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Overview of Aminoglycosides and other protein synthesis inhibitors

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Title: Overview of Aminoglycosides and other protein synthesis inhibitors


1
Welcome
2
Overview of Aminoglycosides and other protein
synthesis inhibitors
3
Presented By
  • Maruf Kamal (2008-3-70-006)
  • Sabbir Ahmed (2008-3-70-007)
  • Md. Tanvir Rahman (2009-1-70-018)

4
Introducton
  • An aminoglycoside is a molecule or a portion of a
    molecule composed of amino-modified sugars.
  • Several aminoglycosides function as antibiotics
    that are effective against certain types of
    bacteria. They include amikacin, arbekacin,
    gentamicin, kanamycin, neomycin, netilmicin,
    paromomycin, rhodostreptomycin, streptomycin,
    tobramycin, and apramycin.

5
History
  Aminoglycoside   Year   Source organism
streptomycin 1944 Streptomyces griseus
neomycin 1949 Streptomyces fradiae
kanamycin 1957 Streptomyces kanamyceticus
paromomycin 1959 Streptomyces rimosus
spectinomycin 1962 Streptomyces spectabilis
gentamicin 1963 Micromonospora purpurea
tobramycin 1968 Streptomyces tenebrarius
sisomicin 1972 Micromonospora inyoensis
amikacin 1972 semisynthetic derivative of kanamycin
netilmicin 1975 semisynthetic derivative of sisomicin
6
History
  • The first aminoglycoside, streptomycin, was
    isolated from Streptomyces griseus in 1943.
    Neomycin, isolated from Streptomyces fradiae, had
    better activity than streptomycin against aerobic
    gram-negative bacilli but, because of its
    formidable toxicity, could not safely be used
    systemically. Gentamicin, isolated from
    Micromonospora in 1963, was a breakthrough in the
    treatment of gram-negative bacillary infections,
    including those caused by Pseudomonas aeruginosa.
    Other aminoglycosides were subsequently
    developed, including amikacin (Amikin),
    netilmicin (Netromycin) and tobramycin (Nebcin),
    which are all currently available for systemic
    use

7
Nomenclature
  • Aminoglycosides that are derived from bacteria of
    the Streptomyces genus are named with the suffix
    -mycin, whereas those that are derived from
    Micromonospora are named with the suffix -micin.
  • This nomenclature system is not specific for
    aminoglycosides. For example, vancomycin is a
    glycopeptide antibiotic and erythromycin, which
    is produced from the species Saccharopolyspora
    erythraea (previously misclassified as
    Streptomyces) along with its synthetic
    derivatives clarithromycin and azithromycin, is a
    macrolide. All differ in their mechanisms of
    action, however.

8
Physical and chemical properties
  • They are water-soluble due to their polar groups
    (hydroxyl and amine groups), stable in solution
    and more active at alkaline than at acid PH.
  • Aminoglycosides frequently exhibit synergism
    with ß-lactams or vancomycin.
  • However, aminoglycosides may complex with
    ß-lactam drugs, resulting in loss of activity and
    they should not be mixed together for
    administration.

9
Specific Agents
  • Amikacin (Amikin),
  • Gentamicin (Garamycin),
  • Kanamycin (Kantrex),
  • Neomycin, Netilmicin (Netromycin),
  • Streptomycin, Tobramycin (Nebcin)

10
Structure of Aminoglycosides
11
Mechanism of action
  • bactericidal aminoglycosides bind to the 30S
    subunit of the bacterial ribosome, interfering
    with the binding of fMet-tRNA and therefore the
    formation of the initiation complex. Binding to
    the 30S subunit may also cause misreading of mRNA
    codons
  • ß-lactams, vancomycin facilitate uptake by
    Gram-positive organisms
  • resistance via plasmid-mediated
    aminoglycoside-modifying enzymes

12
Mechanism of action
13
Pharmacokinetics
  • poor oral absorption
  • volume of distribution approximates the
    extracellular space (about 0.26 L/kg)
  • (larger in cystic fibrosis patients, about 0.35
    L/kg)
  • tissue distribution variable (poor CNS
    penetration)
  • negligible metabolism
  • renally eliminated (filtered, with a small amount
    of proximal reabsorption)
  • elimination half-life 2-3 hours (if renal
    function normal)

14
Pharmacodynamics
  • concentration-dependent killing
  • postantibiotic effect (concentration-dependent)

15
SARs of Aminoglycosides
  • Crucial for broad spectrum activity
  • Primary target for inactivating enzymes
  • Congeners with amino groups at 2' and 6' are
    especially active

16
SARs of Aminoglycosides
  • Methylation of these amines does not alter
    activity,decreases inactivation
  • Hydroxyls at the 3' or 4 position are not
    critically important

17
SARs of Aminoglycosides
  • Modifications compromise antibacterial activity
  • One exception is amikacin with its
    aminohydroxybutyrate

18
SARs of Aminoglycosides
  • Substitution pattern is somewhat more flexible
  • Only real requirement is the amine at the 3"
    position.

19
Spectrum of activity
  • Aminoglycosides are classified as broad-spectrum
    antibiotics, they used for treatment of serious
    systemic infections caused by
  • Aerobic Gm ve bacilli.
  • Aerobic Gm ve and Gm ve cocci (with the
    exception of Staphylococci) tend to be less
    sensitive to aminoglycosides and thus the
    ß-lactam and other antibiotics tend to be
    preferred for the treatment of infections caused
    by these organisms.

20
Spectrum of activity
  • broad gram-negative spectrum including P.
    aeruginosa
  • gram-positive synergistic in combination with
    ß-lactams, glycopeptides
  • anaerobes negligible activity
  • amikacin Nocardia, MAI, certain rapid-growing
    mycobacteria, gentamicin-resistant gram-negative
    bacilli
  • streptomycin multidrug-resistant tuberculosis,
    tularemia, plague

21
Adverse reactions
  • nephrotoxicity
  • proximal acute tubular necrosis (ATN) ? ? GFR
  • likely related to inhibition of intracellular
    phospholipases in the proximal tubule
  • tends to be reversible
  • associated factors hypotension, dehydration,
    duration of therapy, concomitant liver disease,
    advanced age, other nephrotoxins (vancomycin)
  • nephrotoxicity correlates with drug accumulation
    in the renal cortex

22
Aminoglycoside accumulation in critically ill
surgical patients
23
Toxicity
  • 1- Nephrotoxicity
  • 2- Ototoxicity
  • 3- Neurotoxicity
  • 4- Neuromuscular blockade
  • Additional adverse reactions with
    administration of aminoglycosides may include
    nausea, vomiting, anorexia, rash, and urticaria.

24
Toxicity
  • ototoxicity
  • vestibulotoxic and cochleotoxic
  • generally irreversible
  • difficult to assess
  • high tone frequencies affected first
  • neuromuscular blockade
  • rare but potentially serious
  • enhanced by conditions or drugs affecting the NM
    junction (e.g., myasthenia gravis,
    succinylcholine)
  • can be treated with calcium

25
Contraindications
  • Aminoglycosides should not be given to patients
    requiring long term therapy because of the
    potential for ototoxicity and nephrotoxicity.
  • These drugs are contraindicated in patients
    with
  • - Preexisting hearing loss -
    Myasthenia gravis
  • - Parkinsonism
  • - During lactation or pregnancy.
  • The aminoglycosides are used cautiously in
    patients with renal failure, in the elderly and
    in patients with neuromuscular disorders.

26
Drug interactions
  • Administration of aminoglycosides with the
    cephalosporins may increase the risk of
    nephrotoxicity.
  • When the aminoglycosides are administered with
    loop diuretics there is an increase the risk of
    ototoxicity (irreversible hearing loss).
  • There is an increased risk of neuromuscular
    blockage (paralysis of the respiratory muscles)
    if the aminoglycosides are given shortly after
    general anesthetic (neuromuscular junction
    blockers).

27
Drug interactions
  • Increased risk of nephrotoxicity and ototoxicity
    when aminoglycosides given with vancomycin.
  • Increased risk of nephrotoxicity when
    aminoglycosides given with colistin.
  • Aminoglycosides antagonize effects of
    neostigmine.

28
  • Streptomycin sulfate
  • Neomycin sulfate

29
  • Kanamycin sulfate

Amikacin
30
  • Gentamicin sulfate

Netilmicin sulfate
31
Other Protein Synthesis Inhibitors
  • Tetracycline
  • Chloramphenicol
  • Macrolides
  • Mupirocin
  • Quinolones

32
  • Mechanisms action of tetracycline

33
Commercially available tetracyclines
  • First generation (Dose intervals shorter)
  • Chlorotetracycline
  • Oxytetracycline
  • Tetracycline
  • Dmeclocycline
  • Second Generation (Dose interval longer)
  • Minocycline
  • Methacycline
  • Doxycycline
  • Third Generation
  • Glycylcycline

34
  • Mechanism action of chloramphenicol

35
Structure of cloramphenicol
36
  • MUPIROCIN
  • Mupirocin is active against many gram-positive
    and selected gram-negative bacteria. It has good
    activity against S. pyogenes and
    methicillin-susceptible and methicillin-resistant
    strains of S. aureus. It is bactericidal at
    concentrations achieved with topical application.
  • Mupirocin inhibits bacterial protein synthesis by
    reversible inhibition of Ile tRNA synthase. There
    is no cross-resistance with other antibiotic
    classes. Clinically insignificant, low-level
    resistance results from mutations of the gene
    encoding Ile tRNA synthase or an extra
    chromosomal copy of a gene encoding a modified
    Ile tRNA synthase. High-level resistance is
    mediated by a plasmid or chromosomal copy of a
    gene encoding a bypass synthetase that binds
    Mupirocin poorly.

37
  • Mechanism action of chloramphenicol

38
Structure of chloramphenicol
39
  • Mode of action of Macrolides

40
Examples of Macrolides
  • Erythromycin
  • Clarithromycin
  • Roxithromycin
  • Azithromycin

41
  • Mupirocin is available as a 2 cream or ointment
    for dermatologic use and as a 2 ointment for
    intranasal use. The dermatological preparations
    are indicated for treatment of traumatic skin
    lesions and impetigo secondarily infected with S.
    aureus or S. pyogenes. Systemic absorption
    through intact skin or skin lesions is minimal.
    Any Mupirocin absorbed is rapidly metabolized to
    inactive monic acid.
  • Mupirocin is effective in eradicating S. aureus
    carriage. The consensus is that patients who may
    benefit from Mupirocin prophylaxis are those with
    proven S. aureus nasal colonization plus risk
    factors for distant infection or a history of
    skin or soft tissue infections.
  • Mupirocin may cause irritation and sensitization
    and contact with the eyes should be avoided.
  • Systemic reactions to Mupirocin occur rarely, if
    at all. Application of the ointment to large
    surface areas should be avoided in patients with
    renal failure to avoid accumulation of
    polyethylene glycol from the ointment.

42
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44
Examples of Quinolones
  • Nalidixic acid
  • Ciprofloxacin
  • Levofloxacin
  • Glatifloxacin
  • Norfloxacin
  • Sparfloxacin
  • Fluroquinolone

45
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