Antitubercular Drugs
First/Second-line Agents, MDR-TB, Newer Drugs & Indian (NTEP) Guidelines
Past RGUHS + DNB + MPMSU + MUHS + VNSGU · 55
RGUHSSep '25
RGUHSMay '25
MPMSUMay '25
MPMSUJan '25
MPMSUOct '25
MPMSUMay '25
DNBJun '25
MUHSWinter '25
VNSGUSep '25
DNBOct '24
MUHSWinter '24
MPMSUJun '23
MUHSWinter '23
RGUHSNov '22
MPMSU2022
DNBDec '22
DNBJun '22
MUHSWinter '22
RGUHSNov '21
RGUHSJul '21
DNBJun '21
MUHSWinter '21
VNSGUJun '21
RGUHSJun '20
MPMSU2020
MUHSSummer '20
MUHSWinter '20
RGUHSNov '19
RGUHSMay '19
MUHSSummer '18
RGUHSNov '17
MPMSUJun '17
MPMSU2016
DNBDec '16
MUHSSummer '16
VNSGUApr '16
MPMSU2014
MPMSU2014
MPMSU2014
DNBDec '14
MUHSSummer '14
MUHSSummer '14
MUHSWinter '14
DNBDec '11
RGUHSOct '10
RGUHSOct '10
RGUHSMay '10
RGUHSOct '09
RGUHSMay '09
MPMSU2009
RGUHSApr '08
RGUHSSep '07
RGUHSApr '07
MPMSU2007
MPMSU2006
Antitubercular Drugs
1. Introduction & the mycobacterial therapeutic problem
- Tuberculosis (TB) is a chronic granulomatous disease caused by Mycobacterium tuberculosis; it surpassed HIV as the leading infectious-disease killer in 2014, and is thought to have killed ~1 in 7 of all humans who have ever lived (G&G 14e Ch.65, p.1267).
- About 1/3 of the world's population is latently infected with M. tuberculosis, of whom 10–15% develop active disease over a lifetime; India is the highest-burden country (~2.2 million of the 9.6 million global new cases in 2014, ~600 deaths/day), and TB kills more Indian adults than any other infectious disease (KDT 8e Ch.56, p.815).
- The M. tuberculosis complex comprises species with 99.9% nucleotide similarity: M. tuberculosis (typus humanus), M. canettii, M. africanum, M. bovis, and M. microti — all cause TB (G&G 14e Ch.65, p.1279).
- Mycobacteria are intrinsically hard to treat because of three natural barriers (G&G 14e Ch.65, p.1267):
- Waxy lipid cell wall — >60% lipid, mainly mycolic acids (2-branched, 3-hydroxy fatty acids, 76–90 carbon chains); blocks drug penetration to the cell membrane/cytosol.
- Efflux pumps — abundant membrane transport proteins (e.g. ATP-binding-cassette [ABC] transporters are a full 2.5% of the M. tuberculosis genome) pump out drugs, conferring native resistance.
- Intracellular + extracellular location — bacilli hide inside host cells AND within necrotic, avascular lesions, so drugs must penetrate both compartments.
- Slow growth and dormancy add to the problem: antibiotics most active against rapidly growing cells are relatively ineffective, and dormant bacilli are killed only very slowly (Katzung 16e Ch.47, p.886).
- Combinations of ≥2 drugs are mandatory — to overcome these barriers AND prevent emergence of resistance during the months-to-years of therapy (Katzung 16e Ch.47, p.886).
- The first randomized controlled trial with concealed allocation in human history was for TB — streptomycin versus bed rest (G&G 14e Ch.65, p.1267).
Historical milestones (G&G 14e Ch.65, p.1267; KDT 8e Ch.56, p.815)
- Para-aminosalicylic acid (PAS) — Lehman, 1943 (2nd effective drug); streptomycin — Waksman & Schatz, 1944 (introduced 1947); thioacetazone — Domagk, 1946; isoniazid — 1952; pyrazinamide — Kushner et al., 1952; rifamycins — Sensi & Margalith, 1957 (rifampin clinically 1962); ethambutol — Lederle, 1961.
- A long pause followed, then a "second wave": bedaquiline (FDA 2012) and delamanid (Europe 2013). The "third wave" is now here, plus repurposed agents (moxifloxacin, levofloxacin, oxazolidinones, β-lactams).
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Antitubercular Drugs
PharmaNotes Pro · Comprehensive
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