Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-18T11:05:19.516Z Has data issue: false hasContentIssue false

Metronidazole therapy as initial treatment of Clostridium difficile infection in patients with chronic kidney disease in Korea

Published online by Cambridge University Press:  14 October 2019

Jaeuk Shin
Affiliation:
Division of Gastroenterology, Department of Medicine, Changwon Fatima Hospital, Changwon, Korea
Yu Mi Wi
Affiliation:
Division of Infection, Department of Medicine, Samsung Changwon Hospital, Sungkyunkwan University School of Medicine, Changwon, Korea
Yu-Ji Lee*
Affiliation:
Division of Nephrology, Department of Medicine, Samsung Changwon Hospital, Sungkyunkwan University School of Medicine, Changwon, Korea
*
Author for correspondence: Yu-Ji Lee, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The risk of metronidazole treatment failure in Clostridium difficile infection (CDI) patients with chronic kidney disease (CKD) or end-stage renal disease in Korea has not been established. We evaluated 481 patients who had been admitted to two secondary hospitals with a diagnosis of, and treatment for, CDI during 2010–2016. CDI patients were divided into three groups according to CKD status: non-CKD (n = 363), CKD (n = 55) and those requiring dialysis (n = 63). Logistic regression analyses were performed to examine the association of CKD status with treatment failure. CDI patients receiving dialysis tended to have increased odds of metronidazole and overall treatment failure compared to non-CKD patients; adjusted odds ratios and 95% confidence intervals were 2.09 (1.03–4.21) and 2.18 (1.11–4.32) for metronidazole and overall treatment failure, respectively. However, CKD patients did not have increased odds of metronidazole or overall treatment failure compared to non-CKD patients, even where severe CDI was more prevalent in CKD patients. The incidence of symptomatic ileus or toxic megacolon did not differ among groups. Our results suggest that initial metronidazole therapy may be considered in CDI patients with non-dialysis CKD, but should not be considered in CDI patients undergoing dialysis.

Type
Original Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s) 2019

Introduction

Clostridium difficile infection (CDI) is the most common cause of transmissible nosocomial diarrhoea and is an increasingly frequent cause of morbidity and mortality among hospitalised patients [Reference Bartlett1, Reference George2]. When the normal bacterial flora is disrupted, the colon is colonised with C. difficile bacteria, and released toxins can cause mucosal damage and inflammation [Reference Kelly, Pothoulakis and LaMont3]. CDI is strongly associated with antibiotic use [Reference Magill4], and other risk factors include older age, gastric acid suppression therapy, immunosuppression, prolonged hospitalisation and chronic kidney disease (CKD) [Reference Keddis5Reference Cunney8].

The prevalence of patients with CKD or end-stage renal disease (ESRD) is increasing worldwide. Several studies have demonstrated that patients with CKD or ESRD have approximately two- to three-fold increased risk of CDI compared to those without CKD [Reference Keddis5, Reference Eddi7, Reference Kim9]. Impaired immune function, gastric acid suppression, increased antibiotic use and altered intestinal microbial flora in CKD patients all contribute to the development of CDI [Reference Eddi7, Reference Kim9, Reference McConnell10]. Outcomes of CDI in patients with CKD or ESRD are known to be worse than in those without CKD, and other contributory factors include increased mortality, longer hospital stays and higher costs associated with CDI [Reference Keddis5, Reference Tirath6, Reference Kim9, Reference Thongprayoon11].

The commonly used antibiotics to treat CDI are oral metronidazole or oral vancomycin. Although Infectious Disease Society of America (IDSA) guidelines recently suggested either vancomycin or fidaxomicin for an initial episode of CDI due to a high prevalence of highly virulent strains in the United States, treatment guidance from the European Society of Clinical Microbiology and Infectious Diseases and Australasian Society for Infectious Disease continue to recommend metronidazole as first-line therapy of CDI in mild and moderate disease and vancomycin or fidaxomicin for severe disease, recurrent infection or for those with a high risk of recurrence [Reference Debast, Bauer and Kuijper12, Reference Trubiano13].

As the prevalence of hypervirulent strains is still low in Asia, and metronidazole resistance rates for C. difficile isolates have also been low, metronidazole may be cost-effective for initial therapy among patients with mild to moderate CDI in Asia [Reference Riley and Kimura14, Reference Collins, Hawkey and Riley15]. Oral metronidazole has been mainly used for initial therapy of CDI in CKD and ESRD patients in Korea, but the study for treatment failure in these patients was insufficient [Reference Kim9]. Therefore, we investigated the risk of CDI therapy treatment failure in patients who have non-dialysis CKD or ESRD.

Methods

Study population

This was a retrospective cohort study. Study populations were included in two secondary hospitals in Korea (Samsung Changwon and Changwon Fatima). Patients who were admitted to the hospital with a diagnosis of, and treatment for, an initial episode of CDI were included from June 2010 to November 2016. The diagnosis for CDI was confirmed by a stool toxin assay test or prominent endoscopic findings in patients with symptoms including persistent diarrhoea (± fever or abdominal pain). Estimated glomerular filtration rates (eGFR) were calculated according to the chronic kidney disease epidemiology collaboration equation. CKD was defined as eGFR <60 ml/min/1.73 m2 for more than 3 months. The study was approved by the Institutional Review Board of each hospital and exempt from informed consent.

Data collection

All patient information was collected on age, sex, body mass index (BMI), comorbidities (hypertension and diabetes), use of proton pump inhibitor (PPI) or probiotics, history of previous antibiotics use within 30 days, continuous use of antibiotics during treatment of CDI, fever (body temperature >38.3 °C), shock, variation in white blood cells count (WBC), serum albumin, C-reactive protein (CRP) and serum creatinine. Initial treatment of CDI was discontinuation of other antibiotics and the use of oral metronidazole, oral vancomycin, alone or in combination. The 30-day mortality from the onset of CDI and/or its recurrence within two months from hospital discharge was recorded. The use of concomitant antibiotics was further categorised according to their CDI risk as high (carbapenem, 2nd-, 3rd- or 4th-generation cephalosporin, fluoroquinolone, lincosamide, pivampicillin or temocillin), medium (penicillin, penicillin combination, 1st-generation cephalosporin, macrolide, monobactam or streptogramin) or low (all other systemic antibiotics) and no concomitant antibiotic use [Reference Mullane16]. All patients were classified into three groups according to CKD status: non-CKD, CKD (eGFR <60 ml/min/1.73 m2 for more than three months) and if receiving dialysis or not. Metronidazole treatment failure was defined as addition of, or change to, oral vancomycin for persistent or worsening symptoms such as diarrhoea, fever or increased abdominal discomfort attributed to CDI after three days of initial oral metronidazole therapy [Reference Debast, Bauer and Kuijper12, Reference Trubiano13]. Overall treatment failure was defined as the presence of persistent or worsening symptoms such as diarrhoea, fever or increased abdominal discomfort attributed to CDI after three days of initial CDI treatment, or the addition of further treatment if the physician considered that the current treatment had failed. Acute renal dysfunction was defined as an increase in serum creatinine >50% above baseline and fulminant colitis as the development of hypotension or shock, ileus or toxic megacolon [Reference McDonald17].

Statistical analysis

Continuous variables are presented as mean ± standard deviation (s.d.) or median (interquartile range) as appropriate. Analysis of variance, Kruskal–Wallis test and χ 2 test were used to analyse differences between patient groups as appropriate. Our primary outcome was metronidazole treatment failure and the secondary outcome was overall treatment failure. Logistic regression analysis was used to examine the association of CKD status with treatment failure upon adjustment for age, sex and factors based on a priori knowledge including serum albumin, fever, risk-stratified concomitant antibiotic use, use of glycopeptide, number of antibiotics prescribed (⩾2 or <2), CRP and leukocytosis (WBC > 15 000/μl) [Reference Kim9, Reference Jin, Seo and Wi18, Reference Farne19]. For sensitivity analysis, we additionally adjusted for a history of previous CDI within 8 weeks before diagnosis of current episode, history of using metronidazole to treat other infectious diseases within 4 weeks before diagnosis of CDI and the length of hospital stay from patient admission to diagnosis of CDI, given that these variables may affect the association of CKD status and outcomes. As the continuous use of antibiotics was reported to be a strong predictor of metronidazole treatment failure, we performed subgroup analysis for the primary outcome according to the continuous use of antibiotics and likelihood ratio testing by adding an interaction term between CKD status and the continuous use of antibiotics to the adjusted logistic regression model [Reference Jin, Seo and Wi18]. All analyses were carried out using STATA version 14.2 (StataCorp LP, College Station, TX, USA).

Results

Patient characteristics

A total of 500 patients diagnosed with CDI was identified during the study period. After excluding 19 patients without data on treatment failure, 481 were finally included in this study. The proportion of CDI patients diagnosed with a stool toxin assay, endoscopic findings or both were 412 (85.7%), 23 (4.8%) and 46 (9.6%), respectively. Of them, 363 (75.5%) were diagnosed as non-CKD and 55 (11.5%) as CKD. Sixty-three (13.0%) patients received dialysis therapy. Baseline characteristics among the three groups are shown in Table 1. Patients aged ⩾65 years comprised 67% of the total, and males accounted for 49%. A total of 380 patients were initially treated with oral metronidazole: 282 (78%), 42 (76%) and 56 (89%) in non-CKD, CKD and dialysis patients, respectively. CKD and dialysis patients were more likely to receive PPI therapy and concomitant use of antibiotics compared to patients without CKD.

Table 1. Baseline characteristics of 481 patients with CDI according to CKD status

BMI, body mass index; BT, body temperature; HTN, hypertension; eGFR, estimated glomerular filtration rate; PPI, proton-pump inhibitor; WBC, white blood cells.

a High-risk antibiotics include carbapenem, 2nd-, 3rd- or 4th-generation cephalosporin, fluoroquinolone, lincosamide, pivampicillin or temocillin; medium-risk antibiotics include penicillin, penicillin combination, 1st-generation cephalosporin, macrolide, monobactam or streptogramin; low-risk antibiotics include all other systemic antibiotics.

Metronidazole failure according to CKD status in CDI patients

Of the 380 patients who initially received metronidazole for CDI, the incidence of treatment failure was 20.3%; 18.8%, 16.7% and 30.4% in non-CKD, CKD and ESRD patients, respectively (P = 0.120). Dialysis patients with CDI tended to have increased odds of treatment failure for metronidazole compared to non-CKD patients (adjusted odds ratio (OR) 2.09, 95% confidence interval (CI) 1.03–4.21; P = 0.04). In subgroup analysis according to the concomitant use of antibiotics, there was a difference in association between CKD status and metronidazole failure. In patients not receiving antibiotics, dialysis was associated with an increased odds of metronidazole failure compared to non-CKD status (adjusted OR 2.87, 95% CIs 1.03–8.02; P = 0.044). On the other hand, in patients with the concomitant use of antibiotics, dialysis did not significantly increase the odds of metronidazole failure compared to the non-CKD status (Table 2). In test for interaction, however, it was not statistically significant (P Interaction = 0.53). CKD patients did not have increased odds of metronidazole failure compared to non-CKD patients in overall and subgroup analyses. Likewise, in the sensitivity analysis, further adjusted for history of previous CDI, history of using metronidazole and the length of hospital stay before diagnosis of CDI, the results remained consistent (Table 3).

Table 2. Adjusted odds ratio for metronidazole treatment failure stratified by the continuous use of antibiotics among patients with CDI

CKD, chronic kidney disease; CI, confidence interval; OR, odds ratio.

a OR was adjusted for age, sex, serum albumin, fever, risk-stratified concomitant antibiotic use, use of glycopeptide, number of antibiotics used (⩾2 or <2) and leukocytosis (WBC > 15 000/μl).

Table 3. Sensitivity analysis with further adjustment for treatment failure among patients with CDI

CKD, chronic kidney disease; CI, confidence interval; OR, odds ratio.

a OR was adjusted for age, sex, serum albumin, fever, risk-stratified concomitant antibiotic use, use of glycopeptide, number of antibiotics used (⩾2 or <2), leukocytosis (WBC > 15 000/μl), history of previous CDI within 8 weeks before diagnosis of CDI, history of using metronidazole within 4 weeks before diagnosis of CDI and length of hospital stay from patient admission to diagnosis of CDI.

Overall treatment failure according to CKD status in CDI patients

Of 481 patients with CDI, the overall treatment failure was 16.6%. Compared to non-CKD patients with CDI, dialysis patients with CDI had increased odds of overall treatment failure; fully adjusted OR and 95% CI were 2.18 (1.11–4.32; P = 0.024). However, non-dialysis CKD was not associated with increased odds for overall treatment failure (adjusted OR 0.81, 95% CI 0.34–1.90; P = 0.623).

Other outcomes according to CKD status in CDI patients

The incidence rate of acute renal dysfunction during CDI was higher in the non-dialysis CKD group compared to the non-CKD group (40% vs. 7.7%; P < 0.001). Fulminant colitis also showed an increase according to CKD status; 47 (13.0%), 12 (21.8%) and 15 (23.8%) in non-CKD, non-dialysis CKD and dialysis groups, respectively (P = 0.03). Among 457 patients with follow-up data, there was a significant difference in 30-day mortality according to CKD status with rates of 6.4%, 15.4% and 27.1% in the non-CKD, CKD and dialysis groups, respectively (P < 0.001). The rate of recurrent CDI did not differ among groups; 16.0%, 24.4% and 11.3% in non-CKD, CKD and dialysis groups, respectively (P = 0.204), and likewise for symptomatic ileus or toxic megacolon; 5.0%, 9.1% and 9.5% in non-CKD, CKD and dialysis groups, respectively (P = 0.223).

Discussion

The present study has demonstrated that metronidazole treatment failure for CDI was higher in dialysis patients compared to those without CKD, especially in settings where antibiotics were not used concomitantly. Overall treatment failure for CDI was also significantly higher in dialysis patients compared to those without CKD. However, non-dialysis CKD patients did not have increased odds for treatment failure even when the presence of acute renal dysfunction, suggested as one of the signs of severe colitis, was more prevalent in CKD patients. The 30-day mortality rate incrementally increased according to CKD status (non-CKD, CKD and dialysis) with dialysis patients having the highest mortality. However, recurrent or complicated CDI accompanied by ileus or toxic megacolon did not differ according to CKD status.

Given that the virulent and epidemic ribotype 027 strain of C. difficile is one of the most commonly identified strains in the US and is associated with severity and mortality, a recent IDSA guideline has suggested that either vancomycin or fidaxomicin be used for an initial episode of CDI and metronidazole considered where access to vancomycin or fidaxomicin is limited [Reference McDonald17]. This 027 strain produces a 16-fold higher concentration of toxin A and 23-fold higher concentration of toxin B, as well as the binary (transferase) toxin that leads to increased clostridial adherence to gut tissues [Reference Napolitano and Edmiston20, Reference Cho21]. The associated mortality rate of the 027 strain is considered to be three-fold higher than for less virulent strains, and accounted for 28–50% of CDI in the US [Reference Napolitano and Edmiston20].

Until recently, oral metronidazole has been commonly used for the initial treatment for non-severe CDI in CKD patients, as well more widely in the general Korean population [Reference Kim9, Reference Lee22]. In Korea, the 027 strain is still not common despite its first isolation in 2009 [Reference Tae23] and in 2011 accounted for only seven of 1251 isolates of C. difficile in Korea [Reference Kim24]. Similar results have been reported in Asia, including Japan [Reference Riley and Kimura14, Reference Collins, Hawkey and Riley15]. Furthermore, antimicrobial resistance appears to vary according to the geographical area with reported rates of metronidazole resistance of 15.6% in China from 2012 to 2015, 18.3% in Israel, 5.3% in Iran, 0.11% in Europe and 13.3% in the US (Texas) from 2007 to 2011 [Reference Peng25]. Vancomycin resistance is also variable globally, with rates of 0.87–2.28% of strains exhibiting intermediate resistance to vancomycin in Europe [Reference Freeman26] compared with 17.9% resistance in a US-based national sentinel surveillance study [Reference Snydman27]. In Korea, two recent studies have recorded full susceptibility to metronidazole and vancomycin of all isolates tested [Reference Cho21, Reference Byun28] but in terms of the clinical response to treatment, the rate of metronidazole resistance was found to be 15.2% [Reference Kim9]. Patients with CKD and ESRD may have not only an increased risk of CDI, but also a higher risk of death compared to those without CKD [Reference Eddi7, Reference Eui Oh29]. However, the significance of treatment failures for the most commonly used oral metronidazole among CKD and ESRD patients in Korea remains unclear. In this study, we did not observe increased odds of metronidazole treatment failure among CKD patients compared to non-CKD patients, even if severe CDI was more prevalent in CKD patients. In overall cohort, 20.3% of the patients experienced initial metronidazole treatment failure, but the failure rate in CKD patients was 16.7%, which was not higher than that in control patients. The clinical features of complicated CDI, such as ileus or toxic megacolon in CKD patients, were also not more frequent than in non-CKD patients, and the incidence of recurrent CDI was not significantly different among groups unlike the previous findings [Reference Phatharacharukul30, Reference Thongprayoon31]. Nevertheless, when compared with CDI patients without CKD, initial metronidazole therapy in those undergoing dialysis tended to be associated with an increased risk of treatment failure. As reported by others, concomitant antibiotic use alone in CDI patients was a strong predictor for metronidazole treatment failure [Reference Jin, Seo and Wi18]. Here, even if the association between dialysis and metronidazole failure was more pronounced in CDI patients without the continuous use of antibiotics, a statistically significant interaction effect was not demonstrated in our patient cohort.

Our study has some limitations. First, although we adjusted for potential confounding factors to investigate the association of CKD status with metronidazole treatment failure in CDI patients, confounding factors may have remained due to the observational study design. Moreover, as our study analysed data acquired retrospectively, incomplete or missing data in the medical records might have resulted in measurement bias or misclassification of outcomes. Second, because of the geographical differences in the distribution of epidemiologically dominant strain types and antimicrobial resistance, our findings may be limited to other countries with similar strain prevalence and antimicrobial resistance to Korea. Third, although elevated diagnostic parameters (e.g. WBC > 15 000 cells/μl, serum creatinine ⩾1.5 mg/dl for non-CKD patients or serum creatinine ⩾1.5 times the premorbid level for CKD patients) were used to differentiate CDI severity [Reference McDonald17], there is no consensus regarding a definition of severe CDI, or the most important clinical indicators that should be used to differentiate severity. Further validation of these criteria is therefore warranted and also modified accordingly for patients with CKD or ESRD. Likewise, the role of acute renal dysfunction as a measure of CDI severity remains to be evaluated and validated in international studies [Reference Cimolai32, Reference Shah33]. Lastly, we considered refractory CDI or treatment failure when CDI patients showed worsening symptoms or did not show clinical improvement after 3 days of initial therapy [Reference Debast, Bauer and Kuijper12, Reference Trubiano13]. In retrospect, this timing to determine successful outcomes may have led to the possibility of overestimating the incidence of metronidazole failure.

In conclusion, when dialysis patients were initially treated with oral metronidazole as a CDI treatment, they tended to have higher odds of treatment failure than non-CKD patients but this relationship was not evident for non-CKD patients. Our results suggest that initial metronidazole therapy may be considered in CDI patients with non-dialysis CKD, but should not be considered for CDI patients undergoing dialysis.

Financial support

This research did not receive any specific grant from funding agencies in the public, commercial or not-for-profit sectors.

Conflict of interests

The authors declare no conflicts of interests.

References

1.Bartlett, JG et al. (1978) Antibiotic-associated pseudomembranous colitis due to toxin-producing clostridia. New England Journal of Medicine 298, 531534.Google Scholar
2.George, RH et al. (1978) Identification of Clostridium difficile as a cause of pseudomembranous colitis. British Medical Journal 1, 695.Google Scholar
3.Kelly, CP, Pothoulakis, C and LaMont, JT (1994) Clostridium difficile colitis. New England Journal of Medicine 330, 257262.Google Scholar
4.Magill, SS et al. (2014) Multistate point-prevalence survey of health care-associated infections. New England Journal of Medicine 370, 11981208.Google Scholar
5.Keddis, MT et al. (2012) Clostridium difficile infection in patients with chronic kidney disease. Mayo Clinic Proceedings 87, 10461053.Google Scholar
6.Tirath, A et al. (2017) Clostridium difficile infection in dialysis patients. Journal of investigative Medicine 65, 353357.Google Scholar
7.Eddi, R et al. (2010) Chronic kidney disease as a risk factor for Clostridium difficile infection. Nephrology (Carlton) 15, 471475.Google Scholar
8.Cunney, RJ et al. (1998) Clostridium difficile colitis associated with chronic renal failure. Nephrology, Dialysis and Transplantation 13, 28422846.Google Scholar
9.Kim, SC et al. (2016) Advanced chronic kidney disease: a strong risk factor for Clostridium difficile infection. Korean Journal of Internal Medicine 31, 125133.Google Scholar
10.McConnell, JB et al. (1975) Gastric function in chronic renal failure. Effects of maintenance haemodialysis. Lancet 2, 11211123.Google Scholar
11.Thongprayoon, C et al. (2015) High mortality risk in chronic kidney disease and end stage kidney disease patients with Clostridium difficile infection: a systematic review and meta-analysis. Journal of Nature and Science 1, e85, 113.Google Scholar
12.Debast, SB, Bauer, MP and Kuijper, EJ (2014) European society of clinical microbiology and infectious diseases: update of the treatment guidance document for Clostridium difficile infection. Clinical Microbiology and Infection 20(suppl. 2), 126.Google Scholar
13.Trubiano, JA et al. (2016) Australasian Society of Infectious Diseases updated guidelines for the management of Clostridium difficile infection in adults and children in Australia and New Zealand. Internal Medicine Journal 46, 479493.Google Scholar
14.Riley, TV and Kimura, T (2018) The epidemiology of Clostridium difficile Infection in Japan: a systematic review. Infectious Diseases and Therapy 7, 3970.Google Scholar
15.Collins, DA, Hawkey, PM and Riley, TV (2013) Epidemiology of Clostridium difficile infection in Asia. Antimicrobial Resistance and Infection Control 2, 21.Google Scholar
16.Mullane, KM et al. (2011) Efficacy of fidaxomicin versus vancomycin as therapy for Clostridium difficile infection in individuals taking concomitant antibiotics for other concurrent infections. Clinical Infectious Diseases 53, 440447.Google Scholar
17.McDonald, LC et al. (2018) Clinical practice guidelines for Clostridium difficile infection in adults and children: 2017 update by the Infectious Diseases Society of America (IDSA) and Society for Healthcare Epidemiology of America (SHEA). Clinical Infectious Diseases 66, e1e48.Google Scholar
18.Jin, SJ, Seo, KH and Wi, YM (2018) The effect of concomitant use of systemic antibiotics in patients with Clostridium difficile infection receiving metronidazole therapy. Epidemiology and Infection 146, 558564.Google Scholar
19.Farne, HA et al. (2013) C-reactive protein is a useful predictor of metronidazole treatment failure in mild-to-moderate Clostridium difficile infection. European Journal of Gastroenterology and Hepatology 25, 3336.Google Scholar
20.Napolitano, LM and Edmiston, CE Jr (2017) Clostridium difficile disease: diagnosis, pathogenesis, and treatment update. Surgery 162, 325348.Google Scholar
21.Cho, SH et al. (2017) Characterization of Clostridium difficile strains isolated from patients with C. difficile-associated disease in Korea. Osong Public Health and Research Perspectives 8, 325331.Google Scholar
22.Lee, HC et al. (2016) Clinical outcomes in hospitalized patients with Clostridium difficile infection by age group. Korean Journal of Gastroenterology 67, 8186.Google Scholar
23.Tae, CH et al. (2009) The first case of antibiotic-associated colitis by Clostridium difficile PCR ribotype 027 in Korea. Journal of Korean Medical Science 24, 520524.Google Scholar
24.Kim, H et al. (2011) Emergence of Clostridium difficile ribotype 027 in Korea. Korean Journal of Laboratory Medicine 31, 191196.Google Scholar
25.Peng, Z et al. (2017) Update on antimicrobial resistance in Clostridium difficile: resistance mechanisms and antimicrobial susceptibility testing. Journal of Clinical Microbiology 55, 19982008.Google Scholar
26.Freeman, J et al. (2015) Pan-European longitudinal surveillance of antibiotic resistance among prevalent Clostridium difficile ribotypes. Clinical Microbiology and Infection 21, 248 e249248 e216.Google Scholar
27.Snydman, DR et al. (2015) U.S.-based national sentinel surveillance study for the epidemiology of Clostridium difficile-associated diarrheal isolates and their susceptibility to fidaxomicin. Antimicrobial Agents and Chemotherapy 59, 64376443.Google Scholar
28.Byun, JH et al. (2019) Antimicrobial susceptibility patterns of anaerobic bacterial clinical isolates from 2014 to 2016, including recently named or renamed species. Annals of Laboratory Medicine 39, 190199.Google Scholar
29.Eui Oh, S et al. (2013) Clostridium difficile-associated diarrhea in dialysis patients. Kidney Research and Clinical Practice 32, 2731.Google Scholar
30.Phatharacharukul, P et al. (2015) The risks of incident and recurrent Clostridium difficile-associated diarrhea in chronic kidney disease and end-stage kidney disease patients: a systematic review and meta-analysis. Digestive Diseases and Sciences 60, 29132922.Google Scholar
31.Thongprayoon, C et al. (2015) Chronic kidney disease and end-stage renal disease are risk factors for poor outcomes of Clostridium difficile infection: a systematic review and meta-analysis. International Journal of Clinical Practice 69, 9981006.Google Scholar
32.Cimolai, N (2019) Are Clostridium difficile toxins nephrotoxic? Medical Hypotheses 126, 48.Google Scholar
33.Shah, DN et al. (2013) Defining acute renal dysfunction as a criterion for the severity of Clostridium difficile infection in patients with community-onset vs hospital-onset infection. Journal of Hospital Infection 83, 294299.Google Scholar
Figure 0

Table 1. Baseline characteristics of 481 patients with CDI according to CKD status

Figure 1

Table 2. Adjusted odds ratio for metronidazole treatment failure stratified by the continuous use of antibiotics among patients with CDI

Figure 2

Table 3. Sensitivity analysis with further adjustment for treatment failure among patients with CDI