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Risk factors for quinolone-resistant Escherichia coli infection: a systematic review and meta-analysis

Abstract

Background

Antimicrobial resistance to quinolone is rising worldwide, especially in Escherichia coli causing various infections. Although many studies have been conducted to identify the risk factors for quinolone-resistant Escherichia coli (QREC) infection, the results are inconsistent and have not been systematically reported. The aim of the present study is to conduct a systematic review and meta-analysis to evaluate the potential risk factors for QREC infection.

Methods

A systematic search was performed to collect published data in the EMBASE, PubMed, and the Cochrane Library up to April 2019. Risk factors were analyzed using the pooled odds ratio (ORs) with 95% confidence interval (CIs).

Results

Twenty-seven trials involving 67,019 participants were included in the present study. The following risk factors associated with QREC infection were identified: (1) male (OR = 1.41), (2) hepatic cirrhosis (OR = 2.05), (3) diabetes mellitus (OR = 1.62), (4) cardiovascular disease (OR = 1.76), (5) neurogenic bladder (OR = 8.66), (6) renal dysfunction (OR = 2.47), (7) transplantation (OR = 2.37), (8) urinary tract infection (OR = 2.79) and urinary tract abnormality (OR = 1.85), (9) dementia (OR = 5.83), (10) heart failure (OR = 5.63), (11) neurologic disease (OR = 2.80), (12) immunosuppressive drugs (OR = 2.02), (13) urinary catheter (OR = 4.39), (14) nursing home resident (OR = 4.63), (15) prior surgery (OR = 2.54), (16) quinolones (OR = 7.67), (17) other antibiotics (OR = 2.74), (18) hospitalization (OR = 2.06) and (19) nosocomial infection acquisition (OR = 2.35).

Conclusions

QREC infection was associated with nineteen risk factors including prior quinolones use, hospitalization, and several comorbidities. Reducing exposure to these risk factors and modification of antibiotic use are important to prevent quinolone resistance.

Background

Quinolones, an important class of broad-spectrum antimicrobials against many Gram-negative aerobes, have been widely utilized since the first introduction of ciprofloxacin in 1987 [1]. Formerly, it was suggested that quinolones would be advantageous for minimizing resistance due to the rapid bactericidal activity. As the use of fluoroquinolones has increased, however, the occurrence of quinolone-resistant (QR) strains with decreased susceptibility has been increasingly reported. The QR microorganisms could be recovered from both nosocomial and community-acquired infections [2, 3].

The WHO has proclaimed antimicrobial resistance to be one of the greatest current threats to global health. It is generally accepted that antimicrobial resistance is directly associated with the use of antibiotics [4]. However, there are very few new antibiotic drugs in the pipeline [5], and current antibiotic drugs should be used prudently to decrease antimicrobial resistance rates [6].

Escherichia coli (E. coli) is the most common pathogen in both hospital and community settings, and the species can be divided into five major taxonomic lineages (A, B1, B2, D and E) [7]. The majority of E. coli strains are harmless, and they are even important for healthy people since they reside in the large intestine and provide their hosts with vitamin K complex [8]. Unfortunately, other pathogenic E. coli strains are capable of causing infections that can lead to serious consequences, including and urinary tract infection (UTI) [9] other extraintestinal infections [10]. Recent years, the quinolone-resistant Escherichia coli (QREC) has developed rapidly and spread widely [11]. Take Europe for example, according to the 2009 surveillance report of European Antimicrobial Resistance Surveillance Network (EARS-Net), 30% of all invasive E. coli isolates are resistant to FQ, which limits empirical treatment with these antimicrobials [12].

Knowledge of risk factors associated with QREC infection development is vital to identify high-risk patients in the prevention of QREC acquisition. In addition, such knowledge is also helpful for physicians to make a choice during the empirical therapeutic decision-making process and in the design of effective control measures to prevent infections. A lot of studies have been conducted to determine the risk factors for QREC infection, but the results are not always consistent. For example, Kratochwill et al. found that people with at least 65 years were significantly associated with QREC infection [13], while Pena et al. did not agree with that [14]. Therefore, we performed a systematic review and meta-analysis to investigate the risk factors for QREC infection based on the reported evidence.

Methods

Search strategy

A systematic literature search was conducted to collect the potential data in the electronic databases up to April 2019, including PubMed, EMBASE, and the Cochrane Library. Besides, the reference lists of retrieved reports and relevant systematic reviews were also collected and identified. Both subject terms and free terms were used in the search strategy, including terms related to risk factor assessment (risk/causes, risk factors/assessment, logistic models, multivariate analysis), drug-resistant (quinolone-resistant, fluoroquinolone-resistant), the pathogen (Escherichia coli), and mode of infection (nosocomial, hospital-acquired/associated, healthcare-acquired/associated). Unpublished data or grey literature searches were not performed. No study types were restricted during the search.

Eligibility criteria

Studies were eligible when they met the following entry criteria: (1) about QREC, which was defined as the resistance of Escherichia coli to quinolone, fluoroquinolone, ciprofloxacin, norfloxacin, ofloxacin, fleroxacin, nalidixic acid or other quinolone agents; (2) about QREC infection; (3) studies were about the risk factors for QREC; (4) case-control studies, cohort studies and any other study designs except non-comparative studies, case reports, and case series; (5) studies with raw data of the risk factors; (6) patients with either hospital-acquired healthcare-acquired or community-acquired; (7) sample size > 20. No sex, age or ethnicity of patients were restricted. It should be noted that all the studies that evaluated the risk factors for QREC with control groups were eligible for this meta-analysis. No specific infection condition was restricted. No minimum study duration or follow-up time was required for inclusion. We excluded studies of mixed infections that had Gram-positive infections or any other Gram-negative infections beyond Escherichia coli. Studies published in languages other than English or Chinese were excluded. These eligibility criteria were verified based on the search results.

Data extraction

Two review researchers independently performed the data extraction from included trials according to a previously created form. The extracted data included (1) the first author and years of publication; (2) study design; (3) years when patients were enrolled; (4) the country where the study was implemented; (4) number of cases and control patients; (5) number of male sex and age of cases and control patients; (6) drug resistance pattern and (7) all identified risk factors of QREC infection and other outcomes of interest. The extraction results were evaluated by another author and the disagreement between two researchers was resolved by discussion with another author.

Quality assessment

The Newcastle-Ottawa Quality Assessment Form [15] was used to evaluate the quality of evidence for the included case-control and cohort studies. This standard form consists of three domains, i.e., selection (4 items, 4 points), comparability (1 item, 2 points), and outcome (3 items, 3 points). There are 8 items which scored a total of 9 points. A high-quality study scored 8–9 points, whereas a low-quality study scored less than 6 points. Other studies scored 6–7 points were rated as a moderate grade. Two authors evaluated the quality of each study included in this meta-analysis. Uncertainty or disagreement was resolved by discussion to reach a consensus.

Outcome measures

The present meta-analysis focused on the risk factors for QREC infection. We collected all risk factors when at least two studies reported it. The demographic factors included age, sex (male) and race. The comorbidities included cancer, hepatic cirrhosis, diabetes mellitus, HIV/AIDS (human immunodeficiency virus infection and acquired immune deficiency syndrome), cerebrovascular disease, cardiovascular disease, neurogenic bladder, renal dysfunction, transplantation, urinary tract abnormality, dementia, COPD (chronic obstructive pulmonary diseases), congestive heart failure, autoimmune disease, connective tissue disease, gastrointestinal disease, neurologic disease and hypertension, respiratory disease. Both present treatments and prior treatment included urinary catheter and surgery. Besides, present treatments also included immunosuppressive drugs and nursing home, while prior treatment also included prior quinolones, prior other antibiotics, prior UTI (urinary tract infection) and prior hospitalization. Acquisition of infection source was also analyzed in this meta-analysis. Other parameters of prevalence and prognosis were narratively reviewed.

Statistical analysis

Chi-squared test and the I2 statistics were adopted to evaluate the heterogeneity among the included studies [16, 17]. I2 ≥ 50% or p ≤ 0.1 was considered as a significant heterogeneity and a random-effects model was utilized. Otherwise, a fixed-effects model was used when I2 < 50%. Pooled odds ratios (ORs) and corresponding 95% CIs were calculated for the measurement of the risk factors of QREC infection. The Z-test was utilized to determine the significance of the pooled ORs. Reported probability values were two-sided, with significance set at p ≤ 0.05. Besides, sensitivity analyses were conducted through sequential omission of individual studies in each comparison. If the corresponding p-value of pooled ORs was not substantially different, the results of sensitivity were identified as credible. Potential publication bias was estimated by funnel plots. Symmetrical funnel plots were identified as credible. The present meta-analysis was performed using a Review Manager software, version 5.3 for Windows (Cochrane Collaboration, Oxford, United Kingdom).

Results

Study selection

The literature selection process was performed as shown in the flow diagram of Preferred Reporting Items for Systematic Reviews and Meta-analyses (PRISMA) (Fig. 1). The literature search identified a total of 1186 citations from various electronic databases and the reference lists of retrieved studies and relevant systematic reviews. After removing duplicates using EndNote X7 software, 896 were unique records that were eligible for screening. Then, those potential studies were screened by two authors based on the title/abstract, and 89 were further identified for full-text screening. The disagreements were discussed with a third author to reach a consensus. Finally, 27 studies were included in the present meta-analysis [2, 3, 13, 14, 18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40].

Fig. 1
figure 1

PRISMA flow chart of study selection in the meta-analysis

Study characteristics

The characteristics of the included studies were shown in Table 1. Of the studies included for qualitative synthesis, all were case-control studies [2, 3, 14, 18,19,20,21,22,23,24,25,26,27, 31, 32, 36, 40] and cohort studies [13, 28,29,30, 33,34,35, 37,38,39] in design published between 1995 and 2017. Three were conducted in Spain [2, 14, 32], five in South Korea [18, 20, 30, 36, 37], two in France [19, 35], nine in the USA [13, 21,22,23, 25, 27, 33, 34, 39], two in the Netherlands [31, 40], one each in Finland [3], Israel [24], China [26], the UK [28], Turkey [29], and Pakistan [38]. A total of 67,019 participants (2526 cases and 64,493 controls) were enrolled in this meta-analysis. The sample sizes in included studies ranged from 49 [23] to 59,469 [39]. Most studies focused on the E. coli resistance patterns for ciprofloxacin or levofloxacin-resistant strains. Outcomes of interest included the demographic data and all risk factors, including comorbidities or underlying diseases among the study populations, present and prior treatments, infection source and so on. Besides risk factors of QREC infection, some studies also reported the prevalence [3, 29, 30, 32, 33] and prognosis due to QREC [18].

Table 1 Characteristics of the eligible studies

Study quality

For the 27 observational studies evaluated by Newcastle-Ottawa Quality Assessment Form, four studies scored 8 points [2, 21, 25, 39], which could be regarded as at high-quality. While three study only scored 5 points [29, 30, 33], and could be regarded as at low-quality. The remaining 20 studies scored 6–7 points and could be regarded as at moderate-quality. Therefore, most studies were of moderate-to-high quality. They generally lost points because of a statement of the outcome of interest at the beginning and non-complete follow up.

Risk factors for QREC infection

Table 2 shows the pooled results of risk factors for QREC infection and heterogeneity in the meta-analysis. For the demographic parameters, the results showed that gender (male) [OR (95% CI) = 1.41 (1.21 to 1.64), p <  0.001] is the primary risk factor. However, our evidence did not support that the remaining demographic factors were risk factors for QREC infection. For the comorbidities, the pooled results showed demonstrated that some comorbidities might increase the risk for QREC infection, including hepatic cirrhosis [OR (95% CI) = 2.05 (0.99 to 4.24), p <  0.05], diabetes mellitus [OR (95% CI) = 1.62 (1.43 to 1.83), p <  0.001], cardiovascular disease [OR (95% CI) = 1.76 (1.02 to 3.04), p = 0.04], neurogenic bladder [OR (95% CI) = 8.66 (5.68 to 13.19), p <  0.001], renal dysfunction [OR (95% CI) = 2.47 (1.44 to 4.23), p = 0.001], transplantation [OR (95% CI) = 2.37 (1.17 to 4.79), p = 0.02], urinary tract abnormality [OR (95% CI) = 1.85 (1.37 to 2.49), p <  0.001], dementia [OR (95% CI) = 5.83 (2.33 to 14.60), p <  0.001], congestive heart failure [OR (95% CI) = 5.63 (1.27 to 25.10), p = 0.02], neurologic disease [OR (95% CI) = 2.80 (1.71 to 4.57), p <  0.001]. For the treatments, the significant risk factors included immunosuppressive drugs [OR (95% CI) = 2.02 (1.43 to 2.85), p <  0.001], urinary catheter [OR (95% CI) = 4.39 (2.81 to 6.85), p <  0.001] and nursing home resident [OR (95% CI) = 4.63 (1.62 to 13.26), p = 0.004]. Besides, a lot of prior treatments could also be regarded as the risk factors, including prior surgery [OR (95% CI) = 2.54 (1.28 to 5.04), p = 0.008], quinolones [OR (95% CI) = 7.67 (4.79 to 12.26), p <  0.001], other antibiotics [OR (95% CI) = 2.74 (1.92 to 3.92), p <  0.001], UTI [OR (95% CI) = 2.79 (2.32 to 3.36), p <  0.001] and hospitalization [OR (95% CI) = 2.06 (1.62 to 2.60), p <  0.001]. Furthermore, nosocomial acquisition of infection was also a significant risk factor for QREC [OR (95% CI) = 2.35 (1.47 to 3.75), p <  0.001]. No significant difference of infection source was found between case group and control group (all p > 0.05), suggesting that various infection sources were not the risk factors. Figure 2 illustrates the forest plot describing the relationship between quinolones exposure and QREC infection.

Table 2 Pooled risk factors for QREC infections
Fig. 2
figure 2

Forest plots for the association between exposure to quinolone and QREC infection. QREC, quinolone-resistant Escherichia coli; M-H, Mantel-Haenszel; CI, confidence interval

Sensitivity analyses

Sensitivity analyses were used to find out the obvious study which could change the pooled results through the result of itself. Thus, we conducted sensitivity analyses among the comparisons of the results of pooled ORs for the random-effects and fixed-effects models by the sequential and one-by-one omission of individual studies. Our sensitivity analyses revealed that the corresponding results were not significantly different in most comparisons of the risk factors, suggesting that our meta-analyses were stable. Besides, we even found that the heterogeneity was reduced in some conditions during the sensitivity analyses. However, some studies did change the pooled results. Specifically, when we removed the studies of Han et al., [34] the heterogeneities for cancer and cardiovascular disease were distinctly reduced evidently by I2 decreased from 75 to 40% and from 69 to 46%, respectively. After using a fixed-effects model, the ORs and the corresponding 95% CIs for cancer changed from 1.66 (0.96, 2.85) to 2.07 (1.57, 2.75) and from 1.76 (1.02, 3.04) to 2.28 (1.66, 3.12). respectively. Similarly, when we removed the study of Pena et al., [14] the ORs (95% CIs) for hepatic cirrhosis and urinary tract infection changed from 2.05 (0.99, 4.24) to 2.96 (1.22, 7.15) and from 0.78 (0.28, 2.19] to 0.48 (0.31, 0.74), respectively. These corresponding results changed and became statistically significant.

Publication bias

The publication bias among the included studies was evaluated using funnel plots. No obvious asymmetry was identified in funnel plots of most outcomes, suggesting that there was no significant publication bias. However, the publication bias of immunosuppressive drugs use should not be ignored. As shown in Fig. 3, the funnel plot was quite asymmetrical.

Fig. 3
figure 3

Funnel plot of comparison for immunosuppressive drugs uses as the potential risk factor. Each small circle represents an independent study for the indicated association. The funnel plot appears asymmetric. OR, odds ratio; SE, standard error

Discussion

In the current systematic review and meta-analysis, we aimed to evaluate the risk factors for QREC infection by summarizing the published data of relevant articles so far. Since it was first evaluated in Japan in 1988 [41], QREC has become one of the most frequent QR bacterial strains, which has also been endemic in other areas worldwide, including East Asia [26], South Asia [38], Europe [19, 35], and North America, especially the USA [21,22,23, 25, 27, 33, 34, 39]. The direct consequence of QREC dissemination is that infections with such strains are difficult to eradicate and the treatment options are limited. Thus, from the perspective of preventive medicine, determining the possibility of QREC infection in the early stage by studying risk factors and taking reasonable prevention could be helpful to reduce the incidence. Although some studies [2, 14, 18] on the risk factors of QREC infection are previously available, their results are controversial because of the different selection criteria, sample sizes or study designs. Accordingly, we performed the present meta-analysis, which to our knowledge, is the first meta-analysis in this field, to identify the potential risk factors for QREC infection.

After a comprehensive search, 27 case-control or cohort studies with 67,019 participants with infections were collected in our meta-analysis. Based on the outcomes reported in these included studies, we pooled the data of each risk factor according to the classification. Our meta-analysis identified that the risk factors for acquisition of QREC infection varied about demographic factors, comorbidities, present and prior treatments as well as acquisition routes. Infection sources, including urinary tract, intra-abdominal and respiratory tract infection were not identified as the significant risk factors.

Specifically, our meta-analysis did not suggest the old people (> 65 years) as the risk factor. But heterogeneity could not be ignored. The sensitivity analysis demonstrated that when the study of Pena et al. [14] was omitted, the old people (> 65 years) were more susceptible to QREC infection. Besides, since some original studies compared the age using continuous data with mean ± standard deviation, we conducted another comparison using the pooled mean difference (MD) with 95% CI. As was shown in Additional file 1: Figure S1, the meta-analysis found that age was a significant risk factor for QREC infection [MD (95% CI) = 5.21 (0.39 to 10.03), p = 0.03].

Over twenty comorbidities or underlying diseases were reported in the original studies. Our findings suggest that some comorbidities were significantly associated with the acquisition of QREC infection compared with E. coli. These noteworthy comorbidities included hepatic cirrhosis, diabetes mellitus, cardiovascular disease, neurogenic bladder, renal dysfunction, transplantation, urinary tract abnormality, dementia, congestive heart failure, neurologic disease.

Some treatments may also closely relate to the production of QREC infection. Among them, immunosuppressive drugs use, urinary catheter use, hospitalization stay and prior quinolones, other antibiotics use were identified as significant risk factors. Therefore, no matter exposure to quinolones or other antibiotics, the risk of acquisition QREC infection is increased. On the other hand, it is also worth mentioning that QREC isolates may also be resistant to other antimicrobial agents. For example, Lin and the colleagues found that 98.4% ciprofloxacin-resistant E. coli strains were concurrently resistant to at least one of eight antimicrobial classes other than ciprofloxacin, including monobactams, carbapenems, penicillins, cephalosporins, aminoglycosides, minocycline, TMP/SMX, and chloramphenicol [26]. Therefore, It is necessary to use antibiotics carefully and appropriately. Clinicians in different countries should be aware of local antimicrobial resistance data and prescribe or adjust antibiotics according to susceptibility testing results.

In addition, some original studies also compared the outcomes between cases and controls [18, 20]. Generally, the prognosis is poorer among case patients compared with control patients. Take mortality for example, patients infected with QREC have a higher overall rate of mortality than the control patients (25.51 vs 12.67%). Pooling data from four original studies according to the mortality gave odds ratio of 2.43 (1.59 to 3.72) with p <  0.001 for patients infected with QREC vs. control patients (Additional file 2: Figure S2).

There are several strengths in this systematic review and meta-analysis. First, the full text of meta-analysis was designed and reported closely followed the standard PRISMA guidelines, which were comprehensible and concise for other peer researchers in this field. And to our knowledge, this study is the first comprehensive meta-analysis to date focusing on the risk factors for QREC infections. Second, considering there are numerous potential risk factors, we summarized each of them once two or more studies contained. The comprehensive reports of comparisons contribute to finding the shortages in these included studies. Last but not least, 27 studies with 67,019 participants were included in this meta-analysis. The huge sample sizes are conducive to guarantee statistical power and reliability of the results of this meta-analysis.

As with many systematic reviews and meta-analyses, our study has some limitations, which may affect the results. First, as most of the included studies only reported unadjusted data on risk factors, we analyzed only crude risk factors among participants with QREC in the section of results. Second, the present study only retrieved published studies from three database and the relevant studies from the reference lists. Other potential articles published in other databases and unpublished studies might have been missed. Third, the significant heterogeneity (I2 ≥ 50% or p ≤ 0.1) was identified in some variables across these eligible original trials. The heterogeneity may be derived from the different study design (cohort studies and case-control studies) or antimicrobial susceptibility testing cannot be ignored in some comparisons.

Conclusions

In conclusion, the present meta-analysis has identified a number of factors associated with QREC infection development. Therefore, these results have some implication for the medical institutions and the centers for disease control that attention should be paid to patients with QREC infection. Further studies are required in order to better stratify and control quinolone resistance risk in patients with E. coli infections.

Availability of data and materials

Data supporting the conclusions of this article are available from the corresponding author on reasonable request.

Abbreviations

CI:

Confidence Interval

COPD:

Chronic Obstructive Pulmonary Diseases

E. coli :

Escherichia coli

EARS-Net:

European Antimicrobial Resistance Surveillance Network

HIV/AIDS:

Human Immunodeficiency Virus infection and Acquired Immune Deficiency Syndrome

MD:

Mean Difference

OR:

Odds Ratios

PRISMA:

Preferred Reporting Items for Systematic Reviews and Meta-analyses

QR:

Quinolone Resistant

QREC:

Quinolone-Resistant Escherichia coli

TMP/ SMX:

Trimethoprim/Sulfamethoxazole

UTI:

Urinary Tract Infection

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Acknowledgements

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Funding

Funding for this review was provided by Chongqing Health Center for Women and Children, Chongqing, China.

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DZ contributed to study design, data extraction, quality assessment, analysis and interpretation of data, and drafting the manuscript. QL contributed to study design, data extraction, quality assessment, analysis and interpretation of data, and drafting the manuscript. YS contributed to study design, quality assessment and analysis, interpretation of data and revising the article. QZ contributed to conceiving the study, participating in study design and revising the article. All authors proofed and approved the submitted version of the article.

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Correspondence to Qin Zhang.

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Supplementary information

Additional file 1: Figure S1.

Forest plots of pooled age as the potential risk factor for QREC infection. QREC, quinolone-resistant Escherichia coli; I-V, Inverse-Variance; CI, confidence interval.

Additional file 2: Figure S2.

Forest plots of pooled mortality in participants infected with Escherichia coli. I-V, Inverse-Variance; CI, confidence interval.

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Zhu, DM., Li, QH., Shen, Y. et al. Risk factors for quinolone-resistant Escherichia coli infection: a systematic review and meta-analysis. Antimicrob Resist Infect Control 9, 11 (2020). https://0-doi-org.brum.beds.ac.uk/10.1186/s13756-019-0675-3

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