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a v a i l a b l e a... j o u r n a l h o m...
european urology 49 (2006) 235–244
available at www.sciencedirect.com
journal homepage: www.europeanurology.com
Review - Infections
Treatment of Bacterial Urinary Tract Infections:
Presence and Future
Florian M.E. Wagenlehner *, Kurt G. Naber
Urologic Clinic, Hospital St. Elisabeth, Straubing, Germany
Article info
Abstract
Article history:
Accepted December 12, 2005
Published online ahead of
print on January 4, 2006
Bacterial urinary tract infections (UTIs) are frequent infections in the
outpatient as well as in the nosocomial setting. The stratification into
uncomplicated and complicated UTIs has proven to be clinically useful.
Bacterial virulence factors on the one side and the integrity of the host
defense mechanisms on the other side determine the course of the
infection. In uncomplicated UTIs Escherichia coli is the leading organism,
whereas in complicated UTIs the bacterial spectrum is much broader
including Gram-negative and Gram-positive and often multiresistant
organisms. The therapy of uncomplicated UTIs is almost exclusively
antibacterial, whereas in complicated UTIs the complicating factors
have to be treated as well. There are two predominant aims in the
antimicrobial treatment of both uncomplicated and complicated UTIs:
(i) rapid and effective response to therapy and prevention of recurrence
of the individual patient treated; (ii) prevention of emergence of resistance to antimicrobial chemotherapy in the microbial environment. The
main drawback of current antibiotic therapies is the emergence and
rapid increase of antibiotic resistance. To combat this development
several strategies can be followed. Decrease the amount of antibiotics
administered, optimal dosing, prevention of infection and development
of new antibiotic substances. The aim of this review is to highlight the
current and to describe future treatment options for UTIs.
# 2005 Elsevier B.V. All rights reserved.
Keywords:
Urinary tract infections (UTI)
Uncomplicated and
complicated UTI
Antibiotic resistance of
uropathogens
Antibiotic treatment
New antiinfectives for
treatment of UTI
* Corresponding author. Urologic Clinic, Hospital St. Elisabeth, St. Elisabeth Str. 23, D-94315
Straubing, Germany. Tel. +49 9421 710 6702; Fax: +49 9421 710 1717.
E-mail address: [email protected] (Florian M.E. Wagenlehner).
1.
Background
Urinary tract infections (UTIs) are among the most
prevalent microbial diseases, and their financial
burden on society is substantial.
In the United States of America, UTIs are responsible for over 7 million physician visits annually,
including more than 2 million visits for cystitis [1,2].
Approximately 15% of all community-prescribed
antibiotics in the United States are dispensed for
0302-2838/$ – see front matter # 2005 Elsevier B.V. All rights reserved. doi:10.1016/j.eururo.2005.12.017
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european urology 49 (2006) 235–244
UTI, at an estimated annual cost of over $1 billion [3].
Furthermore, the direct and indirect costs associated
with community-acquired UTIs in the United States
alone exceed an estimated $1.6 billion [2].
UTIs account for more than 100,000 hospital
admissions annually, most often for pyelonephritis
[1,2], and they also account for at least 40% of all
hospital-acquired infections and are in the majority
of cases catheter-associated [4–6]. Nosocomial bacteriuria develops in up to 25% of patients requiring a
urinary catheter for 7 days, with a daily risk of 5%
[6]. It has been estimated that an episode of
nosocomial bacteriuria adds $500 to $1,000 [7,8] to
the direct cost of acute-care hospitalization. In
addition the pathogens are fully exposed to the
nosocomial environment, including selective pressure by antibiotic or antiseptic substances. Therefore nosocomial UTIs comprise perhaps the largest
institutional reservoir of nosocomial antibioticresistant pathogens [6].
Whereas community acquired UTIs are often
uncomplicated, almost all nosocomial UTIs are
complicated infections. Complicated UTI is a very
heterogenous entity, with a common pattern of the
following complicating factors:
- anatomical, structural or functional alterations of
the urinary tract (e.g. stents, urine transport
disturbances, instrumentation of the urinary tract,
stones, tumors, neurological disorders)
- impaired renal function, by parenchymal diseases, or pre,-intra,-or post renal nephropathies
(e.g. acute, chronic renal insufficiencies, heart
insufficiency)
- accompanying diseases, that impair the patients
immune status (e.g. diabetes mellitus, liver insufficiency, immunosuppression, cancer, AIDS,
hypothermia).
(ii) prevention of emergence of resistance to chemotherapy in the microbial environment or at
least prevention of further increase of resistance.
2.1.
Current treatment and prophylaxis of UTI
Two major strategies currently exist in the pharmacological treatment and prophylaxis of UTIs:
(i) Antimicrobial chemotherapy and
(ii) Vaccines.
2.1.1.
Chemotherapy
The currently recommended chemotherapeutic
classes and dosages of antiinfectives for the treatment of bacterial UTI are listed in Table 1. The target
and mechanism of actions of chemotherapeutic
drugs is shown in Fig. 1.
Antimicrobial susceptibility levels are often
gauged relative to what antibiotic concentration is
achievable in the blood. However tissue levels in
renal parenchyma, the deeper layer of the urinary
bladder wall or in the prostate may be more relevant
in the treatment of UTI. Because these concentrations are difficult to assess in humans, urinary
concentrations or antimicrobial activity levels in the
urine are frequently consulted to evaluate the
activity of an antibiotic substance in the treatment
of UTI [9]. The urinary excretion and the determination of the activity of a substance in urine is
therefore important to assess if a substance is
suitable for treatment of UTI. The urinary excretion
of fluoroquinolones for example differs widely
between substances. A high urinary excretion
For antimicrobial chemotherapy the bacterial spectrum, it’s antimicrobial resistance patterns and
the development of both over the time is critical for
an effective chemotherapy.
The prevalence of uropathogens is different
comparing uncomplicated and complicated UTI.
2.
Aims in the treatment of UTI
There are two predominant aims in the treatment of
both uncomplicated and complicated UTIs:
(i) rapid and effective response to therapy and
prevention of recurrence in the individual
patient treated.
Fig. 1 – Target and mechanism of actions of current and
future antibacterial substances [modified after [50]. DHFA –
dihydrofolic acid; THFA – tetrahydrofolic acid; PABA –
para-amino-benzoic acid.
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european urology 49 (2006) 235–244
Table 1 – Groups and dosages of current chemotherapeutics for the treatment of UTI in adults
Antibiotic groups
Antimicrobial substance
b-lactams
Mecillinam
Aminopenicillin + BLI
Acylureidopenicillin + BLI
Cephalosporin Gr. 1
Cephalosporin Gr. 2
Cephalosporin Gr. 3
Cephalosporin Gr. 3a
Cephalosporin Gr. 3b
Cephalosporin Gr. 4
Carbapenem Gr. 1
Carbapenem Gr. 2
Fluoroquinolones
Fluoroquinolone
Fluoroquinolone
Fluoroquinolone
Fluoroquinolone
Gr.
Gr.
Gr.
Gr.
1
2
3
4
Daily dosage
oral
i.v./i.m.
Pivmecillinam
Ampicillin/Sulbactam
Amoxicillin/Clavulanic acid
Piperacillin/Tazobactam
Cephalexin
Cefuroxime axetil
Cefuroxime
Cefotiam
Cefpodoxim proxetile
Cefixime
Ceftibuten
Cefotaxime
Cetriaxone
Ceftazidime
Cefepime
Ertapenem
Imipenem
Meropenem
2 200*–400* mg
2 750 mg
3 625–1000 mg
–
for prophylaxis only
2 250*–500 mg
–
–
2 200 mg
1 400 mg
1 200*–400 mg
–
–
–
–
–
–
–
–
3 0.75–3 g
3 1.2–2.2 g
3 2.5–4.5 g
–
–
3 0.75–1.5 g
2–3 1–2 g
–
–
–
2–3 1–2 g
1 1–2 g
2–3 1–2 g
22g
11g
3–4 0.5–1 g
3 0.5–1 g
Norfloxacin
Ciprofloxacin
Levofloxacin
Gatifloxacin
2 400* mg
2 500–750 mg
1–2 500 mg
1 400 mg
–
2–3 400 mg
1–2 500 mg
1 400 mg
Pyrimethamines
Trimethoprim
Trimethoprim + Sulfamethoxazole
2 200 mg
2 160 mg + 2 800 mg
Fosfomycines
Fosfomycine
Fosfomycin-trometamol
1 3* g
Nitrofuranes
Nitrofurane
Nitrofurantoin
3 100* mg
Gentamicin
Tobramycin
Amikacin
–
–
–
1 5–7 mg/BW
1 5–7 mg/BW
1 15 mg/BW
Linezolid
2 600 mg
2 600 mg
Vancomycin
Teicoplanin
–
–
2 1000 mg
1 400 mg
Aminoglycosides
Aminoglycoside
Oxazolidinones
Oxazolidinone
Glycopeptides
Glycopeptide
BLI – beta-lactamase inhibitor; Gr. – group according to PEG [31]; BW – body weight (kg); *recommended for uncomplicated UTI.
(75%) can be observed with gatifloxacin (80%),
levofloxacin (84%), lomefloxacin (75%) and ofloxacin
(81%). An intermediate excretion rate (40–74%) is seen
with ciprofloxacin (43%), enoxacin (53%), fleroxacin
(67%), and a low excretion rate (<40%) is seen with
gemifloxacin (28%), moxifloxacin (20%), norfloxacin
(20%), pefloxacin (14%) and sparfloxacin (10%) [9].
Whereas most of the drugs with high or intermediate
excretion achieved the clinical indication for the
treatment of UTI, of the drugs with low excretion only
the older substance norfloxacin achieved this indication, possibly because of the lack of comparator
substances at these days. The newer fluoroquinolone
substances gemifloxacin and moxifloxacin both have
passed phase III UTI studies with the comparator
agents ciprofloxacin, ofloxacin or levofloxacin with
generally unsatisfying results (data on file Bayer
Healthcare, SmithKline Beecham). As a result of these
studies the indication for the treatment of UTI in both
substances was not achieved up to date. Therefore
both pharmacokinetic parameters, serum concentration and urinary excretion are currently used to
evaluate if an antibiotic substance might be suitable
for the treatment of UTI.
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european urology 49 (2006) 235–244
The main drawback of current antibiotic therapies
is the emergence and rapid increase of antibiotic
resistance [10]. Since antibiotics have been introduced into clinical medicine, antibiotic resistant
bacteria have evolved [11]. Antibiotic resistance
mechanisms have recently been alluded to in the
European Urology Update Series 2, 2004, page 125–135
[10]. The overall cause of increasing antibiotic
resistance is selective pressure by antimicrobial
substances in various environmental settings causing antibiotic resistant bacterial clones, followed by
the distribution of such clones facilitated by modern
medico-social circumstances [10]. The development
of new antimicrobial substances in the past has
counterbalanced this trend. However we are currently approaching a resistance level that might pose
a risk to loose effectiveness of antibiotic treatment in
the future. The epidemiology of antibiotic resistant
bacteria varies with type of infection, with medical
speciality, with region, and with time.
2.1.2.
Vaccines
There are two different agents for immunisation
currently availabale. Uro-vaxom1 and Strovac1.
Both preparations are recommended for patients
with recurrent uncomplicated UTIs.
Uro-vaxom1 is an orally administered bacterial
extract consisting of immunostimulating components derived fom 18 uropathogenic E. coli strains
[12]. A metaanalysis on five placebo controlled,
double-blind studies comprising 601 women
resulted in a pooled odds ratio of 2.28. UTIs per
year were reduced from 1 to a rate of 0.15–0.82 [13].
In a multicenter, double-blind study 453 female
patients were enrolled and Uro-vaxom1 resulted in
a 34% reduction of UTIs in patients compared to
placebo [14]. Therefore the oral immunotherapy
with Uro-vaxom is effective in the prevention of
recurrent UTI. Nevertheless a metaanalysis showed
that if antibiotic prophylaxis was compared with
placebo the reduction of recurrent UTIs was 81%
with antibiotics compared to placebo [15]. Unfortunately there are no data comparing Uro-vaxom1
with antibiotics in the prevention of recurrent UTI.
Strovac1 is a whole cell bacterial extract derived
from uropathogenic E. coli strains, P. mirabilis, M.
morganii, K. pneumoniae and E. faecalis. The preparation is administered intramuscularly also for prevention of recurrent UTI. In an prospective,
comparing study 41 patients with recurrent uncomplicated UTI were evaluated. The rate of reinfections
within 6 months was 41% in patients treated with
SulcoUrovac1 versus 96% in patients receiving
placebo [16]. Follow-up studies, however should be
carried out.
2.1.3.
Probiotics
The use of probiotics entails prophylaxis and
treatment of UTI and is mainly concentrated on
Lactobacilli. Conflicting results have been observed
in clinical trials and animal studies mostly because
unspecific strains of Lactobacilli have been used.
Positive results have only been obtained using well
characterized strains [17]. Application for prophylaxis can be intravaginal or oral. For treatment
probiotics were mainly installed into the bladder.
Clinical studies using vaginally administered
Lactobacillus rhamnosis GR1 in combination with
either L. reuteri B 54 or RC 14 resulted in reduced
UTI recurrences. In one study of 52 women, UTI
recurrences were reduced from an average of 6 per
year to 1.6 with once weekly vaginal suppositories of
GR-1/B-54 [18].
A clinical randomized, placebo controlled study
of 64 women using daily oral intake of L. rhamnosus
GR-1 and L. reuteri RC-14 led to a significant reduction
in uropathogens and yeast in the vagina [19]. It can
possibly be concluded from such findings that UTI
might also be preventable by oral intake of specific
lactobacilli.
Few studies have shown positive results in the
treatment of UTI by probiotics. One such animal
study showed that after therapeutic application of
Lactobacillus murinus bladder counts of treated mice
were significantly lower although no significant
differences were detected in P. mirabilis kidney
colonisation of treated and non-treated animals [20].
3.
Future strategies in the treatment of
bacterial UTI
The current research goals comprise the following
targets:
- known substances are improved in terms of higher
bioavailability, longer half life, better PK/PD
performance, other formulations (i.e. extended/
gastric release formulation; liposomal formulation).
- known substances are evaluated for other indications (i.e. UTI).
- new derivatives of known substance classes are
developed in order to enlarge the bacterial
spectrum, improve bioavailability, improve antimicrobial action (i.e. younger generation substances).
- new substance classes which should have new
molecular targets are developed.
- new strategies to improve susceptibility of bacteria are developed (i.e. efflux-pump inhibitors).
european urology 49 (2006) 235–244
- new strategies to slow down the emergence of
antimicrobial resistance are developed.
- alternative antimicrobial substances are under
discovery (e.g. bacteriophages, bacteriophage
enzymes).
- new compounds for vaccination in uncomplicated, and possibly as well as in complicated
UTI are developed.
Bacteria exhibit an enormous repertoire of different resistance mechanisms. Unspecific mechanisms such as reduced permeability or efflux alter the
tolerance to antibiotic substances less than specific
mechanisms, such as inactivation of the antibiotic
for example. However the antibiotic spectrum targeted is much more extensive. On the other hand
unspecific mechanisms can also be induced by non
antibiotic substances such as salicylates. Low-level
resistance can thus be confered and give bacteria a
selection-advantage [10].
What parameters should be assessed for new
drugs to become included in the treatment of UTI?
Although there are no exact quantitative prerequesites, the following qualities should be considered:
- coverage of the respective bacterial spectrum
(uncomplicated versus complicated UTIs)
- antimicrobial activity in urine in an acidic as well
as alkaline environment
- sufficient urinary excretion of the drug
3.1.
Emerging vaccines
Vaccination theoretically is the best strategy to
prevent bacterial infections. There are however some
pitfalls in the vaccination against UTIs: Complicated
UTIs show a highly heterogenous bacterial spectrum.
In uncomplicated UTIs E. coli is the predominant
pathogen. However infections and recurrent infections are usually caused by a variety of E. coli strains.
All uropathogenic E. coli as a common feature
have a FimH-chaperone-adhesin on the tip of their
type 1 fimbriae. A FimH adhesion-based vaccine,
which showed promising results in animal and in
vitro studies [24,25], so far could not enter larger
vaccination trials in humans.
A somewhat different approach is made by using
a vaginal vaccine containing 10 heat killed uropathogenic bacteria. A placebo-controlled phase II
clinical trial was performed in 54 women. Women
receiving immunisation experienced an infection in
45%, whereas the placebo treated women experienced an infection in 89% [26]. Based on this result
vaginal mucosal vaccine seem to be effective.
P. mirabilis is a difficult to treat pathogen causing
complicated UTIs especially in patients with permanent catheters or stents. The urease produced by
this organism leads to stone formation and catheter
blockage. The primary surface antigen is the MR/P
fimbria is a good candidate for vaccination. In vitro
studies with a MrpH vaccine showed promising
results [27].
Emerging chemotherapeutics
Emerging compounds are discussed in Table 2
regarding the following parameters: Substance, class,
mode of action, bacterial spectrum, pharmacokinetics with emphasis on urinary excretion, opinion
about success. The target and mechanism of actions
of future chemotherapeutic drugs are shown in Fig. 1.
3.2.
3.3.
239
4.
Prevention of emergence of antibiotic
resistance
The most important draw-back in the treatment of
UTIs is the development of antimicrobial resistance.
The prevention of emergence of resistance in
human medicine entails several strategies:
Emerging novel strategies
Bacteriophage lytic enzymes are highly evolved
molecules produced by bacterial viruses to digest
the bacterial cell wall for bacteriophage progeny
release [21]. These enzymes have been used successfully in animal models to treat bacterial infections in
blood and mucosal surfaces. Phages or their enzymes
are very specific for the pathogen without disturbing
the normal flora. These novel antimicrobial strategies
have shown very interesting in vitro results [22,23].
The further development might be promising,
because this strategy involves highly conserved
evolutionary mechanisms that have proven to be
efficacious in nature over millions of years.
-
decrease of antibiotic consumption
antibiotic cycling
new dosing strategies for antibiotics
combination of two classes of antibiotics
All strategies not specifically designed for antimicrobial therapy of UTI may have to be adjusted
accordingly.
4.1.
Decrease of antibiotic consumption
To lower antibiotic consumption in UTI three
strategies are developed and are evidence based
by several good clinical studies: (i) asymptomatic
240
european urology 49 (2006) 235–244
Table 2 – Emerging compounds are discussed regarding substance-name, antibiotic class and characteristics (mode of
action, bacterial spectrum, pharmacokinetics with emphasis on urinary excretion, opinion about success)
Antibiotic substance
Antibiotic class
Characteristics
Daptomycin (intravenous)
Lipopetide-antibiotic
Exerts its antibacterial activity by disrupting multiple aspects of the
bacterial membrane function.
Specific activity against Gram-positive pathogens including MRSA
and VRE, not active against Gram-negative bacteria.
Urinary excretion is 78%.
Clinically relevant toxicities are limited to skeletal muscle effects, at
higher dose levels, peripheral nerve effects.
The high urinary excretion promises activity in UTI, however the large
molecule might hinder distribution into urinary tract tissues. The
specific Gram-positive activity restricts the substance to treatment
of a relative small proportion of UTIs [32–37].
Tigecycline (intravenous)
Glycylcyline
Exerts its antibacterial activity by inhibiting protein synthesis.
Good activity against Gram-positive pathogens including MRSA and
VRE, and against E. coli, Klebsiella spp., Enterobacter spp. and C. freundii,
including ESBL producing organisms. Less active against P. aeruginosa,
Proteus spp., M. morganii and S. marcsecens because of efflux-mechanisms.
Urinary excretion is approximately 14%.
Side effects observed in general were mild.
The substance covers an interesting bacterial spectrum for the treatment
of UTI, although difficult to treat organisms, such a P. aeruginosa or
Proteus spp. are more resistant because of efflux pump activity.
The relatively low urinary excretion might be a potential drawback
in the treatment of UTI [38].
Cefozopran (intravenous)
Cephalosporin
Strong activity against P. aeruginosa. Because of the specific activity
against P. aeruginosa this compound is of potential interest for
the treatment of complicated UTI [39].
Ceftobiprole (intravenous)
Cephalosporin
Anti-MRSA cephalosporin. Against Gram-negative bacteria comparable
activity to group 3 and 4 cephalosporins. The spectrum of activity
towards P. aeruginosa resembles that of ceftazidime. Limited activity
against putative ESBL poducers but good activity against putative
high-level AmpC producers.
Urinary excretion is about 90%.
Because of the wide range of activity against most uropathogens and the
high urinary excretion, the substance is of potential interest in
the treatment of UTI [40].
Doripenem (intravenous)
Carbapenem
Exerts activity against Gram-positive bacteria except MRSA and
enterococci and Gram-negative bacteria including imipenem
resistant P. aeruginosa.
Urinary excretion is 75%.
Doripenem is highly excreted in urine and shows excellent activity
against P. aeruginosa. Therefore it is of potential interest for treatment
of complicated UTI [41].
Not indicated
b-lactamase inhibitors
Novel b-lactamase inhibitors are under development for the potential
treatment of UTI. Because of the increasing prevalence of
ESBL-producing enterobacteria in UTIs, novel b-lactamase inhibitors
might be promising.
Ciprofloxacin XR
(extended release) (oral)
Fluoroquinolone
Exerts identical antibacterial activity as ciprofloxacin targeting
predominantly Gram-negative pathogens with good activity
against P. aeruginosa.
Urinary excretion is 40%.
Ciprofloxacin XR is a once daily formulation, overall comparable to
twice daily ciprofloxacin [42–44].
Balofloxacin (oral)
Fluoroquinolone
Exerts good antibacterial activity against Gram-positive pathogens,
but in comparison to other fluoroquinolones decreased activity against
Gram-negative pathogens.
Urinary excretion is 86%.
Balofloxacin is in the treatment of UTI probably not superior to
other fluoroquinolones [45].
european urology 49 (2006) 235–244
241
Table 2 (Continued )
Antibiotic substance
Antibiotic class
Characteristics
Garenoxacin
(oral and intravenous)
Des-F(6)-quinolone
Not indicated
Dihydrofolate
reductase inhibitors
Exerts good antibacterial activity against Gram positive pathogens.
Activity against Gram-negative pathogens is comparable to fluoroquinolones,
such as ciprofloxacin or levofloxacin, activity against P. aeruginosa is poor.
It seems that garenoxacin exerts also activity against fluoroquinolone
resistant strains. The ability to induce resistance in vitro is apparently
less than with fluoroquinolones such as levofloxacin.
Urinary excretion is 30 to 40%.
In view of the increasing quinolone resistance, substances of this class
with decreased cross resistance and less susceptibility to resistance
emergence are needed. Des-F(6)-quinolone derivatives like garenoxacin
are promising substances for the treatment of UTI [46].
Novel dihydrofolate reductase inhibitors are under discovery. The novel
compounds are more active against Gram-positive pathogens.
Because of the long lasting activity of trimethoprim, novel dihydrofolate
reductase inhibitors are generally of interest in the treatment of UTI.
Not indicated
MurA inhibitors
Not indicated
Bacterial efflux
pump inhibitors
Not indicated
Siderophore-b-lactam
conjugates
Exert activity against Gram-positive and Gram-negative organisms to a
variable degree. They target the bacterial enzyme MurA and thus inhibit
cell wall synthesis.
In view of the increasing antimicrobial resistance novel acting antibiotics
are of interest for all kinds of bacterial infections [47].
Exert activity in combination with other antimicrobials against bacterial
species that overexpress efflux pumps, such as P. aeruginosa. Efflux
pump inhibitor agents have provided proof-of-principle of potentiation
of other animicrobials both in vitro and in vivo. The initial practical
application of improving activity against P. aeruginosa confirms that
existing antibiotics can be potentiated by inhibition of efflux pumps, and
suggests that efflux pump inhibitors may be a possible future treatment
option that would address an unmet medical need. In addition efflux
pumps contribute to a large extent to the emergence of resistance
against different antibiotic classes. Efflux pump inhibitors can narrow
the mutant selection window and thus slow down emergence of
antibiotic resistance [48].
Novel strategy for the potential treatment of Gram-negative bacterial
infections, including P. aeruginosa. Siderophore substances are covalently
bound to aminopenicillins. Because of the bacterial spectrum covered,
siderophore-b-lactam conjugation is a novel strategy of interest for the
treatment of UTIs [49].
bacteriuria must not be treated in general (there are
some exceptions), (ii) short-term therapy of uncomplicated UTI by suitable antimicrobial agents, and iii)
low dose prophylaxis in uncomplicated recurrent
UTI, respectively development of effective vaccines.
4.2.
Antibiotic cycling
For antibiotic cycling there are practically no reliable
studies available concerning treatment of UTI. There
is, however, a more or less general agreement that the
overuse of one group of antibiotics selecting for
similar resistance genes should be avoided especially
in a hospital of institutional setting. Therefore good
guidelines recommend in general alternative substances as well, to allow antibiotic cycling.
4.3.
Antibiotic dosing
The key idea of the third strategy, however yet
clinically untested, is based on the use of antibiotic
concentrations that require bacterial cells to obtain
two concurrent resistance mutations for growth.
That concentration has been called mutant prevention concentration (MPC) because no resistant bacterial colony is recovered even when high numbers of
bacterial cells are plated. Resistant mutants are
selected exclusively within a vulnerable concentration range (mutant selection window) that extends
from the point where growth inhibition begins,
approximately by the minimal inhibitory concentration, up to the mutant prevention concentration [28].
If the antibiotic dose given is high enough also to kill
the mutant population, the selection of clinically
resistant mutants could be restricted [29]. A further
idea in this respect is to narrow the mutant selection
window by developing appropriate substances,
for example those which lower the MPC, or those
that lower these concentrations of other drugs (e.g.
efflux pump inhibitors). Therefore drugs with the
most favourable pharmacokinetic/pharmacodynamic characteristics should be used as first-line
242
european urology 49 (2006) 235–244
agents in order to preserve the potential of a specific
drug class and, most importantly, to provide the
patient with an optimally effective regimen. On the
other hand the dosing of an antibiotic should be
aimed high enough to reach the MPC.
4.4.
Combination of two classes of antibiotics
For some organisms or in some infections it is
difficult to find antibiotics that can be dosed high
enough to prevent emergence of antibiotic resistance. A typical example is antibiotic treatment of M.
tuberculosis where combination therapy with two or
more antibiotic substances of different classes is
recommended. In order to become resistant against
two antibiotic substances, two concurrent mutations are required for bacterial growth, which has a
very low probability to occur [28]. Clinical studies in
UTIs however are very scarce. In one study combination therapy with a macrolide and ciprofloxacin
showed higher efficacy in eliminating uropathogens
than the single therapy with ciprofloxacin [30]. The
success of the macrolide in this study however was
more attributed to the specific biofilm inhibiting
effect of the macrolide [30].
- The low dose antibiotic prophylaxis in recurrent
UTIs is effective, however the emergence of
antibiotic resistant pathogens might be underestimated, although the idea of antibiotic prophylaxis is to use low dosages that do not fall within
the mutant selection window and thus theoretically should not cause emergence of resistance.
- Vaccination will be an important issue in the
future. The most experience has been made with
vaccines in recurrent uncomplicated cystitis,
because a single species E. coli causes more than
90% of episodes. Desirable would be more
attempts for vaccination in complicated UTIs,
especially with difficult to treat organisms like P.
aeruginosa.
The ongoing process in the treatment of infectious diseases is highly dynamic. The substantial
difference to non-infectious diseases is that the
management of an infection in a single patient allways has an effect on the environment. Considering this, the management of infectious diseases
must be highly responsible.
References
5.
Conclusion
There are a number of new derivatives of classes in
use. In most cases these derivatives are subject to
cross resistance inherent to the whole substance
class. Therefore new classes of antibiotics with
unrelated mode of action are a more valuable development. The indications for treatment of such novel
substances should be selected very carefully, in order
to conserve new substance classes as long as possible.
For a variety of reasons however new substance
classes will be increasingly difficult to launche.
Therefore new derivatives of classes in use should
be thoroughly screened for their potential to induce
resistance. Substances with a low potential to select
resistant strains will be highly welcome. Very important in that respect will be combinatory agents that
impede general widespread mechanisms of resistance, such as efflux pump inhibitors. Novel antimicrobial strategies, such as the use of bacteriophagal
enzymes urgently need to be evaluated further.
The best strategy in infection in general is the
prevention of the disease. In UTI there is a variety of
concepts involved:
- Hygienic issues and catheter materials are predominantly important in complicated, health-care
associated UTIs.
[1] Warren JW, Abrutyn E, Hebel JR, Johnson JR, Schaeffer AJ,
Stamm WE. Guidelines for antimicrobial treatment of
uncomplicated acute bacterial cystitis and acute pyelonephritis in women. Infectious Diseases Society of America
(IDSA). Clin Infect Dis 1999;29(4):745–58.
[2] Foxman B. Epidemiology of urinary tract infections: incidence, morbidity, and economic costs. Am J Med 2002;
113(Suppl. 1A):5S–13S.
[3] Mazzulli T. Resistance trends in urinary tract pathogens
and impact on management. J Urol 2002;168(4 Pt 2):1720–2.
[4] Gales AC, Jones RN, Gordon KA, et al. Activity and spectrum of 22 antimicrobial agents tested against urinary
tract infection pathogens in hospitalized patients in Latin
America: report from the second year of the SENTRY
antimicrobial surveillance program (1998). J Antimicrob
Chemother 2000;45(3):295–303.
[5] Ruden H, Gastmeier P, Daschner FD, Schumacher M.
Nosocomial and community-acquired infections in Germany. Summary of the results of the First National Prevalence Study (NIDEP). Infection 1997;25(4):199–202.
[6] Maki DG, Tambyah PA. Engineering out the risk for infection with urinary catheters. Emerg Infect Dis 2001;
7(2):342–7.
[7] Patton JP, Nash DB, Abrutyn E. Urinary tract infection:
economic considerations. Med Clin North Am 1991;
75(2):495–513.
[8] Lai KK, Fontecchio SA. Use of silver-hydrogel urinary
catheters on the incidence of catheter-associated urinary
tract infections in hospitalized patients. Am J Infect Control 2002;30(4):221–5.
european urology 49 (2006) 235–244
[9] Naber KG. Which fluoroquinolones are suitable for the
treatment of urinary tract infections? Int J Antimicrob
Agents 2001;17(4):331–41.
[10] Wagenlehner F, Naber KG. Antibiotics and resistance of
uropathogens. EAU Update Series 2004;2:125–35.
[11] Abraham E, Chain E. An encyme from bacteria able to
destroy penicillin. Nature 1940;146:837.
[12] Bauer H, Bleßmann GS, Pitrow DB, Rahlfs VW. Prevention
of recurrent urinary tract infections with immunoactive
E. coli fractions. Eur J Obstet Gyn 1999;86:33.
[13] Bauer HW, Rahlfs VW, Lauener PA, Blessmann GS. Prevention of recurrent urinary tract infections with
immuno-active E. coli fractions: a meta-analysis of five
placebo-controlled double-blind studies. Int J Antimicrob
Agents 2002;19(6):451–6.
[14] Bauer HW, Alloussi S, Egger G, Blumlein HM, Cozma G,
Schulman CC. A long-term, multicenter, double-blind
study of an Escherichia coli extract (OM-89) in female
patients with recurrent urinary tract infections. Eur Urol
2005;47(4):542–8, discussion 548.
[15] Albert X, Huertas I, Pereiro II, Sanfelix J, Gosalbes V,
Perrota C. Antibiotics for preventing recurrent urinary
tract infection in non-pregnant women. Cochrane Database Syst Rev (3):2004. p. CD001209.
[16] Riedasch G, Mo¨hring K. Immunisierungstherapie rezidivierender Harnwegsinfekte der Frau. Therapiewoche
1986;6:896–900.
[17] Reid G, Bruce RW. Probiotics to prevent urinary tract infections: the rationale and evidence. World J Urol in press.
[18] Reid G, Bruce AW, Taylor M. Instillation of Lactobacillus
and stimulation of indigenous organisms to prevent
recurrence of urinary tract infections. Microecol Ther
1995;23:32–45.
[19] Reid G, Charbonneau D, Erb J, et al. Oral use of Lactobacillus rhamnosus GR-1 and L. fermentum RC-14 significantly alters vaginal flora: randomized, placebocontrolled trial in 64 healthy women. FEMS Immunol
Med Microbiol 2003;35(2):131–4.
[20] Fraga M, Scavone P, Zunino P. Preventive and therapeutic
administration of an indigenous Lactobacillus sp. strain
against Proteus mirabilis ascending urinary tract infection in a mouse model. Antonie Van Leeuwenhoek
2005;88(1):25–34.
[21] Fischetti VA. Bacteriophage lytic enzymes: novel antiinfectives. Trends Microbiol 2005;13(10):491–6.
[22] Cheng Q, Nelson D, Zhu S, Fischetti VA. Removal of group
B streptococci colonizing the vagina and oropharynx of
mice with a bacteriophage lytic enzyme. Antimicrob
Agents Chemother 2005;49(1):111–7.
[23] Yoong P, Schuch R, Nelson D, Fischetti VA. Identification
of a broadly active phage lytic enzyme with lethal activity
against antibiotic-resistant Enterococcus faecalis and
Enterococcus faecium. J Bacteriol 2004;186(14):4808–12.
[24] Langermann S, Mollby R, Burlein JE, et al. Vaccination
with FimH adhesin protects cynomolgus monkeys from
colonization and infection by uropathogenic Escherichia
coli. J Infect Dis 2000;181(2):774–8.
[25] Meiland R, Geerlings SE, Langermann S, Brouwer EC,
Coenjaerts FE, Hoepelman AI. Fimch antiserum inhibits
[26]
[27]
[28]
[29]
[30]
[31]
[32]
[33]
[34]
[35]
[36]
[37]
[38]
[39]
[40]
[41]
243
the adherence of Escherichia coli to cells collected by
voided urine specimens of diabetic women. J Urol
2004;171(4):1589–93.
Uehling DT, Hopkins WJ, Elkahwaji JE, Schmidt DM, Leverson GE. Phase 2 clinical trial of a vaginal mucosal vaccine
for urinary tract infections. J Urol 2003;170(3):867–9.
Li X, Mobley HL. Vaccines for Proteus mirabilis in urinary
tract infection. Int J Antimicrob Agents 2002;19(6):461–5.
Zhao X, Drlica K. Restricting the selection of antibioticresistant mutants: a general strategy derived from fluoroquinolone studies. Clin Infect Dis 2001;33(Suppl. 3):
S147–56.
Drlica K. Antibiotic resistance: can we beat the bugs? Drug
Discov Today 2001;6(14):714–5.
Sano M, Takahashi S, Nishimura M, et al. A clinical study
on combination therapy of antimicrobial agents for complicated urinary tract infection–with special reference to
combination with clarithromycin. Nippon Hinyokika
Gakkai Zasshi 1997;88(6):596–604.
Vogel F, Naber KG, Wacha H, Shah P, So¨rgel F, Kayser FH,
et al. Parenterale Antibiotika bei Erwachsenen. Chemotherapie J 1999;8:2–49.
Snydman DR, Jacobus NV, McDermott LA, Lonks JR, Boyce
JM. Comparative In vitro activities of daptomycin and
vancomycin against resistant gram-positive pathogens.
Antimicrob Agents Chemother 2000;44(12):3447–50.
Laganas V, Alder J, Silverman JA. In vitro bactericidal
activities of daptomycin against Staphylococcus aureus
and Enterococcus faecalis are not mediated by inhibition
of lipoteichoic acid biosynthesis. Antimicrob Agents Chemother 2003;47(8):2682–4.
Fuchs PC, Barry AL, Brown SD. In vitro bactericidal activity
of daptomycin against staphylococci. J Antimicrob Chemother 2002;49(3):467–70.
Louie A, Kaw P, Liu W, Jumbe N, Miller MH, Drusano GL.
Pharmacodynamics of daptomycin in a murine thigh
model of Staphylococcus aureus infection. Antimicrob
Agents Chemother 2001;45(3):845–51.
Woodworth JR, Nyhart Jr EH, Brier GL, Wolny JD, Black HR.
Single-dose pharmacokinetics and antibacterial activity
of daptomycin, a new lipopeptide antibiotic, in healthy
volunteers.
Antimicrob
Agents
Chemother
1992;36(2):318–25.
De Bruin MF, Tally FP. Efficacy and safety of daptomycin
for the treatment of bacteremia and serious infections
due to Gram-positive bacteria. in 4th Decennial International
Conference on Nosocomial and Healthcare-Associated Infections, 2000 Vol. Abstract 594, 2000.
Rubinstein E, Vaughan D. Tigecycline: a novel glycylcycline. Drugs 2005;65(10):1317–36.
Kumamoto Y, Tsukamoto T, Matsukawa M, et al. Comparative studies on activities of antimicrobial agents
against causative organisms isolated from patients with
urinary tract infections (2002). I. Susceptibility distribution. Jpn J Antibiot 2004;57(3):246–74.
Heinzl S.
Neue Antibiotika Chemotherapie Journal
2005;14:54–7.
Jones RN, Sader HS, Fritsche TR. Comparative activity of
doripenem and three other carbapenems tested against
244
[42]
[43]
[44]
[45]
european urology 49 (2006) 235–244
Gram-negative bacilli with various beta-lactamase resistance mechanisms. Diagn Microbiol Infect Dis 2005;
52(1):71–4.
Henry Jr DC, Bettis RB, Riffer E, et al. Comparison of oncedaily extended-release ciprofloxacin and conventional
twice-daily ciprofloxacin for the treatment of uncomplicated urinary tract infection in women. Clin Ther
2002;24(12):2088–104.
Wagenlehner FM, Kinzig-Schippers M, Tischmeyer U,
Wagenlehner C, Sorgel F, Dalhoff A, Naber KG. Pharmacokinetics of ciprofloxacin XR (1000 mg) versus volunteers
receiving a single oral dose. Int J Antimicrob Agents
2005;Dec 9, [Epub ahead of print].
Talan DA, Naber KG, Palou J, Elkharrat D. Extendedrelease ciprofloxacin (Cipro XR) for treatment of urinary
tract infections. Int J Antimicrob Agents 2004;23(Suppl.
1):S54–66.
Rubinstein E. History of quinolones and their side effects.
Chemotherapy 2001;47(Suppl. 3):3–8, discussion 44–48.
[46] Dalhoff A, Schmitz FJ. In vitro antibacterial activity and
pharmacodynamics of new quinolones. Eur J Clin Microbiol Infect Dis 2003;22(4):203–21.
[47] Eschenburg S, Priestman MA, Abdul-Latif FA, Delachaume C, Fassy F, Schonbrunn E. A novel inhibitor that
suspends the induced fit mechanism of UDP-N-acetylglucosamine enolpyruvyl transferase (MurA). J Biol Chem
2005;280(14):14070–5.
[48] Kaatz GW. Inhibition of bacterial efflux pumps: a new
strategy to combat increasing antimicrobial agent resistance. Expert Opin Emerg Drugs 2002;7(2):223–33.
[49] Heinisch L, Wittmann S, Stoiber T, Scherlitz-Hofmann I,
Ankel-Fuchs D, Mollmann U. Synthesis and biological
activity of tris- and tetrakiscatecholate siderophores
based on poly-aza alkanoic acids or alkylbenzoic acids
and their conjugates with beta-lactam antibiotics. Arzneimittelforschung 2003;53(3):188–95.
[50] Neu HC. The crisis in antibiotic resistance. Science
1992;257(5073):1064–73.