Aminoglycosides are a class of antibiotics that consist of amino sugars attached to a hexose ring. They are bactericidal and used to treat infections caused by aerobic gram-negative bacteria. Aminoglycosides work by binding to the 30S ribosomal subunit and inhibiting bacterial protein synthesis. They are not absorbed orally and are administered via injection or topically. Common adverse effects include ototoxicity, nephrotoxicity, and neuromuscular blockade. Aminoglycosides require monitoring due to their toxicity profile.
2. Learning objectives
• What are aminoglycosides and their distinctive features?
• Classification
• Pharmacokinetics
• Mechanism of action
• Resistance
• Spectrum
• Indications
• Adverse effects
• Drug-drug interaction
• contraindications 2
3. Introduction
• Consist of two or more amino sugars attached by glycoside
linkage to hexose ring.
• Streptomycin was the first to be discovered in 1944
• Actinomycetes –Streptomyces griseus
• Source: various species of Streptomyces
• Interfere with protein synthesis
• Bactericidal
• Used to treat serious infections caused by aerobic Gram –ve
bacteria
• Sulfate salt
• All exhibit ototoxicity and nephrotoxicity
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6. Pharmacokinetics
• ABSORPTION: Polycationic(very high charge),highly polar, not
absorbed or destroyed by GIT, Usually given subcutaneously, IM,
IV and sometimes Intrathecally. Topical application are also
available.
Bactericidal effect is conc. dependent.
• Distribution: Mainly distributed into extracellular fluid. Poorly
penetrate into CSF.Some of them cross the placental barrier.
• METABOLISM: They are not metabolized in the body.
• Half life: 2-3hrs
• EXCRETION: Excreted as such in urine by glomerular filtration.
Accumulation occur with renal failure. 6
7. Mechanism of Action
• Initially they penetrate bacterial cell wall to reach
periplasmic space through porin channel
• Further transport across cytoplasmic membrane takes
place by oxygen dependent active transport
mechanism
• Bind with 30s ribosomal subunit.
• Protein synthesis is inhibited by 3 ways.
Interference with initiation complex of peptide
formation
Misreading of mRNA
Breakup of polysomes into nonfunctional
monosomes/inhibiting translocation
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10. Resistance
There are four mechanisms
of aminoglycoside resistance:
1. Reduced uptake or
decreased cell permeability
2. Alterations at the ribosomal
binding sites
3. Production
of aminoglycoside modifying
enzymes
4. Natural resistance of
anaerobic bacteria
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12. Gram +ve anaerobes
• Resistant to anaerobes except clostridia
Mycobacterium tuberculosis
• Streptomycin is 1st line treatment
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13. Indications
Gentamicin: Used to treat
pneumonia and septicemia
caused by Pseudomonas
aeruginosa. Given along with
carbenicillin to have synergistic
action.
• Given along with
benzylpenicillin to treat
bacterial endocarditis.
• Given along with
metronidazole or clindamycin
to treat anaerobic infection.13
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14. • Cephalosporin/ureidopenicillin/t
icarcillin is combined with
gentamycin to treat infection
caused by Gram –ve bacteria.
• Applied locally to treat wounds,
infections and burns.
• Tobramycin: similar to
gentamycin but more effective
against pseudomonas infections.
• Used to treat infections caused
by bacteria resistant to
gentamycin.
Neomycin: used to treat
infection of skin and mucous
membranes.
• Ophthalmic use14
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15. Kanamycin: used to treat
infections caused by Gram –ve
bacilli.
• Little activity against
pseudomonas.
Amikacin: derivative of
kanamycin
• It has advantage over other
aminoglycosides that it is
resistant to many inactivating
enzymes produced by
bacteria.
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16. Streptomycin:
It is used to treat
• UTIs
• Pyelonephritis
• Brucellosis
• Febrile neutropenia
• 1st line drug in the
treatment of T.B
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17. Adverse Effects
Ototoxicity: It is of 2
types
1. Vestibular damage
2. Cochlear damage
It is due to VIII cranial
nerve damage.
Drug accumulate in
endolymph and perilymph of
inner ear which can lead to
progressive damage to
vestibular & cochlear hear
cells.
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18. • Kanamycin, Amikacin, Netilmicin and Neomycin may
effect the auditory functions, which leads to tinnitus,
high frequency hearing loss and deafness.
• Gentamycin and Streptomycin mainly effect the
vestibular function. There is nausea, vomiting and
difficulty in standing, vertigo, nystagmus(involuntary
movements of eyeball).
• Tobramycin effect both.
Risk factors:
elderly
Co-current use of other ototoxic drugs i.e. vancomycin,
loop diuretics
Pre-existing auditory impairment
Increase conc.of drug in plasma
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19. Nephrotoxicity: Aminoglycosides
get concentrated in renal cortex.
Retention of aminoglycosides by
proximal tubular cells disrupt
calcium mediated transport process
and result in kidney damage ranging
from mild, reversible renal
impairment to severe acute tubular
necrosis which can be irreversible.
• Gentamicin, Neomycin, Amikacin
are nephrotoxic.
• Neomycin is more nephrotoxic.
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20. Neurotoxicity: These drugs
cause neuromuscular blockade
which leads to skeletal muscle
weakness and respiratory
depression.
• Neuromuscular blockade is
due to Gentamycin and
Amikacin.
• They inhibit pre-synaptic
release of Ach.
• They inhibit post-synaptic
nicotinic receptors.
• Displace Calcium from NM
junction
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22. Drug-Drug interaction
• Neuromuscular blockage may increase when amino
glycosides are given to patients who have received
anesthetics (halogenated hydrocarbon).
• Frusemide potentiate the ototoxic and nephrotoxic
effects of aminoglycosides.
• Neomycin destroys the vitamin K producing bacteria in
the gut. It thus potentiate the effects of oral
anticoagulants.
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23. Contraindications
• Pregnancy: as they cross placenta and can cause fetal
abnormalities.
• Co-current administration of nephrotoxic drugs should be
avoided.
• Neuromuscular blocking agents should not be given along
with aminoglycosides because this will lead to respiratory
depression.
• With other ototoxic drugs
• Elderly patient
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