The fixed dose combination of trimethoprim and sulfamethoxazole is called cotrimoxazole.
Adverse Drug Reaction, Spectrum, Resistance and Use of Cotrimoxazole.
2. The fixed dose combination of trimethoprim and
sulfamethoxazole is called cotrimoxazole.
Trimethoprim is a diaminopyrimidine related
to the antimalarial drug pyrimethamine which
selectively inhibits bacterial dihydrofolate
reductase (DHFRase).
Cotrimoxazole introduced in 1969 causes sequential
block of folate metabolism.
4. Trimethoprim is >50,000 times more active against
bacterial DHFRase than against the mammalian
enzyme.
Thus, human folate metabolism is not interfered at
antibacterial concentrations of trimethoprim.
individually, both sulfonamide and trimethoprim are
bacteriostatic, but the combination becomes
cidal against many organisms.
5. Maximum synergism is seen when
the organism is sensitive to both the components,
But even when it is
moderately resistant to one component, the action of
the other may be enhanced.
6. Sulfamethoxazole was selected for combining
with trimethoprim because both have
nearly the same t½ (- 10 hr).
Optimal synergy in case of
most organisms is exhibited at a concentration
ratio of sulfamethoxazole 20 : trimethoprim I.
The MIC of each component may be reduced by
3-6 times.
7. This ratio is obtained in the plasma
when the two are given in a dose ratio of
5 : I, because trimethoprim is more lipid
soluble, enters many tissues, has a larger volume
of distribution than sulfamethoxazole and
attains lower plasma concentration.
8. However,
trimethoprim crosses blood-brain barrier and placenta,
while sulfamethoxazole has a poorer entry.
Moreover, trimethoprim
is more rapidly absorbed than sulfamethoxazole
hence
concentration ratios may vary with time.
9. Trimethoprim is 40% plasma protein bound,
while sulfamethoxazole is 65% bound.
10. Spectrum of action
Antibacterial spectra of
trimethoprim and sulfonamides overlap considerably.
Additional organisms covered by the combination are-
Salmonella typhi,
Serratia,
Klebsiella,
Enterobacter,
Yersinia enterocolitica,
Pneumocystis jiroveci
11. Many sulphonamide resistant strains
Staph. aureus,
Strep. pyogenes
Shigella,
Eteropathogenic E. coli,
H.inftuenzae,
Gonococci and
Meningococci.
12. Resistance
Bacteria are capable of acquiring
resistance to trimethoprim mostly through plasmid
mediated acquisition of a DHFRase
having lower affinity for the inhibitor.
Resistance to the combination has been slow to
develop
compared to either drug alone,
but widespread
use of the combination over a long period has
resulted in reduced responsiveness of over 30%
13. Adverse effects
All adverse effects seen
with sulfonamides can be produced by cotrimoxazole.
Nausea, vomiting, stomatitis, headache and
rashes are the usual manifestations.
Folate deficiency (megaloblastic anaemia)
is infrequent, occurs only in patients with
marginal folate levels.
14. Blood dyscrasia occurs rarely.
Cotrimoxazole should not be given during
pregnancy. Trimethoprim being an antifolate,
there is theoretical teratogenic risk.
Neonatal haemolysis and
methaemoglobinaemia can occur
15. Patients with renal disease may develop uremia.
Dose should be reduced in moderately
severe renal impairment.
A high incidence (upto 50%) of fever, rash
and bone marrow hypoplasia has been reported
among AIDS patients with Pneumocystis
jiroveci infection when treated with high
dose cotrimoxazole
16. The elderly are also at greater risk of bone
marrow toxicity from cotrimoxazole.
Diuretics given with cotrimoxazole have produced
a higher incidence of thrombocytopenia.