A Textbook of Clinical Pharmacology and Therapeutics

MYCOBACTERIUMLEPRAEINFECTION 339

MYCOBACTERIUM LEPRAEINFECTION

Leprosy manifests in two forms, lepromatoid (the organism
being localized to skin or nerve) or lepromatous (a general-
ized bacteraemic disease that effects many organs, analogous
to miliary tuberculosis). The main drugs used to treat leprosy
are dapsone,rifampicinandclofazimine. The current World
Health Organization (WHO) regimen for multibacillary
leprosy is:

1. rifampicin, once a month;
   2.dapsone, daily unsupervised given for 24 months;
   3.clofazimine, daily unsupervised, plus a larger dose under
   supervision every four weeks.

Other anti-lepromatous drugs include ofloxacin, mino-
cycline,clarithromycin(see Chapter 43) and thalidomide.

DAPSONE

Uses

Dapsone(4,4-diaminodiphenyl sulphone) is a bacteriostatic
sulphone. It has been the standard drug for treating all forms
of leprosy, but irregular and inadequate duration of treatment
as a single agent has produced resistance. Dapsoneis used to
treat dermatitis herpetiformis, as well as leprosy, pneumocystis
and, combined with pyrimethamine, for malaria prophylaxis.

Mechanism of action

Dapsoneis a competitive inhibitor of dihydropteroate (folate)
synthase, thereby impairing production of dihydrofolic acid.

Adverse effects

These include:

• anaemia and agranulocytosis;


• gastro-intestinal disturbances and (rarely) hepatitis;


• allergy and rashes, including Stevens–Johnson
  syndrome;


• peripheral neuropathy;


• methaemoglobinaemia;


• haemolytic anaemia, especially in glucose-6-phosphate
  dehydrogenase (G6PDH)-deficient patients.

Pharmacokinetics

Dapsone is well absorbed (90%) from the gastro-intestinal
tract. The t1/2is on average 27 hours. It is extensively metabo-
lized in the liver, partly by N-acetylation, with only 10–20% of
the parent drug being excreted in the urine. There is some
enterohepatic circulation.

Drug interactions

The metabolism of dapsoneis increased by hepatic enzyme
inducers (e.g. rifampicin) such that its t1/2is reduced to 12–15
hours.

FURTHER READING

Joint Tuberculosis Committee of the British Thoracic Society. Control

and prevention of tuberculosis in the United Kingdom: code of

practice 2000. Thorax2000; 55 : 887–901.

Joint Tuberculosis Committee Guidelines 1999. Management of

opportunist mycobacterial infections: Subcommittee of the Joint

Tuberculosis Committee of the British Thoracic Society. Thorax

2000; 55 : 210–8.

Joint Tuberculosis Committee of the British Thoracic Society.

Chemotherapy and management of tuberculosis in the United

Kingdom: recommendations 1998. Thorax1998; 53 : 536–48.

Case history

A 27-year old Asian woman presents to her physician with a

history of streaky haemoptysis and weight loss for the past

two months. Clinical examination is reported as normal. Her

chest x-ray shows patchy right upper lobe consolidation and

her sputum is positive for acid-fast bacilli. After having

obtained three sputum samples, she is started, while in hos-

pital, on a four-drug regimen, pyrazinamide (800 mg/day),

ethambutol (600 mg/day), isoniazid (300 mg/day) and

rifampicin (450 mg/day). She is also prescribed pyridoxine

10 mg daily (to reduce the likelihood of developing periph-

eral neuropathy secondary to INH). She tolerates the ther-

apy well, without evidence of hepatic dysfunction, and her

systemic symptoms improve. Three months later, when

reviewed in the outpatient clinic, she has been off pyrazi-

namide and ethambutol for just over one month, and she

complains of daily nausea and vomiting, and is found to be

eight weeks pregnant. She is taking the low-dose oestrogen

contraceptive pill and is adamant that she has been meticu-

lously compliant with all of her anti-TB medications and the

contraceptive pill.

Question

What therapeutic problem has occurred here and how can

you explain the clinical situation?

How could this outcome have been avoided?

Answer

Ethambutol, isoniazid, rifampicin and pyrazinamide are all

inducers of hepatic CYP450 enzymes. Rifampicin is most

potent. and affects many CYPs. Over a period of several

weeks her drug therapy induced several CYP450 isoenzymes,

especially CYP3A4, so that hepatic metabolism of oestrogen

and progesterone was markedly enhanced, reducing their

systemic concentrations and efficacy as contraceptives.

Therefore, drug-induced hepatic CYP450 enzyme induction

caused a failure of contraceptive efficacy and so the patient

was ‘unprotected’ and became pregnant. The patient should

continue on her anti-TB drug regimen, as there is no evi-

dence that these agents are harmful to the developing fetus,

except for streptomycin, which should never be given in

pregnancy.

This outcome could have been prevented by advising the

patient to double her usual dose of her oral contraceptives

while taking anti-TB therapy, and to take additional contra-

ceptive precautions (e.g. barrier methods), or to abandon

the pill altogether and use alternative effective contracep-

tive measures (e.g. an intrauterine contraceptive device)

during her anti-TB drug treatment.