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Aminoglycosides are bactericidal [https://www.wikilectures.eu/w/Antibiotics?veaction=edit antibiotics], mainly used in hospitals.
[[File:Structure of gentamicin.png|thumb|Structure of gentamicin]]
[[File:Streptomycin-structure.png|thumb|Structure of streptomycin]]
Aminoglycosides are '''bactericidal [[antibiotics]]'''[[Antibiotics|,]] mainly used in hospitals.


== Mechanism of action ==
== Mechanism of action ==
Line 5: Line 7:


== Antimicrobial spectrum ==
== Antimicrobial spectrum ==
Aminoglycosides are mainly effective against infections caused by Gram-negatives (Escherichia, Klebsiella, Enterobacter, Serratia, Citrobacter, Pseudomonas, Acinetobacter, Salmonella, Shigella) and Gram-positives (Staphylococcus aureus, including β-lactamase-producing strains, Staphylococcus epidermidis). Less sensitive to resistant are streptococci and enterococci. Anaerobes are naturally resistant.
Aminoglycosides are '''mainly effective against infections caused by Gram-negatives''' ('''''Escherichia, Klebsiella, Enterobacter, Serratia, Citrobacter, Pseudomonas, Acinetobacter, Salmonella, Shigella''''') and Gram-positives '''(''Staphylococcus aureus''''', including [[Beta-lactamases|β-lactamase]]-producing strains, '''''Staphylococcus epidermidi''s'''). Less sensitive to resistant are ''streptococci'' and ''enterococci''. Anaerobes are naturally resistant.


== Pharmacokinetics ==
== Pharmacokinetics ==
Aminoglycosides are not absorbed per os and act locally in the GIT. They are therefore administered parenterally (mostly i.v.). They are also well absorbed after i.m. administration. They penetrate poorly into body fluids and tissues. They are not metabolised and are excreted by glomerular filtration. Elimination is markedly reduced in renal impairment (in patients with renal insufficiency and failure; in children in the first week of life, especially premature infants due to renal immaturity; in old age when glomerular filtration decreases due to reduced renal blood flow). In these cases, aminoglycosides may accumulate and cause toxic damage. In the renal tubules, they enter cells by active transport and penetrate into lysosomes, where they cause intracellular shedding of autolytic lysosomal enzymes and subsequent cell autolysis and necrosis.
Aminoglycosides are not absorbed per os and act locally in the GIT. They are used '''parenterally''' '''(mostly i.v.)'''. They are also well absorbed after '''i.m. administration'''. They penetrate '''poorly into body fluids and [[Connective tissues|tissues]]'''[[Connective tissues|.]] They are '''not metabolised and are excreted by glomerular filtration'''. Elimination is markedly reduced in renal impairment (in patients with renal insufficiency and failure; in children in the first week of life, especially premature infants due to renal immaturity; in old age when glomerular filtration decreases due to reduced renal [[blood]] flow). In these cases, aminoglycosides may accumulate and cause toxic damage. In the renal tubules, they enter cells by active transport and penetrate into lysosomes, where they cause intracellular shedding of autolytic lysosomal enzymes and subsequent cell autolysis and necrosis.


== Pharmacodynamics ==
== Pharmacodynamics ==
The effect of aminoglycosides is dependent on plasma concentration. They are hydrophilic, so they do not penetrate biological membranes easily. They are subject to active O2-dependent transport across the inner part of the membrane (therefore they do not act on anaerobes). They induce a rapid killing phase (6 h), followed by a bacteriostasis phase (even when antibiotic concentrations are low), when bacterial regrowth does not occur. This phase is also called the "post-antibiotic effect" (PAE). Its magnitude is determined by the size of the cmax, and the type of bacteria. It is amplified by the presence of leukocytes. Combination with β-lactams facilitates penetration by passive diffusion.
'''The effect of aminoglycosides is dependent on [[plasma]] concentration'''. They are hydrophilic, so they do not penetrate [[Biological membrane|biological membranes]] easily. They are subject to active O2-dependent transport across the inner part of the membrane (therefore they do not act on anaerobes). They induce a rapid killing phase (6 h), followed by a bacteriostasis phase (even when antibiotic concentrations are low), when bacterial regrowth does not occur. This phase is also called the '''"post-antibiotic effect" (PAE)'''. Its magnitude is determined by the size of the cmax, and the type of bacteria. It is amplified by the presence of leukocytes. Combination with β-lactams facilitates penetration by passive diffusion.


== Side effects and toxicity ==
== Side effects and toxicity ==
Aminoglycosides are potentially ototoxic. Ototoxicity may be acute (after high dose) from reversible blockade of calcium current in hair cells, which can be corrected by calcium administration because of the competitive antagonism between the antibiotic and calcium. Chronic ototoxicity is attributed to the time of exposure (AUC) and is up to 50% irreversible, unpredictable, sudden and intense after 5-7 days of treatment. Adverse effects include neurotoxicity. Aminoglycosides are also nephrotoxic due to their effect on the renal tubules. The damage tends to be reversible. It is important to note that they are one of the few antibiotics whose effect and toxicity correlate closely with plasma concentrations (better than dose). Yet the difference between the concentrations underlying antibiotic and toxic effects is small (they have a narrow therapeutic window). Therapeutic drug monitoring (TDM) is performed.
Aminoglycosides are potentially '''ototoxic'''. Ototoxicity may be acute (after high dose) from reversible blockade of calcium current in hair cells, which can be corrected by calcium administration because of the competitive antagonism between the antibiotic and calcium. Chronic ototoxicity is attributed to the time of exposure (AUC) and is up to 50% irreversible, unpredictable, sudden and intense after '''5-7 days''' of treatment. Adverse effects include neurotoxicity. Aminoglycosides are also nephrotoxic due to their effect on the renal tubules. The damage tends to be reversible. It is important to note that they are one of the few antibiotics whose effect and toxicity correlate closely with plasma concentrations (better than dose). Yet the difference between the concentrations underlying antibiotic and toxic effects is small (they have a narrow therapeutic window). Therapeutic drug monitoring (TDM) is performed.


== Benefits of aminoglycosides ==
== Benefits of aminoglycosides ==
* Bactericidal
* '''Bactericidal'''
* postantibiotic effect
* '''postantibiotic effect'''
* low price
* '''low price'''


== Indications ==
== Indications ==
Treatment with aminoglycoside antibiotics is indicated for more serious infections: septic conditions, CNS infections, respiratory tract infections (pneumonia), intra-abdominal and hepatobiliary infections, endocarditis, complicated urinary tract infections with sensitive agents included in the antibiotic spectrum. In monotherapy they are used only in urinary tract infections, otherwise in combination mostly with β-lactams. In enterococcal endocarditis in combination with ampicillin.
Treatment with aminoglycoside antibiotics is indicated for more '''serious infections: septic conditions, CNS infections, respiratory tract infections ([[Bacterial Pneumonia|pneumonia]]), intra-abdominal and hepatobiliary infections, [[endocarditis]]''', '''complicated urinary tract infections''' with sensitive agents included in the antibiotic spectrum. In monotherapy they are used only in urinary tract infections, otherwise in combination mostly with β-lactams. In ''enterococcal'' endocarditis in combination with ampicillin.


== Representatives of antibiotics ==
== Representatives of antibiotics ==
[[Soubor:Streptomycin.png |náhled|vpravo| Struktura streptomycinu]]


* basic aminoglycosides of older type (with defined indication): streptomycin, neomycin, kanamycin
* basic aminoglycosides of older type (with defined indication): '''streptomycin, neomycin, kanamycin'''
* highly effective newer ones with lower toxicity: gentamicin, tobramycin, amikacin, netilmicin
* highly effective newer ones with lower toxicity: '''gentamicin, tobramycin, amikacin, netilmicin'''


'''Streptomycin'''<br />It is the drug of choice for brucellosis, tularemia, nodular fever, used as an antituberculosis. In combination with penicillin, it is used to treat endocarditis caused by viridal streptococci or enterococci.
'''Streptomycin'''<br />It is the drug of choice for '''[[brucellosis]], tularemia, nodular fever''', used as an '''antituberculosis'''. In combination with penicillin, it is used to treat endocarditis caused by viridal ''streptococci'' or ''enterococci''.


'''Gentamicin'''
'''Gentamicin'''


The basic broad-spectrum antibiotic of this group. It should not be given to pregnant women, newborns and premature infants. Adverse effects include nephrotoxicity (albuminuria, proteinuria), ototoxicity (dizziness, vertigo), curareform effects (neostigmine is an antagonist), skin manifestations, increased liver tests, changes in blood pressure and others.
The basic broad-spectrum antibiotic of this group. It should not be given to pregnant women, newborns and premature infants. Adverse effects include nephrotoxicity (albuminuria, [[Proteinuria in Children|proteinuria]]), ototoxicity ([[dizziness]], vertigo), curareform effects (neostigmine is an antagonist), skin manifestations, increased liver tests, changes in [[blood pressure]] and others.
 
'''Amikacin'''


'''Amikacin'''<br />
It is used to treat infections that are caused by gentamicin-resistant microbes.
It is used to treat infections that are caused by gentamicin-resistant microbes.


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* LINCOVÁ, Dagmar a Hassan FARGHALI, et al. ''Základní a aplikovaná farmakologie. ''2. vydání. Praha : Galén, 2007. <nowiki>ISBN 978-80-7262-373-0</nowiki>.
* LINCOVÁ, Dagmar a Hassan FARGHALI, et al. ''Základní a aplikovaná farmakologie. ''2. vydání. Praha : Galén, 2007. <nowiki>ISBN 978-80-7262-373-0</nowiki>.


*
=== '''Antibiotics and chemoterapeutics''' ===
{| class="wikitable"
! rowspan="21" |baktericidal
 
|[[aminoglycosides|'''aminoglycosides''']]
| colspan="3" |amikacin, gentamycin, isepamycin, neomycin, netilmicin, spectinomycin, streptomycin, tobramycin
|-
|'''antituberkulotics'''
| colspan="3" |izoniazid, cykloserin, ethambutol, ethionamid, kapreomycin, pyrazinamid, viomycin
|-
| rowspan="10" |
'''<br />'''
 
'''<br />'''
 
'''[[Beta-lactam antibiotics|beta-lactam]]'''
 
| rowspan="5" |cephalosporins
 
|I.generation
|cafazolin, cefadroxil, cefalexin, cefalotin, cefapirin
|-
|II.generation
|cefuroxim, cefamandol, cefpodoxim, proxetil, cefprozil monohydrate, cefuroxim-axetil
|-
|III.generation
|cefotaxim, cefetamet pivoxil, cefixim, cefoperazon, cefsulodin, ceftazidim, ceftibuten, ceftriaxon, co-cefoperazon
|-
|IV.generation
|cefepim, cefpirom
|-
|V.generation
|ceftarolin
|-
|carbapenems
| colspan="2" |imipenem, doripenem, ertapenem, merapenem
|-
|monobaktams
| colspan="2" |aztreonam
|-
| rowspan="3" |penicillins
|narrow-spectrum penicillins                                                                                                                                                                                                   
|penicillin G, penicillin V, cloxacilin, dicloxacilin, oxacilin, flucloxacilin
|-
|broad-spectrum penicillins
|amoxicilin, ampicilin, ticarcilin, piperacilin
|-
|beta-lactam inhibitors
|co-amoxicilin, co-ticarcilin, sulbaktam, tazobaktam
|-
|'''glycopeptides'''
| colspan="3" |teikoplanin, vankomycin
|-
| rowspan="4" |'''quinolones'''
|I.generation
| colspan="2" |nalidixic acid, oxolinic acid
|-
|II.generation
| colspan="2" |ciprofloxacin, norfloxacin, pipemicid acid, rosoxacin
|-
|III.generation
| colspan="2" |sparfloxacin, enoxacin, floroxacin, lomefloxacin, ofloxacin, pefloxacin
|-
|IV.generation
| colspan="2" |moxifloxacin
|-
|'''nitroimidazoles'''
| colspan="3" |metronidazol, ornidazol
|-
|'''nitrofurans'''
| colspan="3" |furazolidon, nifuratel, nifuroxazid, nitrofurantoin,
|-
|'''polypeptide antibiotics'''
| colspan="3" |bacitracin, colistin, gramicidin, polymyxin B
|-
|'''rifamycins'''
| colspan="3" |rifampicin, rifabutin, rifaximin, rifamycin
|-
! rowspan="11" |bakteriostatic
|'''amphenicol'''
| colspan="3" |azidamfenikol, chloramfenikol, florfenikol, thiamfenikol
|-
|'''glycylcyclines'''
| colspan="3" |tigecyclin
|-
|'''lincosamides'''
| colspan="3" |klindamycin, linkomycin
|-
| rowspan="2" |'''macrolides'''
|I.generation
| colspan="2" |erytromycin, josamycin, oleandomycin, spiramycin
|-
|II.generation
| colspan="2" |azithromycin, clarithromycin, roxithromycin
|-
|'''oxazolidinones'''
| colspan="3" |linezolid
|-
|'''pyrimidines'''
| colspan="3" |co-trimoxazol, pyrimetamin, trimetoprim
|-
|'''streptogramins'''
| colspan="3" |streptogramin A, B
|-
|'''sulphonamides'''
| colspan="3" |sulfamothoxazol, sulfasalazin, sulfathiazol, sulfisoxazol
|-
|'''sulfones'''
| colspan="3" |dapson
|-
|'''tetracyclines'''
| colspan="3" |doxycyklin
|}
[[Category:Pharmacology]]
[[Category:Infectous medicine]]
[[Category:Microbiology]]
[[Category:Biochemistry]]

Latest revision as of 21:55, 10 January 2024

Structure of gentamicin
Structure of streptomycin

Aminoglycosides are bactericidal antibiotics, mainly used in hospitals.

Mechanism of action[edit | edit source]

They inhibit protein synthesis by irreversible binding to the 30S subunit of the ribosome.

Antimicrobial spectrum[edit | edit source]

Aminoglycosides are mainly effective against infections caused by Gram-negatives (Escherichia, Klebsiella, Enterobacter, Serratia, Citrobacter, Pseudomonas, Acinetobacter, Salmonella, Shigella) and Gram-positives (Staphylococcus aureus, including β-lactamase-producing strains, Staphylococcus epidermidis). Less sensitive to resistant are streptococci and enterococci. Anaerobes are naturally resistant.

Pharmacokinetics[edit | edit source]

Aminoglycosides are not absorbed per os and act locally in the GIT. They are used parenterally (mostly i.v.). They are also well absorbed after i.m. administration. They penetrate poorly into body fluids and tissues. They are not metabolised and are excreted by glomerular filtration. Elimination is markedly reduced in renal impairment (in patients with renal insufficiency and failure; in children in the first week of life, especially premature infants due to renal immaturity; in old age when glomerular filtration decreases due to reduced renal blood flow). In these cases, aminoglycosides may accumulate and cause toxic damage. In the renal tubules, they enter cells by active transport and penetrate into lysosomes, where they cause intracellular shedding of autolytic lysosomal enzymes and subsequent cell autolysis and necrosis.

Pharmacodynamics[edit | edit source]

The effect of aminoglycosides is dependent on plasma concentration. They are hydrophilic, so they do not penetrate biological membranes easily. They are subject to active O2-dependent transport across the inner part of the membrane (therefore they do not act on anaerobes). They induce a rapid killing phase (6 h), followed by a bacteriostasis phase (even when antibiotic concentrations are low), when bacterial regrowth does not occur. This phase is also called the "post-antibiotic effect" (PAE). Its magnitude is determined by the size of the cmax, and the type of bacteria. It is amplified by the presence of leukocytes. Combination with β-lactams facilitates penetration by passive diffusion.

Side effects and toxicity[edit | edit source]

Aminoglycosides are potentially ototoxic. Ototoxicity may be acute (after high dose) from reversible blockade of calcium current in hair cells, which can be corrected by calcium administration because of the competitive antagonism between the antibiotic and calcium. Chronic ototoxicity is attributed to the time of exposure (AUC) and is up to 50% irreversible, unpredictable, sudden and intense after 5-7 days of treatment. Adverse effects include neurotoxicity. Aminoglycosides are also nephrotoxic due to their effect on the renal tubules. The damage tends to be reversible. It is important to note that they are one of the few antibiotics whose effect and toxicity correlate closely with plasma concentrations (better than dose). Yet the difference between the concentrations underlying antibiotic and toxic effects is small (they have a narrow therapeutic window). Therapeutic drug monitoring (TDM) is performed.

Benefits of aminoglycosides[edit | edit source]

  • Bactericidal
  • postantibiotic effect
  • low price

Indications[edit | edit source]

Treatment with aminoglycoside antibiotics is indicated for more serious infections: septic conditions, CNS infections, respiratory tract infections (pneumonia), intra-abdominal and hepatobiliary infections, endocarditis, complicated urinary tract infections with sensitive agents included in the antibiotic spectrum. In monotherapy they are used only in urinary tract infections, otherwise in combination mostly with β-lactams. In enterococcal endocarditis in combination with ampicillin.

Representatives of antibiotics[edit | edit source]

  • basic aminoglycosides of older type (with defined indication): streptomycin, neomycin, kanamycin
  • highly effective newer ones with lower toxicity: gentamicin, tobramycin, amikacin, netilmicin

Streptomycin
It is the drug of choice for brucellosis, tularemia, nodular fever, used as an antituberculosis. In combination with penicillin, it is used to treat endocarditis caused by viridal streptococci or enterococci.

Gentamicin

The basic broad-spectrum antibiotic of this group. It should not be given to pregnant women, newborns and premature infants. Adverse effects include nephrotoxicity (albuminuria, proteinuria), ototoxicity (dizziness, vertigo), curareform effects (neostigmine is an antagonist), skin manifestations, increased liver tests, changes in blood pressure and others.

Amikacin

It is used to treat infections that are caused by gentamicin-resistant microbes.

Links[edit | edit source]

Related articles[edit | edit source]

Sources[edit | edit source]

  • MARTÍNKOVÁ, J., S. MIČUDA a J. CERMANOVÁ. Antibiotika [online]. [cit. 2010-07-25]. <https://www.lfhk.cuni.cz/farmakol/predn/bak/kapitoly/atb-bak.doc/>.
  • LINCOVÁ, Dagmar a Hassan FARGHALI, et al. Základní a aplikovaná farmakologie. 2. vydání. Praha : Galén, 2007. ISBN 978-80-7262-373-0.

Antibiotics and chemoterapeutics[edit | edit source]

baktericidal aminoglycosides amikacin, gentamycin, isepamycin, neomycin, netilmicin, spectinomycin, streptomycin, tobramycin
antituberkulotics izoniazid, cykloserin, ethambutol, ethionamid, kapreomycin, pyrazinamid, viomycin



beta-lactam

cephalosporins I.generation cafazolin, cefadroxil, cefalexin, cefalotin, cefapirin
II.generation cefuroxim, cefamandol, cefpodoxim, proxetil, cefprozil monohydrate, cefuroxim-axetil
III.generation cefotaxim, cefetamet pivoxil, cefixim, cefoperazon, cefsulodin, ceftazidim, ceftibuten, ceftriaxon, co-cefoperazon
IV.generation cefepim, cefpirom
V.generation ceftarolin
carbapenems imipenem, doripenem, ertapenem, merapenem
monobaktams aztreonam
penicillins narrow-spectrum penicillins penicillin G, penicillin V, cloxacilin, dicloxacilin, oxacilin, flucloxacilin
broad-spectrum penicillins amoxicilin, ampicilin, ticarcilin, piperacilin
beta-lactam inhibitors co-amoxicilin, co-ticarcilin, sulbaktam, tazobaktam
glycopeptides teikoplanin, vankomycin
quinolones I.generation nalidixic acid, oxolinic acid
II.generation ciprofloxacin, norfloxacin, pipemicid acid, rosoxacin
III.generation sparfloxacin, enoxacin, floroxacin, lomefloxacin, ofloxacin, pefloxacin
IV.generation moxifloxacin
nitroimidazoles metronidazol, ornidazol
nitrofurans furazolidon, nifuratel, nifuroxazid, nitrofurantoin,
polypeptide antibiotics bacitracin, colistin, gramicidin, polymyxin B
rifamycins rifampicin, rifabutin, rifaximin, rifamycin
bakteriostatic amphenicol azidamfenikol, chloramfenikol, florfenikol, thiamfenikol
glycylcyclines tigecyclin
lincosamides klindamycin, linkomycin
macrolides I.generation erytromycin, josamycin, oleandomycin, spiramycin
II.generation azithromycin, clarithromycin, roxithromycin
oxazolidinones linezolid
pyrimidines co-trimoxazol, pyrimetamin, trimetoprim
streptogramins streptogramin A, B
sulphonamides sulfamothoxazol, sulfasalazin, sulfathiazol, sulfisoxazol
sulfones dapson
tetracyclines doxycyklin
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