Summary of
positive and negative aspects and dosing of potentially useful drugs in the
treatment of infections with ESBL- and
AmpC-producing Enterobacteriaceae:
Drug
|
Positive aspects
|
Negative aspects
|
Dosing (for adults with normal
renal function)
and comments
|
Meropenem, imipenem,
doripenem
|
Reference drugs,
usually active
|
Ecological impact;
less experience with doripenem
|
Standard dosing is
recommended
|
Ertapenem
|
Not active against P. aeruginosa; usually
active; convenient
for outpatient therapy
and deescalation
from other carbapenems
|
Ecological impact if
CPE endemicity / outbreak; doubts in
cases of septic
shock (insufficient dosing?); anecdotal failures described with development
of resistance (porin loss)
|
1 g/day in most
situations; for septic shock or high-inoculum infections with borderline MIC isolates,
use other alternatives or increase
dose to 2 g/day
|
Amoxicillin-clavulanic
acid
|
No inoculum effect;
probably noninferior to
carbapenems in UTI
and biliary tract
infections; not
active against P. aeruginosa;
convenient for oral switch
|
Not available for
i.v. use in many countries;
heterogeneous
resistance rates, usually >40% among
ESBL producers; AmpC
producers are resistant
|
Intravenous, 2.2 g/8
h; oral, at least 1.250 g/8h for UTI
|
Ceftolozane-tazobactam
|
Areas with large
proportions of susceptible isolates
|
Reserve drug for MDR
P. aeruginosa infection; scarce
experience so far;
10-30% resistance rates among ESBL producers, lower rates in AmpC producers
|
1.5 g/8h; approved
for cUTI and cIAI (with
metronidazole);
consider 3 g/8 h for
pneumonia
|
Ceftazidime-avibactam
|
Large proportion of
susceptible isolates
|
Reserve drug for
KPC- or OXA-48-producing
Enterobacteriaceae
|
2.5 g/8 h; approved
for cUTI and cIAI (with
metronidazole); in Europe,
also approved for HAP in case of limited options
|
Cefotaxime,
ceftriaxone, ceftazidime,
cefepime
|
Some ESBL-E may be
susceptible; cefepime
is usually active
against AmpC producers
|
Most isolates are
resistant (except to cefepime in the
case of AmpC
producers); inoculum effect; ecological
impact; clinical
data are scarce and contradictory
|
If used, high doses
are recommended
(cefotaxime, 1 g/6 h
to 2 g/8 h; ceftazidime
or cefepime, 2 g/8
h)
|
Cefoxitin,
cefotetan, cefmetazole,
moxalactam, flomoxef
|
Not active against P. aeruginosa; areas with
large proportions of
susceptible isolates
(ESBL producers);
probably useful against
UTI for stable
patients
|
AmpC producers are
resistant; inoculum effect;
observational
studies with contradictory results;
anecdotally
described development of resistance
during therapy
|
High doses; close
follow-up needed
|
Temocillin
|
Active against ESBL
and AmpC producers;
not active against P. aeruginosa
|
Not available in
many countries; comparative studies are lacking
|
Probably 2 g every 8
h
|
Gentamicin,
tobramycin, amikacin
|
Active against many
ESBL and AmpC producers; useful for UTI
|
Nephrotoxicity; less
efficacious in non-UTI infections; heterogeneous resistance rates
|
Standard dosing; may
be considered empirically as carbapenem sparing
agents (in monotherapy
or in
combination with a
lower-spectrum beta-
lactam) until
microbiological data are available
|
Tigecycline
|
Active against most
ESBL and AmpC producers; not active against P. aeruginosa
|
FDA and EMA warnings
for use only if other options
are
unavailable/unsuitable; probably not a good
option for UTI or
HAP
|
100-mg loading dose,
50 mg/12 h; may be an
alternative in cIAI
|
Fosfomycin (i.v.)
|
Noninferior to
piperacillin-tazobactam in
cUTI (pending
publication of data)
|
Not available in
many countries; scant experience; risk of emergence of resistant
subpopulations with monotherapy
|
4 g/6 h to 6–8 g/8 h
|
Ciprofloxacin,
levofloxacin
|
Potentially useful
for fully susceptible isolates; convenient for oral switch
|
Ecological impact;
most isolates are resistant; failures for isolates with MICs of 0.5–1
mg/liter have been described
|
For i.v.
ciprofloxacin, 400 mg/8–12 h; for oral ciprofloxacin, 500–700 mg/12 h; for
levofloxacin (i.v.,
oral), 750 mg/24 h
|
Trimethoprim-sulfamethoxazole
( Bactrim /
Co-trimoxazole )
|
Convenient for oral switch
|
Most isolates are resistant; scant published
experience
|
i.v. or oral,
160/800 mg/8–12 h
|
·
CPE:
carbapenemase-producing Enterobacteriaceae
·
cUTI:
complicated urinary tract infection
·
cIAI:
complicated intrabadominal infection
Recommended
dosing for the most frequently used drugs against carbapenem-resistant Enterobacteriaceae
(CRE) for patients with normal renal function:
Drug
|
Usual/standard dose(s)
|
Dosing for CRE and comments
|
Meropenem
|
1 g/8 h
|
2 g/8 h by EI
(isolates with MICs of 2–8 mg/liter; for isolates with higher MICs, it is
probably not efficacious)
|
Ertapenem
|
1 g/24 h
|
Consider 2 g/day for
double-carbapenem regimens
|
From the EMA, loading
dose, 6–9 MU, and then 9 MU/day in 2–3 doses; from the FDA, 2.5–5 mg of
colistin base activity/kg/day
|
EMA dose is
recommended for severe CRE infections; the need for a loading dose and high
continuation dose in patients without severe infection/shock is controversial
|
|
From the FDA, 1.5–2.5
mg/kg/day in 2 doses
|
For mild infections
and isolates with MICs of ≤1 mg/liter, the FDA dose is probably appropriate;
for severe infections and isolates with MICs of up to 4 mg/liter, a loading
dose of 2–2.5 mg/kg followed by 3 mg/kg/day in 2 doses is recommended
(controversially)
|
|
Tigecycline
|
100-mg loading dose
and then 50 mg/12 h
|
For HAP, cUTI, BSI, or
shock, consider a 200-mg loading dose and then 100 mg/12 h
|
Gentamicin, tobramycin
|
5–7 mg/kg/day
|
For HAP or shock
without other options, higher doses (10–15 mg/kg) might be considered, but
the risk of toxicity is high; TDM is recommended
|
Amikacin
|
15–20 mg/kg/day
|
For HAP or shock
without other options, higher doses (25–30 mg/kg) might be considered, but
the risk of toxicity is high; TDM is recommended
|
Fosfomycin
|
4 g/6 h to 8 g/8 h
|
Use in combination;
high sodium concn
|
Temocillin
|
2 g/8–12 h
|
KPC producers are
occasionally susceptible; continuous infusion improves PK-PD target
attainment
|
Aztreonam
|
1–2 g/8 h
|
MBL producers are
susceptible if they are not ESBL or AmpC producers
|
Ceftazidime
|
1–2 g/8 h
|
OXA-48 producers are
susceptible if they are not ESBL or AmpC producers
|
Ceftazidime-avibactam
|
2.5 g/8 h
|
KPC and OXA-48
producers are frequently susceptible
|
Meropenem-vaborbactam
|
2/2 g/8 h
|
KPC producers are
frequently susceptible
|
Please refer to the
text for explanations and references. EI, extended infusion; EMA, European
Medicines Agency; FDA, U.S. Food and Drug Administration; HAP,
hospital-acquired pneumonia; cUTI, complicated urinary tract infection; BSI,
bloodstream infection; MU, million units; TDM, therapeutic drug monitoring;
MBL, metallo-β-lactamase.
a = One million
units of colistimethate sodium = 80 mg colistimethate sodium = 34 mg of
colistin base activity.
b = One million
units of polymyxin B = 100 mg of colistin base activity.
|
||
Multidrug-resistant A. baumannii and P. aeruginosa
For
multidrug-resistant A. baumannii and P. aeruginosa, the polymyxins (ie,
colistin and polymyxin B) are usually the cornerstones for therapy. Combination
therapy is also advised when polymyxins are used to treat multidrug-resistant A. baumannii and P. aeruginosa.
Most
multidrug-resistant A. baumannii and P. aeruginosa retain susceptibility for
the polymyxins. Aminoglycosides may be useful, particularly for urinary tract
infections, assuming susceptibility is retained for one of these antibiotics.
Otherwise, there are a limited number agents with potential activity.
Carbapenem-resistant A. baumannii and
P. aeruginosa are typically resistant
to all beta-lactams and fluoroquinolones. The intrinsic resistance of these
organisms further limits antibiotic options. Although sulbactam has been used
to treat some infections due to A.
baumannii, most multidrug-resistant isolates of A. baumannii have reduced susceptibility to this agent.
Acinetobacter
Infection
In the
setting of resistance to first line agents, therapeutic options are generally
limited to polymyxins (colistin [polymyxin E] and polymyxin B), minocycline,
and tigecycline. We generally use polymyxins, for which there is the most
clinical experience in treating extensively drug-resistant Acinetobacter. Furthermore, tigecycline may not reach adequate
levels in the serum, urinary tract, or CNS to successfully treat infections in
these compartments. Susceptibility testing for these agents should be performed
as well prior to their use given the possibility of resistance.
We
generally favor using a second agent, such as a carbapenem, minocycline,
tigecycline, or rifampin, in addition to polymyxins for serious infections (eg,
bacteremia, pneumonia, critical illness) with resistant isolates. There are no
definitive clinical data that demonstrate improved outcomes with combination
versus monotherapy, and some randomized trials have suggested that certain
combinations (colistin and rifampin or colistin and meropenem) resulted in
comparable clinical outcomes as monotherapy with colistin. Nevertheless,
infections with multidrug-resistant Acinetobacter
are associated with high mortality rates, and we are concerned that the use of
a single agent is not adequate, particularly since resistance can develop
during therapy, leaving no therapeutic alternatives.
Inhaled
colistin may be beneficial in select patients, although not all studies suggest
a benefit. We favor use of inhaled colistin among patients with severe
pneumonia due to Acinetobacter that
is resistant to beta-lactams and carbapenems (ie, sensitive to colistin only),
since intravenous colistin yields low lung concentration.
Pseudomonas aeruginosa infection
A polymyxin
(colistin or polymyxin B) is the only therapeutic option for some strains of
multidrug-resistant P. aeruginosa.
Thus colistin is being increasingly used despite its well-known propensity for
causing nephrotoxicity and ototoxicity
References:
- · Rodríguez-Baño et al. Treatment of Infections Caused by Extended-Spectrum-Beta-Lactamase-, AmpC-, and Carbapenemase-Producing Enterobacteriaceae. Clinical Microbiology Reviews Feb 2018, 31 (2) e00079-17
- · UptoDate: Overview of carbapenemase-producing gram-negative bacilli
- · UptoDate: Acinetobacter infection: Treatment and prevention
- · UptoDate: Principles of antimicrobial therapy of Pseudomonas aeruginosa infections
All information accessed on 24 Feb 2020
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