Treatment of Tuberculosis PDF

Summary

This document provides an overview of tuberculosis treatment, focusing on various antituberculosis drugs such as Isoniazid, Rifampicin, Ethambutol, and Pyrazinamide. It details their mechanisms of action, resistance, pharmacokinetic properties, adverse effects, and drug interactions. Tables and lists of information in the document also help to understand the treatment and provide effective information for readers.

Full Transcript

# Treatment of Tuberculosis

## Antituberculosis Drugs

### First Line Drugs (FLDs)
#### First Line Oral (FLO) Drugs
1. Isoniazid (INH/H)
2. Rifampicin (R)
3. Pyrazinamide (Z)
4. Ethambutol (E)

## Isoniazid
- Isonicotinic acid hydrazide (INH)
- Structurally related to pyridoxine (vitamin B6)
- Prodrug activated in M. tuberculosis by KatG, a catalase-peroxidase.
- Inhibits cell wall by inhibiting mycolic acid synthesis
- Bactericidal to actively growing bacilli
- Acts on both intracellular and extracellular bacilli

### Mechanism of Resistance
- Mutation in catalase peroxidase gene
- Mutation in the promoter gene inhA

### PK
- Penetrates most body fluids and accumulates in caseated lesions
- Acetylated in the liver by N-acetyltransferase; acetyl isoniazid is eliminated faster than isoniazid

### Uses:
- Combined with RIF, PZA, EMB for treatment
- Used alone for prophylaxis

### Adverse Effects
- Allergic Reaction
- Metabolites of INH may be hepatotoxic (↑ with Age, daily alcohol consumption, drug abuse)
- INH can inhibit mammalian pyridoxal kinase and enhance pyridoxine excretion
- Peripheral neuropathy with high dose
- Minimized by the coadministration of pyridoxine.
- Inhibits the metabolism of other drugs, especially diphenylhydantoin.

### Drug Interactions
- AlOH inhibits absorption of INH
- Alcohol increases risk of hepatitis
- Inhibits the metabolism of phenytoin and carbamazepine

## Rifampicin, rifapentine, rifabutin

- Rifamycin derivative, Inhibits DNA-dependent RNA polymerase
- Bactericidal against intra- and extracellular bacilli
- Also active against M. leprae, Staph. Aureus, N. meningitis, H. influenza, Brucella, and Legionella
- Rifapentine and rifabutin are analogs of rifampin

### Resistance
- Develops rapidly if used alone
- Results from point mutation in rpoB gene

### PK
- Well absorbed orally; significantly protein bound
- Excreted mainly thru liver and bile (Enterohepatic circulation)
- Induces hepatic microsomes
- decrease half-lives of drugs such as anticonvulsants, antiretrovirals etc.

### Adverse effects
- Mainly hepatitis (Dose-dependent and reversible)
- Nausea and vomiting, dizziness, fatigue, fever, jaundice, and an orange color to urine and other excretions.

### Drug interactions:
- Enzyme inducer
- Accelerates metabolism of many drugs e.g. oral contraceptives, anticoagulants, protease inhibitors

## Ethambutol (Myambutol)

- Inhibits arabinosyl transferases involved in cell wall biosynthesis
- Tuberculostatic
- Resistance due to mutation in emb B gene

### Adverse effects:
- Reversible retrobulbar neuritis (impaired visual acuity, red-green colour discrimination)
- Mild GI disturbances; Decreases urate secretion and may precipitate gout

## Pyrazinamide

- Derivative of nicotinamide
- Prodrug that is converted to pyrazinoic acid by bacterial pyrazinamidase enzyme.
- Bactericidal
- Inactive at neutral pH, but it inhibits tubercle bacilli in the acidic (pH 5) phagosomes of macrophages.
- Mutation in pcnA gene (encodes pyrazinamidase enzyme)
- Adrs: hepatotoxicity, vomiting, anorexia. Not used in pregnancy

### Adverse Effects
- Hepatotoxicity is the major adverse effect
- Inhibits urate excretion and can precipitate acute episodes of gout.
- Acts on extracellular tubercle bacilli.

## Second Line Drugs (SLDS)

### Second Line Oral (SLO) Drugs
1. Fluoroquinolones
- Levofloxacin (Lfx)
- Moxifloxacin (Mfx)
- Gatifloxacin (Gfx)
2. Ethionamide (Eto)
3. Prothionamide (Pto)
4. Cycloserine (Cs)
5. Terizidone (Trz)
6. Para-aminosalicylic Acid (PAS)
7. Thiacetazone (Taz)
8. Rifabutin/Rifapentine

## Antituberculosis Agents

| MIC (meg/ml) | Mechanism of Action | Geme(s) Imvolved in Resistance | Role in Resistance |
|---|---|---|---|
| 0.01-0.25 | Inhibition of mycolic acid synthesis and other multiple effects on DNA, lipids, carbohydrates, and NAD metabolism | katG, inha, ahpC | Prodrug conversion, Drug target, Marker of resistance |
| 0.5-2 | Inhibition of RNA synthesis | rpoB | Drug target |
| 16-100* | Inhibition of membrane energy and transport| pcnA | Prodrug conversion |
| 1-5 | Inhibition of arabinogalactan synthesis | embCAB | Drug target |
| 2-8 | Inhibition of protein synthesis| rpsL, rrs (16S rRNA)| Drug target, Drug target |
| 2-4 | Inhibition of protein synthesis | rrs (16S rRNA) | Drug target |
| 0.5-2.5 | Inhibition of DNA synthesis | gyrA or gyrB | Drug target |
| 10 | Inhibition of mycolic acid synthesis | etal or ethA, inha | Prodrug conversion, Drug target |
| 1-8 | Inhibition of folate pathway and mycobactin synthesis (7) | thyA (thymidylate synthase)? | Drug target |

## Tuberculosis Treatment

| | Tuberculosis | Treatment |
|------|--------------------------------------|-----------------------------------|
| 1 | Latent TB Infection (Chemoprophylaxis) | Daily INH for 9 months |
| 2 | Category 1 (New or previously untreated cases) | 2HRZE + 4HR |
| 3 | Category 2 (Previously treated cases; relapses and treatment defaults) | 2HRZES + I HRZE + 5HRE |
| 4 | Treatment failure and special cases: | |
| | a. Resistance (or intolerance) to H | 6 RZE + Q (for extensive disease) |
| | b. Resistance (or intolerance) to R | 12 HZEQ + S (for ext. disease) |
| | c. Intolerance to Z | 2 HRE + 7 HR |