antimycobacterial Flashcards
mycobacterium clinical manifestations
TB (M. tuberculosis), Leprosy (M. leprae)
Pulomonary, intestinal mucosa and lymph nodes: M. avium-intracellulare (fatal in AIDS pts)
challenges to antimycobacterial therapy
Cells grow slowly ( difficult to kill, grow, identify, and do susceptibility testing), very lengthy therapy, chronic disease, intracellular forms
Spontaneous resistance- requires multi drug therapy
goals- convert cultures to negative in shortest possible time, prevent emergence of drug resistance, assure complete cure without relapse
tuberculosis
disease- primarily pulmonary can disseminate into CNS, M . tuberculosis is 90% the problem, M. avium intracellulare (MAI) is a serious problem in AIDS patients
Diagnosis- TB skin test (positive prior to symptoms), X-ray, acid fast stain/culture
first line drugs used in TB
isoniazid, rifampin, rifabutin, ethambutol, pyrazinamide, streptomycin
isoniazid
Nicotinic acid derviative,
MOA: bactericidal for actively growing bacilli, bacteriostatic for resting cells
Inhibits synthesis of mycolic acids- isoniazid is a prodrug that is activatated by catalase peroxidase (Kat G) of the tubercle bacillus, the activated drugs target is the enoyl- acyl carrier protein reductase (blocks InhA protein, blocking fatty acid elongation and therefore mycolic acid synthesis)
Resistant strains often result from mutation in KatG or InhA
Uses: all pts with INH-sensitive strains should receive INH if possible, for treatment always given w/ other agents
Absorption/excretion: rapidly absorbed, N- acetylation is under genetic control, N acetyltransferase-2 polymorphisms (slow acetylators longer half life, rapid acetylators short)
SEs: neurotoxicity esp peripheral neuritis- significantly improved with B6 admin, hepatotoxicity
rifampin
MOA: inhibits bacterial RNA synthesis by binding to RNA Polymerase beta, bactericidal
never used alone always w/ isoniazid
SE: hepatotoxicity, potent inducer of multiple CYPs and metabolsim is increased of other drugs, orange-red color to bodily fluids
Ethambutol
MOA: interferes arabinosyl transferase, blocking cell wall synthesis, tuberculostatic
Absorbed well into CSF
SE: not heptatotoxic , optic neuritis, uric acid increase
Pyrazinamide
MOA: blocks mycolic acid synthesis by inhibiting fatty acid synthase 1, bactericidal
Uses: combination therapy, important component of short term multi drug therapy
absorption/excretion: widely distributed including CSF
SE: hepatic damage especially when combined with rifampin, drug fever, hyper uricemia
Streptomycin
MOA: binds to several ribosomal sites, stops intiation, causes mRNA misreading
Uses: reserved for the most serious of TB
SE: ototoxicity, nephrotoxicity
multi drug regimens for treating active TB
always use at least 2 drugs
importance of bactericidal and intracellular drugs for conventional TB: need a cidal plus intracellular drugs
Bacteriostatic are both intra and extra (ethambutol, and p-aminosalicylic acid
Bacteriocidals: (intra and extra- isoniazid, rifampin and pyrazinamide) Extra only: streptomycin
Atypical mycobacterial infections
atypical= MOTT (mycobacteria other than tubercle bacilli)
treatment regiments: MOTTS are generally not sensitive to many anti - TB regimens
rifabutin and clarithromycin
rifabutin
single- agent prophylaxis of M. avium intracellulare MAC in AIDS patients
multi-drug treatment of MAC alternative to rifampin
Toxicities- similar to rifampin (hepatotoxic) less severe, nausea and rash, drug interactions similar to rifampin but less potent CYP inducer
Clarithromycin/azithromycin
part of multi drug regimen of M-avium-intracellulare in AIDS pts
also used for MAC prophylaxis Bactericidal
leprosy hansens disease
disease: endemic areas ( 2 types lepromatous and tuberculoid) invitro growth and susceptibility testing hard
dapsone, clofazimine, and rifampin
dapsone
MOA: same as sulfonamides, structural analog of paraaminobenzoic acid (PABA) inhibits synthesis of folic acid, bacteriostatic
uses: combination therapy with other drugs (rifampin) prophylaxis and treatment of pneumocystis jiroveci
absorption: slow and fast acetylators
SE: hemolytic anemia and methemoglobinemia
