Antibiotic-Resistant E. coli in Uncomplicated Community-Acquired Urinary Tract Infection
A Prospective Cohort Study from 2015/16 (the SARHA Study) Compared With Data From the Antimicrobial Resistance Surveillance System (ARS)
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Background: Routine urine culture testing is not recommended for uncomplicated urinary tract infections (UTIs). As a result, the antibiotic resistance patterns or the organisms causing UTIs are not adequately reflected in routine data. We studied the sensitivity of Escherichia coli (E. coli) to trimethoprim (TMP) and to cotrimoxazole (i.e., trimethoprim/sulfamethoxazole, TMP/SMX) in community-acquired UTI and compared the findings with the resistance data of the Antimicrobial Resistance Surveillance System (ARS).
Methods: General practitioners and internists in private practice prospectively recruited all of their adult patients with symptoms of a urinary tract infection from May 2015 to February 2016. Urine specimens from all patients were tested (including urine culture testing and antibiotic susceptibility) and infections were defined as uncomplicated or complicated UTIs.
Results: 1245 participants from 58 medical practices were enrolled in the study. Pathogenic organisms were found in the urine of 877 patients, of whom 74.5% had E. coli infections. Among the E.-coli-positive UTIs, 52.4% were classified as uncomplicated and 47.6% as complicated. The prevalence of E. coli that was resistant to TMP and to TMP/SMX in uncomplicated UTIs was 15.2% and 13.0%, respectively, compared to 25.3% and 24.4%, respectively, from all UTIs in ARS in 2015. Study participants who had previously taken antibiotics had the highest prevalence of E. coli resistance (30.9%), followed by those who had two or more UTIs within the past six months (28.9%).
Conclusion: E. coli with resistance to TMP was significantly less prevalent among the study patients with uncomplicated UTIs than in the routine data of the ARS. Accordingly, TMP should still be considered as an option for the treatment of uncomplicated UTIs. TMP/SMX is considered the agent of second choice because of its side effects. Surveillance systems based on routine data do not yield a representative sample for the evaluation of the resistance situation in patients with uncomplicated UTIs.
Urinary tract infection (UTI) is one of the most common bacterial infections seen in primary care and thus one of the most common indications for which antibiotics are precribed. (1–3). In 2013, the prevalence of the diagnoses “Urinary Tract Infection” (N39.0) or “Acute Cystitis” (N30.0) was 7.3% and 1.7%, respectively, among all females aged 12 years or older insured with the German statutory health insurer Barmer GEK (4). As the majority of the community-acquired UTIs manifested as an acute cystitis, in this study the term uncomplicated UTI primarily refers to acute uncomplicated cystitis (5). Among other studies, E. coli has been found to be one of the main causative agents (70–80%) of uncomplicated UTI (6–8). Complicated urinary tract infections are defined as UTIs occurring in patients with risk factors for severe disease, sequelae or treatment failure. Microbiological testing of the urine prior to initiation of treatment is recommended for patients with complicated UTIs, pregnant women and patients with recurrent urinary tract infections. Uncomplicated urinary tract infections, most commonly affecting young healthy women, are caused by a narrow spectrum of causative agents. The antibiotic susceptibility of these bacteria can be predicted with high probability (9). Thus, routine urine culture testing is not recommended for practical and economic reasons; instead, uncomplicated UTIs are treated with empiric antibiotic therapy (6, 10).
Treatment recommendations for empiric antibiotic therapy are based on antimicrobial resistance data from epidemiological studies or from surveillance systems such as the Antimicrobial Resistance Surveillance System (ARS). ARS is a laboratory-based surveillance system established at the Robert Koch Institute with the aim of providing reference data on the antimicrobial resistance situation in the community-based generalist/internist and inpatient hospital care settings (11, 12).
Patterns of antibiotic resistance can show time and regional differences (13). ARS provides regular up-to-date data and is an essential source of information for the selection of appropriate empiric antibiotic therapy. However, since microbiological testing is not carried out on a routine basis for patients with uncomplicated UTIs, results in ARS for uncomplicated UTIs are underrepresented. In contrast, ARS data likely reflects the situation of complicated UTIs where urine cultures are obtained in the community-based medical practice setting. A wider bacterial spectrum and higher proportions of resistance can be expected in cases of complicated UTIs, so the occurence of antibiotic resistance in patients with uncomplicated UTIs is likely overestimated (14–17). This could lead to the misconception that actually appropriate antibiotics are no longer recommended as first-line agents for uncomplicated UTI and that reserve antibiotics with a broader spectrum are used instead.
Trimethoprim (TMP) and co-trimoxazole (trimethoprim/sulfamethoxazole, TMP/SMX) are generally well-tolerated and cost-effective drugs, used in the past as first-line agents in the empirical management of uncomplicated urinary tract infections. Proportions of resistance should be below 20% to ensure optimum benefits from these antibiotics (6, 13, 18). Because proportions of resistance significantly greater than 20% had been found, TMP und TMP/SMX were no longer considered first-line treatments for uncomplicated UTIs in the recommendations of the German clinical practice (S3) guideline published in 2010 (6, 8, 19). Nevertheless, these agents were still among the antibiotics most frequently prescribed for the treatment of urinary tract infections (4). In the revised version of this clinical practice guideline published in 2017, TMP was once again recommended as the first-line agent (6, 20).
Our study aimed to provide up-to-date data on the antibiotic susceptibility of E. coli in community-acquired uncomplicated UTIs. Another aim was to determine if and to what extent the proportions of antibiotic resistance in uncomplicated UTIs are overestimated in ARS data. The results of this study will contribute to answering the question of how ARS routine data from urine cultures can be used to guide the management of community-acquired uncomplicated UTI in the future.
In the SARHA study (Surveillance der Antibiotikaresistenz von Harnwegsinfektionen, die ambulant erworben wurden [Surveillance of antibiotic resistance in community-acquired urinary tract infections]), the current proportions of resistance of E. coli to TMP, TMP/SMX and other antibiotics in community-acquired uncomplicated urinary tract infections were assessed. These results were compared with the resistance situation in complicated UTIs, in the participating practices in the year prior to the study period, and with the ARS resistance data from urine cultures requested by community-based general/internal medicine practices.
Among 40 microbiological laboratories participating in ARS in 2015, 4 laboratories were recruited for this study based on the following criteria:
- regular transfer of outpatient care data on organisms and resistances detected in urine specimens from various regions in Germany
- interest in study participation.
From May 2015 to February 2016, community-based internists and general practitioners who were clients of the participating laboratories were recruited. All patients aged 18 years or older presenting in these practices with clinical signs and symptoms of urinary tract infection (dysuria, frequent urge to urinate) were included in this study after giving their informed consent. Each participant provided one urine sample. Microbiological testing was performed on all urine samples, regardless of the recommendation of the clinical practice guideline.
Antimicrobial susceptibility testing
Pathogen identification and resistance testing was performed using automated systems. A bacterial count ≥ 10³ colony-forming units (CFU)/mL was considered a positive urine culture (21, 22). In addition to TMP and TMP/SMX, the following antibiotics were used in the antimicrobial susceptibility testing: fosfomycin, nitrofurantoin, ampicillin, amoxicillin/clavulanic acid, and ciprofloxacin. The interpretation of the results was based on the guidelines of the European Committee on Antimicrobial Susceptibility Testing (EUCAST).
The questionnaire collected information about year and month of birth, sex and the following parameters:
- Diabetes mellitus
- Indwelling urinary catheter
- Functional/anatomical abnormalities
- Urologic/renal diseases
- Antibiotic therapy within the last 2 weeks
- Frequency of occurrence of urinary tract infections within the last 6 months.
In addition, the treating physicians stated whether they would have ordered a urine culture under routine conditions, rather than within the context of this study alone.
In a univariable and multivariable analysis, the association of various factors with the resistance to TMP or TMP/SMX among patients with UTIs and with E.coli detected was assessed using logistic regression. “pcorr” is used to identify p-values corrected for multiple comparisons. Uncorrected p-values are to be considered as descriptive only.
For a comprehensive description of the surveillance system ARS, the comparison groups and further details on the statistical methods used, please refer to the eMethods section.
Ethics committee approval application
A study approval of the ethics committee of the Charité Universitätsmedizin Berlin is available (number EA2/008/15).
Four laboratories from various regions of Germany (north, east, west, southwest) participated in this study (eFigure 1). Among 58 practices, a total of 1309 patients were recruited. Of these, 1245 patients were included in this study and their data were analyzed. Reasons for patient exclusions were missing informed consent, age <18 years (minority) or inconsistencies between sample and patient data.
In 877 (70.4% of 1245) patients, positive urine culture results were available (800 [91.2%] female; 77 [8.8%] male). The average age of women diagnosed with UTI was 57.5 years (standard deviation [SD] 16.1; range 18–95) and the average age of men was 68.3 years (SD 20.9; range 25–96).
In 749 samples (85.4% of samples with positive urine culture), only one organism was identified, whereas 128 (14.6%) had more than one organism. E. coli was the most commonly isolated pathogen in 653 samples (74.5%) (Table 1). The frequency of occurrence of additional information about patients with E.coli detected can be seen in eTable 1. In 342 (52.4%) of the E. coli-positive samples, patients were diagnosed with uncomplicated UTIs, in 311 (47.6%) with complicated UTIs (Figure 1).
Results of susceptibility testing
Antimicrobial susceptibility testing did not always include all antibiotics. For amoxicillin/clavulanic acid and ampicillin, the proportion of tested isolates was below 50%, and for all other antibiotics above 90%. The following proportions refer to the total number of isolates tested for each antibiotic.
For uncomplicated UTIs, the proportions of resistance of E. coli to TMP and TMP/SMX were 15.2% and 13.0%, respectively, and for complicated UTIs 26.1% and 23.3%, respectively. The corresponding proportions of resistance in the ARS routine data from urine samples collected in 2015 were 25.3% and 24.4%, respectively (Table 2).
The highest proportions of resistance with regard to the additional information were found among patients with previous antibiotic treatment, including 30.9% resistance to TMP (95% confidence interval: [20.2; 43.3]) and 27.1% to TMP/SMX (95% CI: [17.2; 39.1]). Similarly among patients who experienced at least two UTIs within the last 6 months, 28.9% resistance to TMP (95% CI: [22.7; 35.6]) and 25.0% to TMP/SMX (95% CI: [19.3; 31.4]), respectively, were found.
In the univariable analysis, the proportion of resistance of E. coli to TMP and TMP/SMX was significantly associated with the occurrence of ≥ 2 UTIs within the last 6 months (TMP: Odds Ratio [OR] = 2.09; 95% CI: [1.39; 3.13], pcorr = 0,0035, TMP/SMX: OR = 1.97, 95% CI: [1.3; 2.98], pcorr = 0.013). No statistically significant associations were found for the other factors included in the analysis (eTable 2). The results of the multivariable analysis are listed in eTable 3.
The proportion of resistance of E. coli to TMP stratified by laboratories/regions showed only minor variations for uncomplicated UTIs, while the regional differences were more distinct for complicated UTIs (Table 3). However, none of these differences were statistically significant.
Susceptibility testing of other antibiotics in patients with uncomplicated UTIs revealed lower proportions of resistance for nitrofurantoin (0.6%), fosfomycin (0.6%) and ciprofloxacin (4.5%), as well as high proportions of resistance for amoxicillin/clavulanic acid (27.3%) and ampicillin (29.3%) (eTable 4). From 2013 to 2016, the proportions of resistance to TMP and fosfomycin remained constant in the ARS routine data, while a decreasing trend was noted for the resistance to TMP/SMX and nitrofurantoin (eTable 5).
Requesting of urine cultures
According to the guideline recommendations, a urine culture would have been indicated in 649 (52.1%) of the patients. According to the physicians, a routine urine culture would actually have been ordered for 409 (63.0%) patients. In 251 (42.1%) of the 596 patients in whom a urine culture would not have been necessary according to the guideline recommendations, a urine culture was requested nonetheless (eTable 6). The physicians’ decision for or against requesting a urine culture did not always correlate with the guideline recommendations (phi coefficient φ = 0.21).
In our study, we determined the proportions of resistance of E. coli in patients with community-acquired uncomplicated UTIs in 58 medical practices of community-based internists and general practitioners in various regions of Germany and compared the results with the corresponding data from the ARS system.
To the best of our knowledge, our study is the first to include all patients with the clinical diagnosis of UTI and in which the classification of uncomplicated and complicated UTIs was made at the time of the analysis, based on the additional patient information. This approach ensured that the UTIs were classified accurately according to the predefined criteria. Furthermore, the costs for all microbiological tests ordered as part of the study were covered. In this way, the risk of inclusion bias was largely minimized.
The proportions of resistance of E. coli to TMP and TMP/SMX in uncomplicated UTIs were significantly lower in our study compared to the corresponding values of the Antimicrobial Resistance Surveillance system during the same period. It can therefore be suggested that the selection of an antibiotic for the empiric therapy of an uncomplicated UTI based on ARS routine data is only permissible under certain conditions. One option to make the best use of ARS is to select sentinel practices, regularly providing urine samples of all patients with suspected UTI for microbiological testing, and to classify these patients into the groups “uncomplicated“ and “complicated“ UTIs in order to obtain data of higher quality and with lower risk of bias (25). Alternatively, validation studies could be performed on a regular basis.
The low proportions of resistance of fosfomycin, nitrofurantoin and TMP support the current recommendation in the German clinical practice guideline to use these antibiotics as first-line agents for the empiric therapy of uncomplicated UTIs (6, 20). Even though our study also found low proportions of resistance of TMP/SMX and ciprofloxacin, these drugs should not be used as first-line agents due to their unfavorable adverse effect profile. Because of its broad activity spectrum, ciprofloxacin should be reserved for the treatment of severe infections.
In recent studies from Germany, similar proportions of resistance of 17.5% (TMP) and 15.0% (TMP/SMX), respectively, were found for uncomplicated UTIs. Studies from neighboring countries arrived at similar results: Austria 15.8% (TMP)/14.4% (TMP/SMX), France 17.5% (TMP) (7, 26–28). Since the use of TMP is associated with an increase in TMP resistance, the development of the resistance situation should be monitored, considering that TMP is now again recommended as a first-line agent (29).
The study practices’ proportions of resistance from the previous year (May 2014 until February 2015) did not differ significantly from those in all practices of general practitioners and internists (ARS 2014 and 2015) (Table 2). Thus, selection bias with regard to the participating physicians appears unlikely.
The only factor in the univariable analyses that had a statistically significant association after multiple testing corrections with the proportions of resistance of E. coli to TMP and TMP/SMX was “≥ 2 UTIs in the previous 6 months“. Although the factor “antibiotic treatment in the past 2 weeks” was not found to be significant after multiple testing corrections, the p-value was marginally significant without this correction, thus, we believe it is also an important factor to consider. For the other studied factors even uncorrected p-values were considerably higher than 0.05. In part, this lack of significant associations may be attributed to the small sample sizes in the various categories (for example only 3 pregnant women). In patients with UTI and previous antibiotic treatment or with recurrent UTIs, switching to another antibiotic should primarily be considered in the light of the high proportions of resistance, and microbiological testing may need to be performed. In individual cases, it can be an option to treat the UTI after microbiological testing.
Physicians following the guideline recommendations send urine samples of patients with complicated UTIs for microbiological testing on a routine basis.
However, our study found only a weak association between the guideline recommendations and the decision of physicians to request a urine culture. No urine cultures were requested despite the recommendation to do so, while, on the other hand, microbiological testing was performed without recommendation. Finding differences in the approach to community-based diagnosis and treatment of UTIs compared to the guidelines is not surprising as these have already been demonstrated in various studies (25, 30, 31). This situation is not so much caused by unawareness of the existing recommendations, but it is rather related to attitudes, behavior and external barriers (32, 33).
No information about previous hospital stays was obtained. Thus, the possibility cannot be ruled out that a small proportion of the UTIs were not community-acquired UTIs.
There is potential for selection bias because the group of patients who presented with signs and symptoms of UTI in a practice but who were not enrolled in the study is unknown.
The currently available evidence supports the clinical practice guideline’s recommendation of TMP, fosfomycin and nitrofurantoin for the empiric therapy in community-acquired uncomplicated UTI. Because of high proportions of resistance among patients with recurrent UTIs or after antibiotic treatment within the previous 2 weeks, it is recommended to select the appropriate antibiotic agent in this patient population based on microbiological testing.
Routine UTI resistance data obtained from surveillance systems which mainly include data on complicated UTIs with high proportions of resistance, are of limited use for treatment planning in patients with uncomplicated UTIs without additional clinical information. Validation studies or intensified surveillance by means of sentinel practices are possibilities to improve the data basis.
The decision to request microbiological testing relies only in part on the relevant guideline recommendations.
Conflict of interest statement
The authors declare no conflict of interest.
Manuscript received on 24 November 2017; revised version accepted on 11 April 2018
Translated from the original German by Ralf Thoene, MD.
Abteilung für Infektionsepidemiologie
Nosokomiale Infektionen, Surveillance von
Antibiotikaresistenz und -verbrauch
Seestraße 10, 13353 Berlin, Germany
Charité—Universitätsmedizin Berlin, Germany: Anja Klingeberg
LADR GmbH, Medizinisches Versorgungszentrum Plön, Germany: Dr. med. Annegret Krenz-Weinreich
MVZ Dr. Stein und Kollegen GbR, Mönchengladbach, Germany: Prof. Dr. med. Wiltrud Kalka-Moll
MVZ Labor Dr. Limbach & Kollegen GbR, Heidelberg, Germany: Dr. med. Klaus Oberdorfer
Medizinisches Versorgungszentrum, Labor 28 GmbH, Berlin, Germany: Dr. med. Edith Zill, Dagmar Emerich
Department for Health Services Research, Institute for Public Health and Nursing Science, Bremen, Germany: PD Dr. med. Guido Schmiemann
|1.||Foxman B: The epidemiology of urinary tract infection. Nat Rev Urol 2010; 7: 653–60 CrossRef MEDLINE|
|2.||Naber KG: [New aspects on diagnostics and therapy of uncomplicated cystitis]. Der Urologe 2014, Ausgabe A; 53: 1489–94.|
|3.||Schulz M, Kern W, Hering R, Schulz M, Bätzing-Feigenbaum J: Antibiotikaverordnungen in der ambulanten Versorgung in Deutschland bei bestimmten Infektionserkrankungen in 2009 – Teil 1 und 2. Zentralinstitut für die kassenärztliche Versorgung in Deutschland (Zi). Versorgungsatlas-Bericht Nr. 14/04. Berlin 2014. www.versorgungsatlas.de/themen/versorgungsprozesse/?tab=6&uid=46 (last accessed on 22 January 2018).|
|4.||Dicheva S: Harnwegsinfekte bei Frauen. In: Glaeske G, Schicktanz C: BARMER GEK Arzneimittelreport 2015; 107–37.|
|5.||Stamm WE: An epidemic of urinary tract infections? N Engl J Med 2001; 345: 1055–7 CrossRef MEDLINE|
|6.||Leitlinienprogramm DGU: Interdisziplinäre S3 Leitlinie: Epidemiologie, Diagnostik, Therapie, Prävention und Management unkomplizierter, bakterieller, ambulant erworbener Harnwegsinfektionen bei erwachsenen Patienten. Langversion 1.1–2, 2017 AWMF Registernummer: 043/044. www.awmf.org/uploads/tx_szleitlinien/043–044l_S3_Harnwegsinfektionen (last accessed on 20 June 2017).|
|7.||Schmiemann G, Gagyor I, Hummers-Pradier E, Bleidorn J: Resistance profiles of urinary tract infections in general practice—an observational study. BMC Urol 2012; 12: 33 CrossRef MEDLINE PubMed Central|
|8.||Wagenlehner FME, Wagenlehner C, Savov O, Gualco L, Schito G, Naber KG: Klinik und Epidemiologie der unkomplizierten Zystitis bei Frauen. Urologe 2010; 49: 253–61 CrossRef MEDLINE|
|9.||Stamm WE, Hooton TM: Management of urinary tract infections in adults. N Engl J Med 1993; 329: 1328–34 CrossRef MEDLINE|
|10.||Rothberg MB, Wong JB: All dysuria is local. A cost-effectiveness model for designing site-specific management algorithms. J Gen Intern Med 2004; 19: 433–43 CrossRef MEDLINE PubMed Central|
|11.||RKI: Antibiotika-Resistenz-Surveillance. https://ars.rki.de/ (last accessed on 11 June 2018).|
|12.||Noll I, Schweickert B, Abu Sin M, Feig M, Claus H, Eckmanns T: [Antimicrobial resistance in Germany. Four years of antimicrobial resistance surveillance (ARS)]. Bundesgesundheitsblatt – Gesundheitsforschung – Gesundheitsschutz 2012; 55: 1370–6 CrossRef MEDLINE|
|13.||Wagenlehner FME, Hoyme U, Kaase M, Fünfstück R, Naber KG, Schmiemann G: Clinical practice guideline: uncomplicated urinary tract infections. Dtsch Arztebl int 2011; 108: 415–23 VOLLTEXT|
|14.||McNulty CA, Richards J, Livermore DM, et al.: Clinical relevance of laboratory-reported antibiotic resistance in acute uncomplicated urinary tract infection in primary care. J Antimicrob Chemother 2006; 58: 1000–8 CrossRef MEDLINE|
|15.||Kronenberg A, Koenig S, Droz S, Muhlemann K: Active surveillance of antibiotic resistance prevalence in urinary tract and skin infections in the outpatient setting. Clinical microbiology and infection: the official publication of the European Society of Clinical Microbiology and Infectious Diseases 2011; 17: 1845–51 CrossRef MEDLINE|
|16.||Nicolle LE: Complicated urinary tract infection in adults. Can J Infect Dis 2005; 16: 349–60 CrossRef|
|17.||Stamm WE, Norrby SR: Urinary tract infections: disease panorama and challenges. J Infect Dis 2001; 183, Suppl 1: 1–4 CrossRef MEDLINE|
|18.||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: 745–58 CrossRef MEDLINE|
|19.||Kahlmeter G: An international survey of the antimicrobial susceptibility of pathogens from uncomplicated urinary tract infections: the ECO.SENS Project. J Antimicrob Chemother 2003; 51: 69–76 CrossRef MEDLINE|
|20.||Kranz J, Schmidt S, Lebert C, Schneidewind L, Schmiemann G, Wagenlehner F: Uncomplicated bacterial community-acquired urinary tract infection in adults. Dtsch Arztebl Int 2017; 114: 866–73 VOLLTEXT|
|21.||Schmiemann G, Kniehl E, Gebhardt K, Matejczyk MM, Hummers-Pradier E: The diagnosis of urinary tract infection: a systematic review. Dtsch Arztebl Int 2010; 107: 361–7 VOLLTEXT|
|22.||Stamm WE, Counts GW, Running KR, Fihn S, Turck M, Holmes KK: Diagnosis of coliform infection in acutely dysuric women. N Engl J Med 1982; 307: 463–8 CrossRef MEDLINE|
|23.||R Core Team: A language and environment for statistical computing. R Foundation for Statistical Computing V, Austria 2008. www.R-project.org (last accessed on 20 January 2018).|
|24.||Clopper CJ, Pearson ES: The use of confidence or fiducial limits illustrated in the case of the binomial. Biometrika 1934; 26: 404–13 CrossRef|
|25.||Chin TL, McNulty C, Beck C, MacGowan A: Antimicrobial resistance surveillance in urinary tract infections in primary care. J Antimicrob Chemother 2016; 71: 2723–8 CrossRef MEDLINE|
|26.||Kahlmeter G, Ahman J, Matuschek E: Antimicrobial resistance of escherichia coli causing uncomplicated urinary tract infections: a European update for 2014 and comparison with 2000 and 2008. Infect Dis Ther 2015; 4: 417–23 CrossRef MEDLINE PubMed Central|
|27.||Kamenski G, Wagner G, Zehetmayer S, Fink W, Spiegel W, Hoffmann K: Antibacterial resistances in uncomplicated urinary tract infections in women: ECO.SENS II data from primary health care in Austria. BMC Infect Dis 2012; 12: 222 CrossRef MEDLINE PubMed Central|
|28.||Zwirner M, Bialek R, Roth T, et al.: Local resistance profile of bacterial isolates in uncomplicated urinary tract infections (LORE study). Kongressabstract DGHM 2016.|
|29.||Pouwels KB, Freeman R, Muller-Pebody B, et al.: Association between use of different antibiotics and trimethoprim resistance: going beyond the obvious crude association. J Antimicrob Chemother 2018; 73:1700–7 CrossRef MEDLINE|
|30.||Christoffersen T, Bjerrum L, Nielsen AB: General practitioners do not systematically adhere to regional recommendations on treatment of uncomplicated urinary tract infections. Dan Med J 2014; 61: A4814 MEDLINE|
|31.||Lindback H, Lindback J, Melhus A: Inadequate adherence to Swedish guidelines for uncomplicated lower urinary tract infections among adults in general practice. APMIS 2017; 125: 816–21 CrossRef MEDLINE|
|32.||Lugtenberg M, Burgers JS, Zegers-van Schaick JM, Westert GP: Guidelines on uncomplicated urinary tract infections are difficult to follow: perceived barriers and suggested interventions. BMC Fam Pract 2010; 11: 51 CrossRef MEDLINE PubMed Central|
|33.||Kuehlein T, Goetz K, Laux G, Gutscher A, Szecsenyi J, Joos S: Antibiotics in urinary-tract infections. Sustained change in prescribing habits by practice test and self-reflection: a mixed methods before-after study. BMJ Qual Saf 2011; 20: 522–6 CrossRef MEDLINE|
|e1.||Bundesministerium für Gesundheit. DART- Deutsche Antibiotika-Resistenzstrategie, 2008. www.bundesgesundheitsministerium.de/themen/praevention/antibiotika-resistenzen/antibiotika-resistenzstrategie/ (last accessed on 15 February 2018).|
|e2.||Noll I, Eckmanns T, Abu Sin M: Antibiotikaresistenz: Vergleich mit europäischen Daten. Dtsch Arztebl 2017; 114: A-2209–10 VOLLTEXT|
|e3.||Noll I, Eckmanns T: ARS – Antibiotika-Resistenz-Surveillance in Deutschland. Krankenhhyg up2date 2013; 08: 125–38 CrossRef|
|e4.||Holm S: A simple sequentially rejective multiple test procedure. Scandinavian Journal of Statistics 1979; 6: 65–70.|
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