2. Introduction to Tuberculosis
Tuberculosis (TB) remains the leading cause of death
worldwide from a single infectious disease agent. Indeed
many of the world's population is infected with TB. About
1.5 million people died from TB in 2018. The registered
number of new cases of TB worldwide roughly correlates
with economic conditions: the highest incidences are seen
in those countries of Africa, Asia, and Latin America with
the lowest gross national products. WHO estimates that
eight million people get TB every year, of whom 95% live
in developing countries. An estimated 2 million people die
from TB every year.
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3. TB is an ancient infectious disease caused by
Mycobacterium tuberculosis.
It has been known since 1000 B.C., so it not a new
disease. Since TB is a disease of respiratory
transmission, optimal conditions for transmission
include:
Overcrowding
poor personal hygiene
poor public hygiene
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4. • Mycobacterium referred as acid fast organism, to family
Mycobacteriaceae, include organism of TB and Leprosy.
• Test for detection are 14C, antigenic assay, ELISA, DNA
probes.
• Mycosides are glycolipids and peptidoglycolipids.
They have common terminal saccharide group with
Rhamnoses (O-methylated deoxy sugar) at different
positions.
• They are of two groups
i. phenolic glycolipids ii. Peptidoglucolipids
Mycobectins are also of three types:
i. Mycobactin P ii. Mycobactin S and iii. Mycobactin M
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5.
6. Sulfanilamide had weak bacteriostatic properties, later
sulfone derivative dapsone was investigated clinically,
which is still considered one of the most effective drugs
for the treatment of leprosy and also has useful
antimalarial properties, was considered too toxic
because of the high dosages used.
The discovery of the antitubercular activity of the
aminoglycoside antibiotic streptomycin was a modern
era, followed by discoveries of the antitubercular
properties of p-aminosalicylic acid (PAS) first and then,
in 1952, of isoniazid.
Later, the usefulness of the synthetic drug ethambutol
and, eventually, of the semisynthetic antibiotic rifampin
was discovered
7. Combination therapy, with the use of two or more
antitubercular drugs, has been well documented.
The choice of antitubercular combination depends on
various factors, including the location of the disease
(pulmonary, urogenital, gastrointestinal, or neural).
For some time, a combination of isoniazid and
ethambutol, with or without streptomycin, was the
preferred choice of treatment.
The synthetic drug pyrazinamide, because of its
sterilizing ability, is also considered a first-line agent
and is frequently used in place of ethambutol in
combination therapy.
8. Second-line agents for tuberculosis include the
antibiotics cycloserine, kanamycin, and capreomycin
and the synthetic compounds ethionamide and PAS.
Clinical studies indicated that when rifampin is
included in the regimen, particularly in combination
with isoniazid and ethambutol (or pyrazinamide), the
period required for successful therapy is shortened
significantly.
Previous treatment schedules without rifampin
required maintenance therapy for at least 2 years,
whereas those based on the isoniazid– rifampin
combination achieved equal or better results in 6 to 9
months.
9. Classification:
• Synthetic anti tubercular agents:
Isoniazid (INH), Ethionamide, Ethambutol, Pyrazinamide,
Para amino salicylic acid.
Anti tubercular antibiotics:
Rifampicin, Rifabutin, Cycloserine, Streptomycine,
Capreomycin sulphate.
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10. Isonicotinic acid hydrazide, isonicotinyl hydrazide, or INH
(Nydrazid), It is prepared by reacting the methyl ester of
isonicotinic acid with hydrazine.
It is not, however, uniformly effective against all forms of the
disease.
Its action, which is considered bactericidal, is to cause the bacilli
to lose lipid content by a mechanism.
The most generally accepted theory suggests that the principal
effect of isoniazid is to inhibit the synthesis of mycolic acids,
high–molecular-weight, branched –hydroxy fatty acids that
constitute important components of the cell walls of
mycobacteria.
A mycobacterial catalase–peroxidase enzyme complex is required
for the bioactivation of isoniazid, A reactive species, generated
through the action of these enzymes on the drug, is believed to
attack a critical enzyme required for mycolic acid synthesis in
mycobacteria.
11. • The target for the action of INH has recently been
identified as an enzyme that catalyzes the NADH-
specific reduction of 2-trans-enoylacyl carrier
protein, an essential step in fatty acid elongation.
• This enzyme is encoded by a specific gene, inhA, in
M. tuberculosis.
• Coadministration of pyridoxine is reported to
prevent the
• symptoms of peripheral neuritis, suggesting that this
adverse effect may result from antagonism of a
coenzyme action of pyridoxal phosphate.
13. • Ethionamide-2-Ethylthioisonicotinamide,
• This nicotinamide has weak bacteriostatic activity in vitro
but, because of its lipid solubility, is effective in vivo.
• 2-substitution enhances activity in the thioisonicotinamide
series.
• Ethionamide is considered a secondary drug for the
treatment of tuberculosis. Low Potency and Highest
tolerated Dose.
• Pyrazinamide:
• Its antitubercular properties were discovered as a result of
an investigation of heterocyclic analogs of nicotinic acid,
with which it is isosteric.
• Bioactivation of pyrazinamide to pyrazinoic acid by an
amidase present in mycobacteria 13
14. • Ethambutol: EMB
• EMB is active only against dividing mycobacteria. Its
selective toxicity related to the inhibition of the
incorporation of mycolic acids into the cell walls of these
organisms.
• Compound is remarkably stereospecific. The dextro
isomer is 16 times as active as the meso isomer.
• The length of the alkylene chain, the nature of the
branching of the alkyl substituents on the nitrogens, and
the extent of N-alkylation all have a pronounced effect
on the activity.
• Aminosalicylic Acid – PAS
• The mechanism of antibacterial action of PAS is similar
to that of the sulfonamides. 14
15. • Thus, it is believed to prevent the incorporation of p-
aminobenzoic acid (PABA) into the dihydrofolic acid
molecule catalyzed by the enzyme dihydrofolate
synthetase.
• Structure–activity studies have shown that the amino
and carboxyl groups must be para to each other and
free; thus, esters and amides must readily undergo
hydrolysis in vivo to be effective. The hydroxyl group
may be ortho or meta to the carboxyl group, but optimal
activity is seen in the former.
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16. Isoniazid
Rifampin
CLASSIFICATION OF DRUGS
3 Groups depending upon the degree of effectiveness and
potential side effects
First Line: (Primary agents)
are the most effective and have lowest toxicity.
17. Second Line:
Less effective and more toxic effects
p-amino salicylic acid (PAS)
Streptomycin
Ethambutol
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18. Third Line
are least effective and most toxic.
Amikacin
Kanamycin
Capreomycin
Viomycin
Kanamycin
Cycloserine
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20. Rifamycin
• All of the rifamycins (A, B, C, D, and E) are biologically
active.
• Some of the semisynthetic derivatives of rifamycin B are the
most potent known inhibitors of DNAdirected RNA
polymerase in bacteria.
• Their net effect is to inhibit the formation of the virus particle,
apparently by preventing a specific polypeptide conversion.
• Rifamycins bind to the subunit of bacterial DNA-dependent
RNA polymerases to prevent chain initiation.
• Rifampin: Most active, highly active against staphylococci
and used with the combination only.
• Hepatotoxicity was significantly higher when rifampin was
combined with isoniazid. 20
21. • Combination with ethambutol, are less toxic.
• Rifampin is a powerful inducer of hepatic cytochrome
P450 oxygenases.
• When it is used in the treatment of leprosy, rifampin should
be combined with dapsone or some other leprostatic agent
to minimize the emergence of resistant strains of M. leprae.
• Rifampin has its primary metabolite, deacetylrifampin,
which is also biologically active and get reabsorbed. The
concentration of drug remain long time in body.
• It can also give reddish orange discoloration of the urine,
stool, saliva, tears.
• Dose is 600mg and available in parentral form also.
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22. • Rifabutin: Rifabutin, the spiroimidazopiperidyl derivative of
rifamycin B.
• Rifabutin is a very lipophilic compound with a high affinity
for tissues.
• Cycloserine: 4-Amino-3-isoxazolidinone (Seromycin), both
isomers D and L are active.
• Cycloserine is presumed to exert its antibacterial action by
preventing the synthesis of cross-linking peptide in the
formation of bacterial cell walls.
• it is an antimetabolite for alanine and alanine racemase.
• Irreversible inactivation of the enzyme thereby deprives the
cell of the D-alanine required for the synthesis of the cross-
linking peptide.
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23. • Capreomycin Sulfate: Four capreomycins, designated IA,
IB, IIA, and IIB, have been isolated, clinical agent
contains primarily IA and IB.
• It is useful in resistant or treatment failure TB when
given with ethambutol or INH.
• Common side effect is hearing loss, rashes and fever.
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