the carboxy parent derivative all yielded less than 5% of the methaemoglobin generated by dapsone. The 3-nitro benzoic acid ethyl and propyl esters generated 30 and 25% of dapsone's methaemoglobin formation. A similar effect was seen in the 2 compartment system, except for the butyl ester, which yielded similar haemoglobin oxidation to dapsone. The low toxicity ethyl and propyl esters, were also low in toxicity using human liver microsomes, producing less than 30% of the dapsone mediated methaemoglobin. All the compounds except the benzoic acid parent were superior to dapsone in terms of suppression of human neutrophil respiratory burst using a lucigenin-based chemiluminescence assay. The most potent derivatives were the phenyl, propyl and 3-nitro benzoic acid ethyl esters, which were between two- and threefold more potent compared with dapsone in arresting the respiratory burst. Overall, the ethyl ester showed the best combination of low toxicity in the rat and human microsomal systems and its IC(50) was approximately 40% lower than that of dapsone in neutrophil respiratory burst inhibition. These compounds indicate some promise for future development in their superior anti-inflammatory capability and lower toxicity compared with the parent sulphone, dapsone.     

The use of a three compartment in vitro model to investigate the role of hepatic drug metabolism in drug-induced blood dyscrasias.

1. N-hydroxylation is thought to be an essential step in the haemotoxicity of dapsone (DDS). To investigate both metabolism-dependent and cell-selective drug toxicity in vitro we have developed a three-compartment system in which an hepatic drug metabolizing system is contained within a central compartment separated by semipermeable membranes from compartments containing mononuclear leucocytes (MNL) and red blood cells (RBC). 2. Metabolism of dapsone (100 microM) by rat liver microsomes resulted in toxicity to RBC cells (47.3 +/- 2.1% methaemoglobin), but there was no significant toxicity toward MNL (3.7 +/- 1.3% cell death) compared with control values (1.6 +/- 0.9%). However, when RBC were replaced with buffer in the third compartment there was significantly greater (P < 0.001) white cell toxicity (17.6 +/- 0.6% cell death), demonstrating the protection of MNL by RBC. Metabolism of dapsone by human liver microsomes again resulted in RBC toxicity (12.5 +/- 3.3% methaemoglobin) but no significant MNL toxicity (2.9 +/- 0.8% cell death). Replacement of RBC resulted in a significant (P < 0.001) increase in MNL toxicity (6.5 +/- 0.7% cell death). Addition of synthetic dapsone hydroxylamine (30 microM) in the absence of a metabolizing system and with no RBC in the third compartment resulted in significant (P < 0.001) toxicity toward MNL (43.36 +/- 5.82% cell death) compared with control (1.8 +/- 1.1%). The presence of RBC in the third compartment resulted in a significant (P < 0.001) decrease in MNL toxicity (17.6 +/- 2.2% cell death), with 40.1 +/- 3.7% methaemoglobin in the RBC.(ABSTRACT TRUNCATED AT 250 WORDS)     

N-Hydroxylation of dapsone by multiple enzymes of cytochrome P450: implications for inhibition of haemotoxicity.

1. The adverse reactions associated with the administration of dapsone are believed to be caused by metabolism to its hydroxylamine. Previous reports suggest that CYP3A4 is responsible for this biotransformation [1]. 2. Data presented in this paper illustrate the involvement of more than one cytochrome P450 enzyme in dapsone hydroxylamine formation using human liver microsomes. Eadie-Hofstee plots demonstrated bi-phasic kinetics in several livers. No correlation could be established between hydroxylamine formation and CYP3A concentrations in six human livers (r = -0.47; P = 0.34). 3. Studies with low molecular weight inhibitors illustrate the importance of CYP2C9 and CYP3A in dapsone N-hydroxylation. 4. Differential sensitivity of dapsone N-hydroxylation to selective CYP inhibitors indicated that the contribution of individual CYP enzymes varies between livers. Selective inhibition ranged from 6.8 to 44.1% by 5 microM ketoconazole, and from 24.0 to 68.4% by 100 microM sulphaphenazole. The extent of inhibition, by either ketoconazole or sulphaphenazole was dependent on the CYP3A content of the liver. 5. The levels of expression of these cytochrome P450 enzymes may be an important determinant of individual susceptibility to the toxic effects of dapsone, and may influence the ability of an enzyme inhibitor to block dapsone toxicity in vivo. Because of the inability to produce complete inhibition, selective CYP inhibitors are unlikely to offer any clinical advantage over cimetidine in decreasing dapsone hydroxylamine formation in vivo.     

Bioactivation of the cyanide antidote 4-aminopropiophenone (4-PAPP) by human and rat hepatic microsomal enzymes: effect of inhibitors

The bioactivation of the cyanide antidote methaemoglobin former 4-aminopropiophenone (4-PAPP) was studied using rat and human microsomes. With rat liver and NADPH in single and two-compartment systems, dapsone and benzocaine were more potent methaemoglobin generators compared with 4-PAPP. In the single compartment studies, the order of potency of inhibition of 4-PAPP-mediated methaemoglobin formation was cimetidine (1.5 mM)>isoniazid (500 μM)/diethyldithiocarbamate (DDC, 1 mM)>erythromycin (500 μM). Human liver microsomal activation of 4-PAPP in the two-compartment system was partially inhibited by both DDC and cimetidine. These preliminary studies suggest that 4-PAPP may be metabolised by CYP 2C11, 2E1 and 3A in the rat and CYP 2C, 2E1 and probably 3A4 in man.     

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.     

Inhibition of dapsone-induced methaemoglobinaemia by cimetidine in the presence of trimethoprim in the rat.

Administration of dapsone in combination with trimethoprim and cimetidine to male rats resulted in a marked decrease (P less than 0.05) in measured methaemoglobin levels (46.2 +/- 24% Met Hb h) compared with administration of dapsone alone (124.5 +/- 24.4% Met Hb h). The elimination half-life of dapsone (814 +/- 351 min) was more than doubled in the presence of trimethoprim and cimetidine compared with control (355 +/- 160 min, P less than 0.05). However, there were no significant differences in AUC and clearance when dapsone was administered in combination with trimethoprim and cimetidine compared with dapsone alone. Co-administration of trimethoprim with dapsone in the absence of cimetidine did not affect either methaemoglobin formation, AUCs, half-lives, or clearance values of dapsone compared with control. There was a threefold increase in the AUC of trimethoprim (6296 +/- 2249 micrograms min mL-1) in the presence of dapsone compared with trimethoprim alone (2122 +/- 552 micrograms min mL-1). There was also a corresponding decrease in the clearance of trimethoprim in the presence of dapsone compared with control (19.1 +/- 6.9 vs 60.8 +/- 21.0 mL min-1). However, there was no change in the elimination half-life of trimethoprim between the two experimental groups (273 +/- 120 vs 292 +/- 54 min). The AUC of trimethoprim increased more than threefold in the presence of cimetidine (7100 +/- 1501 micrograms min mL-1) compared with trimethoprim alone (2122 +/- 552 micrograms min mL-1).(ABSTRACT TRUNCATED AT 250 WORDS)     

Methaemoglobin formation due to nitrite, disulfiram, 4-aminophenol and monoacetyldapsone hydroxylamine in diabetic and non-diabetic human erythrocytes in vitro

Nitrite, monoacetyl dapsone hydroxylamine, 4-aminophenol and disulfiram-mediated methaemoglobin formation was studied in human diabetic and non-diabetic erythrocytes in vitro. Diabetic intact erythrocytes were significantly less sensitive compared with those of non-diabetics to haemoglobin oxidation caused by the hydroxylamine, nitrite and 4-aminophenol, but not disulfiram. In haemolysates, differential sensitivity did occur with disulfiram and was partially retained with 4-aminophenol and nitrite. The differences were lost with 4-aminophenol, nitrite and disulfiram in the presence of haemoglobin purified from the respective erythrocyte types. Diethyl maleate reduced methaemoglobin formation in non-diabetic intact erythrocytes with 4-aminophenol, the hydroxylamine and disulfiram, but not with nitrite. Overall, the differential sensitivity to methaemoglobin formation seen in diabetic compared with non-diabetic erythrocytes, is probably linked to differences in the respective cells' cytosolic anti-oxidant systems.     

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

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.     

Occupational methaemoglobinaemia. Mechanisms of production, features, diagnosis and management including the use of methylene blue

Methaemoglobin is formed by oxidation of ferrous (FeII) haem to the ferric (FeIII) state and the mechanisms by which this occurs are complex. Most cases are due to one of three processes. Firstly, direct oxidation of ferrohaemoglobin, which involves the transfer of electrons from ferrous haem to the oxidising compound. This mechanism proceeds most readily in the absence of oxygen. Secondly, indirect oxidation, a process of co-oxidation which requires haemoglobin-bound oxygen and is involved, for example, in nitrite-induced methaemoglobinaemia. Thirdly, biotransformation of a chemical to an active intermediate that initiates methaemoglobin formation by a variety of mechanisms. This is the means by which most aromatic compounds, such as amino- and nitro-derivatives of benzene, produce methaemoglobin. Methaemoglobinaemia is an uncommon occupational occurrence. Aromatic compounds are responsible for most cases, their lipophilic nature and volatility facilitating absorption during dermal and inhalational exposure, the principal routes implicated in the workplace. Methaemoglobinaemia presents clinically with symptoms and signs of tissue hypoxia. Concentrations around 80% are life-threatening. Features of toxicity may develop over hours or even days when exposure, whether by inhalation or repeated skin contact, is to relatively low concentrations of inducing chemical(s). Not all features observed in patients with methaemoglobinaemia are due to methaemoglobin formation. For example, the intravascular haemolysis caused by oxidising chemicals such as chlorates poses more risk to life than the methaemoglobinaemia that such chemicals induce. If an occupational history is taken, the diagnosis of methaemoglobinaemia should be relatively straightforward. In addition, two clinical observations may help: firstly, the victim is often less unwell than one would expect from the severity of 'cyanosis' and, secondly, the 'cyanosis' is unresponsive to oxygen therapy. Pulse oximetry is unreliable in the presence of methaemoglobinaemia. Arterial blood gas analysis is mandatory in severe poisoning and reveals normal partial pressures of oxygen (pO2) and carbon dioxide (pCO2,), a normal 'calculated' haemoglobin oxygen saturation, an increased methaemoglobin concentration and possibly a metabolic acidosis. Following decontamination, high-flow oxygen should be given to maximise oxygen carriage by remaining ferrous haem. No controlled trial of the efficacy of methylene blue has been performed but clinical experience suggests that methylene blue can increase the rate of methaemoglobin conversion to haemoglobin some 6-fold. Patients with features and/or methaemoglobin concentrations of 30-50%, should be administered methylene blue 1-2 mg/kg/bodyweight intravenously (the dose depending on the severity of the features), whereas those with methaemoglobin concentrations exceeding 50% should be given methylene blue 2 mg/kg intravenously. Symptomatic improvement usually occurs within 30 minutes and a second dose of methylene blue will be required in only very severe cases or if there is evidence of ongoing methaemoglobin formation. Methylene blue is less effective or ineffective in the presence of glucose-6-phosphate dehydrogenase deficiency since its antidotal action is dependent on nicotinamide-adenine dinucleotide phosphate (NADP+). In addition, methylene blue is most effective in intact erythrocytes; efficacy is reduced in the presence of haemolysis. Moreover, in the presence of haemolysis, high dose methylene blue (20-30 mg/kg) can itself initiate methaemoglobin formation. Supplemental antioxidants such as ascorbic acid (vitamin C), N-acetylcysteine and tocopherol (vitamin E) have been used as adjuvants or alternatives to methylene blue with no confirmed benefit. Exchange transfusion may have a role in the management of severe haemolysis or in G-6-P-D deficiency associated with life-threatening methaemoglobinaemia where methylene blue is relatively contraindicated.     

Occupational Methaemoglobinaemia

Methaemoglobin is formed by oxidation of ferrous (Fe^II) haem to the ferric (F^III) state and the mechanisms by which this occurs are complex. Most cases are due to one of three processes. Firstly, direct oxidation of ferrohaemoglobin, which involves the transfer of electrons from ferrous haem to the oxidising compound. This mechanism proceeds most readily in the absence of oxygen. Secondly, indirect oxidation, a process of co-oxidation which requires haemoglobin-bound oxygen and is involved, for example, in nitrite-induced methaemoglobinaemia. Thirdly, biotransformation of a chemical to an active intermediate that initiates methaemoglobin formation by a variety of mechanisms. This is the means by which most aromatic compounds, such as amino- and nitro-derivatives of benzene, produce methaemoglobin. Methaemoglobinaemia is an uncommon occupational occurrence. Aromatic compounds are responsible for most cases, their lipophilic nature and volatility facilitating absorption during dermal and inhalational exposure, the principal routes implicated in the workplace. Methaemoglobinaemia presents clinically with symptoms and signs of tissue hypoxia. Concentrations around 80% are life-threatening. Features of toxicity may develop over hours or even days when exposure, whether by inhalation or repeated skin contact, is to relatively low concentrations of inducing chemical(s). Not all features observed in patients with methaemoglobinaemia are due to methaemoglobin formation. For example, the intravascular haemolysis caused by oxidising chemicals such as chlorates poses more risk to life than the methaemoglobinaemia that such chemicals induce. If an occupational history is taken, the diagnosis of methaemoglobinaemia should be relatively straightforward. In addition, two clinical observations may help: firstly, the victim is often less unwell than one would expect from the severity of ‘cyanosis’ and, secondly, the ‘cyanosis’ is unresponsive to oxygen therapy. Pulse oximetry is unreliable in the presence of methaemoglobinaemia. Arterial blood gas analysis is mandatory in severe poisoning and reveals normal partial pressures of oxygen (pO₂) and carbon dioxide (pCO₂,), a normal ‘calculated’ haemoglobin oxygen saturation, an increased methaemoglobin concentration and possibly a metabolic acidosis. Following decontamination, high-flow oxygen should be given to maximise oxygen carriage by remaining ferrous haem. No controlled trial of the efficacy of methylene blue has been performed but clinical experience suggests that methylene blue can increase the rate of methaemoglobin conversion to haemoglobin some 6-fold. Patients with features and/or methaemoglobin concentrations of 30–50%, should be administered methylene blue 1–2 mg/kg/bodyweight intravenously (the dose depending on the severity of the features), whereas those with methaemoglobin concentrations exceeding 50% should be given methylene blue 2 mg/kg intravenously. Symptomatic improvement usually occurs within 30 minutes and a second dose of methylene blue will be required in only very severe cases or if there is evidence of ongoing methaemoglobin formation. Methylene blue is less effective or ineffective in the presence of glucose-6-phosphate dehydrogenase deficiency since its antidotal action is dependent on nicotinamide-adenine dinucleotide phosphate (NADP⁺). In addition, methylene blue is most effective in intact erythrocytes; efficacy is reduced in the presence of haemolysis. Moreover, in the presence of haemolysis, high dose methylene blue (20–30 mg/kg) can itself initiate methaemoglobin formation. Supplemental antioxidants such as ascorbic acid (vitamin C), N-acetylcysteine and tocopherol (vitamin E) have been used as adjuvants or alternatives to methylene blue with no confirmed benefit. Exchange transfusion may have a role in the management of severe haemolysis or in G-6-P-D deficiency associated with life-threatening methaemoglobinaemia where methylene blue is relatively contraindicated.