Review of the literature and individual patients’ data meta-analysis on efficacy and tolerance of nitroxoline in the treatment of uncomplicated urinary tract infections

Urinary tract infections (UTI) are very frequently found in humans. The most frequent pathogens are Escherichia coli and other species of Enterobacteriaceae. Gram-positive bacteria, such as staphylococci and enterococci, and non-fermenting Gram-negative bacteria, such as Pseudomonas aeruginosa, can also be found [1]–[4]. Funguria due to Candida spp. is mainly cultured in patients with risk factors, e.g. immunocompromised or with infections due to foreign bodies [5],[6]. The worldwide increasing bacterial resistance has become a general therapeutic problem. In many countries the resistance rates of E. coli against trimethoprim and cotrimoxazole, have exceeded the 20% threshold accepted for empiric therapy by far [1],[3],[7]–[9]. Although in many countries still below 20%, the resistance rates of E. coli against fluoroquinolones are also increasing worldwide. Therefore, cotrimoxazole, trimethoprim, fluoroquinolones, the former standard therapeutics for uncomplicated UTI [10], but also amoxicillin with and without clavulanic acid and oral cephalosporins are no more recommended in many of the current guidelines as first line antibiotics for the treatment of uncomplicated UTI (cystitis) [11]–[13]. Older oral antibiotics, such as fosfomycin trometamol, pivmecillinam, and nitrofurantoin, which have still preserved their antibacterial activity against E. coli and other uropathogens, are now mostly recommended as first line antibiotics for this indication [11]–[13]. But further alternatives should be looked for.

Nitroxoline, 5-nitro-8-hydroxyquinoline, has been described first in the fifties of the last century [14]. Since the sixties it has been used for treatment and prophylaxis of acute and recurrent UTI [15],[16] in adults and children in the European countries. Nitroxoline is active against most Gram-negative and –positive uropathogenic bacteria [17]–[19], against mycoplasmas (M. hominis, Ureaplasma urealyticum) [20],[21] and human pathogenic Candida spp [22],[23]. The antibacterial activity against Acinetobacter spp., Enterococcus spp., and Serratia spp. is variable and Pseudomonas spp. are considered resistant [17],[19]. Oral treatment with nitroxoline has no qualitative and quantitative effect on the fecal flora [24].

The rate of susceptibility of E. coli, the leading uropathogen, at a MIC of nitroxoline of ≤8 mg/l is practically 100% and has not changed over the years as shown by a recent in vitro study with 499 strains from patients with community acquired UTI showing MIC₅₀- and MIC₉₀-values of 2 mg/l and 4 mg/l, respectively. The unimodal MIC distribution indicates that these pathogens are wild types without any acquired resistance [25]. For other uropathogens, such as K. pneumonia, P. mirabilis. P. vulgaris, M. morganii, and S. saprophyticus the MIC₅₀- and MIC₉₀-values were between 4–8/4–8 mg/l with highest MIC of 8 mg/l [26]. The MIC₉₀ for various Candida spp., such as Candida albicans, Candida tropicalis, Candida parapsilosis, Candida krusei, Torulopsis (Candida) glabrata, is between 1 and 4 mg/l nitroxoline [27], which correlate well with other studies [28].

The mode of antibacterial and antifungal action is based on the ability of nitroxoline to chelate with various metallic bivalent cations [29]–[31]. The antibacterial actvity of nitroxoline is decreased by the presence of Mn⁺⁺ and Mg⁺⁺, but not Ca⁺⁺ and univalent ions like Na⁺ and K⁺. The authors assume that magnesium ions stabilizing the lipopolysaccharide (LPS) molecules in the outer bacterial membrane favour the accumulation of nitroxoline in the bacteria, such as E. coli. This process is energy independent. Nitroxoline is binding to bacterial surface structures, which probably leads to an interaction between nitroxoline and magnesium ions complexing with LPS phosphate groups [30],[31]. The bacterial surface becomes hydrophobic as demonstrated for E. coli at 1/8 of MIC of nitroxoline and the adherence to catheter surface is decreased [32]. Nitroxoline inhibits rapidly and selectively RNA synthesis in fission yeast by chelation of bivalent cations required for RNA synthesis [33]. Furthermore, subinhibitory concentrations of nitroxoline have a major inhibitory effect on adhesin expression and bacterial attachment [34]–[36], which may add an important antibacterial mechanism of nitroxoline. Nitroxoline also reduces the formation and induces the dispersal of Pseudomonas aeruginosa biofilms by chelation of iron and zinc [37].

After single oral administration of 200 mg nitroxoline antibacterial urinary activity can be demonstrated by microbiological assays peaking on average between 216 mg/l and 220 mg/l during the urine collection periods 1–2 hours and 3–4 hours [38]. The HPLC concentrations of free nitroxoline, however, were much lower peaking on average between 3.2 mg/l and 5.8 mg/l during that periods. The discrepancy between the two assays was explained by antibacterial active metabolites in urine, because nitroxoline is excreted in the urine in unconjugated as well as conjugated (glucuronide, sulfate etc.) forms [38],[39]. A recent study showed that after oral administration of 250 mg about 99% of the excreted nitroxoline was eliminated as metabolites in urine of volunteers, mainly as sulfate and glucuronide, and only 1.0% as the parent component [40],[41]. In this study urinary inhibitory and bactericidal concentrations were determined against selected uropathogens, such as E. coli, K. pneumonia, P. mirabilis, and S. saprophyticus. In connection with additional urinary bactericidal kinetic studies it was concluded, that nitroxoline exhibits mainly bacteriostatic activity in urine against susceptible strains. Its antibacterial activity is more pronounced in acidic than in alkaline urine.

The aim of this article is to review systematically the available literature on the use of nitroxoline for treatment and prevention of UTI and to meta-analyse four prospective, randomized, single-blind, multicenter, comparative studies, so far unpublished, in order to improve the evidence based recommendation to use nitroxoline as one of the first line drugs for the treatment of uncomplicated UTI (cystitis).

When nitroxoline was first marketed in the European Union in 1962 for treatment and prophylaxis of UTI, microbiological and observational studies were considered sufficient. For this reason between 1962 and 1987 only uncontrolled studies were published not only for treatment and prophylaxis of uncomplicated, but also for treatment of complicated UTI including pyelonephritis, prostatitis and fungal infections in adults of both genders, and also in children. Only two prospective randomized studies, one for treatment of uncomplicated UTI in adults and one for prophylaxis of UTI in children, were published, both with low number of patients [67],[68]. Although these studies may not be considered highly evidential, they can at least contribute to establish the safety of nitroxoline in adults as well as in children together with the large postmarketing observational study.

When the requirements became more stringent for the renewal of the regulatory approval, finally achieved in Germany in 2005, four prospective randomized single blind studies were performed during 1992 and 1993 with cotrimoxazole and norfloxacin as controls. All four studies followed in essence the same protocol with the only difference that the treatment duration in women with sporadic uncomplicated UTI was five days and in women with acute episode of recurrent UTI was ten days. All four studies were of high quality achieving four out of maximum five Jadad scores [73],[74]. The bacterial spectra were similar between the studies with E. coli as most frequent pathogen ranging from 65% to 73%. There was no evidence that females suffering from recurrent UTI showed more resistant strains than those with sporadic UTI. During the years 1992–1993, when the studies were performed, the resistance rates for cotrimoxazole and norfloxacin were still very low. Both antibiotics were considered first line drugs for the treatment of uncomplicated UTI at that time [10]. For all these reasons, including the data of all four studies in one meta-analysis was justified.

Since the clinical report forms (CRF) of the individual patients were available, an IPD meta-analysis could be performed, a specific type of systematic review [75]. Rather than extracting summary (aggregate) data from study publications, the original research data are sought directly for each study. These data can then be re-analysed centrally and combined, if appropriate, in meta-analyses. IPD meta-analyses can improve the quality of data and their analysis and thus produce more reliable results [76]. For this reason they are considered a ‘gold standard’ of systematic review in contrast to meta-analyses of aggregate data, which relates to information averaged or estimated across all individuals in a study. In a two step approach the individual participant data are first analysed in each separate study independently and then synthesized using a suitable model for meta-analysis of aggregate data. With individual participant data an analytic standardisation across the studies and a direct derivation of the information requested is possible, independent of significance or how it was reported.

Since at that time the microbiological evaluation was the primary aim practically in all UTI studies, a single-blind design was considered sufficient, because the eradication (primary aim) could be determined in an objective manner. Nevertheless, from todays point of view the single-blind design could be considered as a weakness of the studies, which may have affected mainly the clinical outcome and some subjective adverse events. However, the non-inferiority of nitroxoline for the eradication of bacteriuria as compared to the controls, cotrimoxazole and norfloxacin, is fairly well established by this IPD meta-analysis, whereas the individual studies contributed each between about 20 and 30% to the final results. Another shortcoming of the study may be, that after the test of cure the patients were not followed for a longer time. Therefore no information is available concerning the relapse rate after the test of cure visit.

Since the final microbiological evaluation in UTI studies is usually not performed at the end of treatment, but rather after the antibiotic substances are completely eliminated from the urinary tract and uropathogens, still present, have had time to multiply to significant numbers, the usual ITT and PP analyses may benefit good results, when patients drop out with favourable results after the end of treatment visit. These patients are considered a microbiological cure in the ITT set (last observation brought forward) and are drop outs for the classical PP analysis. Thus, possible treatment failures will be not recorded, because usually the reasons for dropping out after the treatment visit remains unknown. Therefore, a modified PP set was evaluated, in which all patients dropping out before test of cure were considered treatment failure (worst case scenario). Only if the same results can be achieved in all three evaluation sets, the overall result (non-inferiority) can be taken as proven, which was established by this IPD meta-analysis for nitroxoline as compared to the controls.

The current guidelines do usually not recommend a longer treatment duration of an acute episode in women with recurrent UTI than in those with sporadic UTI any more. For cotrimoxazole and fluoroquinolones even a 3-day therapy is considered sufficient in acute uncomplicated cystitis, but for the usage of macrocrystal nitrofurantoin also a 5-day therapy is recommended in the current guidelines [11]–[13]. Therefore a 5-day therapy of nitroxoline 250 mg tid should also be recommended as one of the first line options for the treatment of acute uncomplicated UTI (cystitis). Since about half of the female patients were pre- and postmenopausal in the studies meta-analysed, the dosage regimen and duration for both female groups can be considered the same, because in current guidelines an acute cystitis in otherwise healthy postmenopausal women is also considered as uncomplicated [12].

Nitroxoline used for more than 50 years for the treatment and prophylaxis of adult patients and children suffering from UTI has shown good clinical efficacy and safety as published in 26 uncontrolled, in two earlier controlled and in one large postmarketing observational study including a total of more than 11,000 patients. This first IPD meta-analysis of four so far unpublished, prospective, randomized, comparative clinical studies with a total of 466 female patients with sporadic or recurrent uncomplicated UTI has demonstrated non-inferiority (10% non-inferiority margin) between treatment with nitroxoline versus controls (cotrimoxazole, norfloxacin). With a 5-day (sporadic UTI) and 10-day (recurrent UTI) treatment with nitroxoline 250 mg t.i.d. eradication of bacteriuria could be achieved in over 90% of the patients. The safety of nitroxoline was comparable with that of the controls. Adverse events, mainly gastrointestinal disorders and only a few allergic reactions, were reported only in 9.4% patients treated with nitroxoline and 7.8% with the control drugs. Combining the vast clinical experience obtained from studies published earlier and non-inferiority of bacteriological efficacy with nitroxoline versus the controls as documented by this high quality IPD meta-analysis and considering the world wide increase of resistance of uropathogens against cotrimoxazole and fluoroquinolones, which has not been seen with nitroxoline despite clinical usage for more than 20 years, nitroxoline should be reconsidered as one of the first line antibiotics for the treatment of uncomplicated UTI.

1. Assoc. Professor of Urology of the Technical University Munich, Munich; priv. address: Karl-Bickleder-Str. 44c, 94315 Straubing, Germany, e-mail: kurt@nabers.de; 2. Statistical Consulting & Data Analysis, Schlehendornweg 24, 07751 Jena, Germany, e-mail: niggemann@p-wert.de; 3. Rosen Pharma, Kirkeler Str.41, 66440 Blieskastel-Niederwürzbach, Germany, e-mail: gisela.stein@rosen-pharma.de; 4. Em. Professor of Internal Medicine of the University of Jena; priv. address: Von-Hase-Weg 22, 07743 Jena, Germany, e-mail: guenter.stein@med.uni-jena.de