Hostname: page-component-cd9895bd7-gbm5v Total loading time: 0 Render date: 2024-12-22T16:33:42.707Z Has data issue: false hasContentIssue false

Clinical risk factors, bacterial aetiology, and outcome of urinary tract infection in children hospitalized with diarrhoea in Bangladesh

Published online by Cambridge University Press:  28 December 2016

R. DAS
Affiliation:
Nutrition and Clinical Services Division (NCSD), International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b), Mohakhali, Dhaka, Bangladesh
T. AHMED
Affiliation:
Nutrition and Clinical Services Division (NCSD), International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b), Mohakhali, Dhaka, Bangladesh
H. SAHA
Affiliation:
Nutrition and Clinical Services Division (NCSD), International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b), Mohakhali, Dhaka, Bangladesh
L. SHAHRIN
Affiliation:
Nutrition and Clinical Services Division (NCSD), International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b), Mohakhali, Dhaka, Bangladesh
F. AFROZE
Affiliation:
Nutrition and Clinical Services Division (NCSD), International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b), Mohakhali, Dhaka, Bangladesh
A. S. M. S. B. SHAHID
Affiliation:
Nutrition and Clinical Services Division (NCSD), International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b), Mohakhali, Dhaka, Bangladesh
K. M. SHAHUNJA
Affiliation:
Nutrition and Clinical Services Division (NCSD), International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b), Mohakhali, Dhaka, Bangladesh
P. K. BARDHAN
Affiliation:
Nutrition and Clinical Services Division (NCSD), International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b), Mohakhali, Dhaka, Bangladesh
M. J. CHISTI*
Affiliation:
Nutrition and Clinical Services Division (NCSD), International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b), Mohakhali, Dhaka, Bangladesh
*
*Author for correspondence: Dr M. J. Chisti, MBBS, MMed, PhD, Scientist & Head, Clinical Research, Hospitals NCSD & Clinical Lead, Intensive Care Unit & Consultant Physician, Respiratory Ward, Dhaka Hospital, icddr,b, 68 Shaheed Tajuddin Ahmed Sarani, Mohakhali, Dhaka 1212, Bangladesh. (Email: [email protected])
Rights & Permissions [Opens in a new window]

Summary

Urinary tract infection (UTI) is common in children aged <5 years with diarrhoea, but little is known about risk factors, aetiology and outcome of such children. We aimed to evaluate these knowledge gaps of UTI in children aged <5 years with diarrhoea. We enrolled all children aged <5 years with diarrhoea admitted to Dhaka Hospital of the International Centre for Diarrhoeal Disease Research, Bangladesh, between May 2011 and April 2013, who had history of fever (⩾38 °C) and obtained a urine sample for culture. Diarrhoea with UTI (confirmed by culture) constituted cases (n = 26) and those without UTI constituted controls (n = 78). Threefold controls were randomly selected. The case-fatality rate was comparable in cases and controls (4% vs. 1%, P = 0·439). Escherichia coli (69%) and Klebsiella (15%) were the most commonly isolated pathogens. Persistent diarrhoea, pneumonia and prior antibiotics use were identified as risk factors for UTI in logistic regression analysis (P < 0·05 for all). Thus, children with diarrhoea presenting with persistent diarrhoea, pneumonia, and prior antibiotic use should be investigated for UTI for their prompt management that may reduce morbidity.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2016 

INTRODUCTION

Urinary tract infection (UTI) is one of the most common serious bacterial illnesses in children, especially in infants and young children [Reference Tseng1] and is often associated with high morbidity and mortality [Reference Salmani2]. The reported incidence of UTI is 7% in girls and 2% in boys during the first 6 years of life [Reference Craig3]. Studies conducted in the UK [Reference Stansfeld4], Sweden [Reference Mårild and Jodal5], Finland [Reference Uhari and Nuutinen6], and The Netherlands [Reference Kwok7] reported incidence rates ranging from 0·17 to 18/1000 person-years for boys and from 0·4 to 66/1000 person-years for girls. Due to overt clinical features, diagnosis of UTI is often delayed, which increases the risk of renal damage-related morbidity [Reference Neumann and Pryles8]. Although non-specific symptoms including vomiting, poor feeding, and diarrhoea have been postulated as signs of UTI in young children, this association has not been verified [Reference Shaw9]. In recent studies conducted in Kingdom of Saudi Arabia and Western Iran, Escherichia coli (44·5%), Klebsiella spp. (18·6%), Enterobacter spp. (15%) and Staphylococcus spp. (12·7%) have been identified as the most common pathogens for UTI [Reference Garout10, Reference Yasemi11]. Of these pathogens E. coli is the most common responsible for UTI [Reference Pitout12]. Studies from Ethiopia and Colombia suggest that antibiotic resistance of urinary tract pathogens is known to increase worldwide, especially to commonly used antimicrobials [Reference Alemu13, Reference Velez14]. The increasing antibiotic resistance trends are likely to have important clinical implications for the empirical use of antibiotics [Reference Farajnia15]. Most recent studies, particularly in developing countries like Jordan and Iran, on the antimicrobial susceptibility of bacterial pathogens causing UTI in children have shown high levels of antibiotic resistance in clinical settings [Reference Al-Mardeni16, Reference Al-Mendalawi17].

Dhaka Hospital of the International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b) has cared for a number of children with diarrhoea that also have UTI but does not have any data on the burden, risk factors, bacterial aetiology and the susceptibility to antibiotics, and outcome of UTI in these children. Our aim was to evaluate the above factors in children with diarrhoea aged <5 years presenting with UTI.

MATERIALS AND METHODS

Study design

This was a retrospective chart review that was conducted at the Dhaka Hospital of icddr,b using the electronic database of the hospital (SHEBA). We used an unmatched case-control design and enrolled all children with diarrhoea of both sexes, aged 0–59 months, who were admitted to the intensive care unit, high-dependency unit, or longer stay ward of the hospital from May 2011 to April 2013 with history of fever (⩾38 °C) and who had a urine culture been performed. Children with diarrhoea with UTI constituted cases and randomly selected children with diarrhoea without UTI constituted controls. Controls were randomly selected by computer randomization using SPSS v. 17.0 (SPSS Inc., Chicago) from a computerized data source of icddr,b. We used a 1:3 unmatched case-control ratio to increase the statistical power of our analyses.

Study site

The study was conducted at Dhaka Hospital of icddr,b. The description of this hospital has been given elsewhere [Reference Chisti18].

Patient management

Children with diarrhoea and a UTI received levofloxacin/ciprofloxacin; associated other comorbidities, i.e. management of pneumonia, sepsis, severe cholera, dysentery, severe malnutrition, and other bacterial infections was performed following the hospital's guidelines [Reference Chisti19, 20].

Definitions

UTI

We defined UTI in a child as the presence of significant bacteriuria [Reference Ibeneme21] from a single sample of urine culture reported by the microbiology laboratory of icddr,b. Only clean-catch urine samples were collected for both cases and controls before administration of any antibiotic at hospital. Urine specimens were collected into a sterile container. Bacterial growth <105 c.f.u./ml from the collected urine sample were regarded as contaminants and disregarded [Reference Ibeneme21].

Diarrhoea

Passage of ⩾3 abnormally loose or watery stools/24 h, and status of dehydration was defined by ‘Dhaka Methods’ of assessment of dehydration that is almost similar to the WHO method and approved by WHO [Reference Alam and Ashraf22].

Nosocomial infection (NI)

If evidence of new infection was identified at least 48 h after admission, patients were categorized as NI. Evidence of new infection was categorized clinically as the development of new clinical features in hospitalized children [Reference Shahunja23, Reference Fagon24].

Sepsis

Presence or presumed presence of infection with hypothermia (⩽35·0 °C) or hyperthermia (⩾38·5 °C), tachycardia, tachypnoea, and abnormal white blood cell count (WBC) (>11 × 109/l or <4 × 109/l or band and neutrophil ratio ⩾0·10) [Reference Chisti25, Reference Dellinger26].

Pneumonia

Initial diagnosis of pneumonia was done clinically following the WHO recommended classification of pneumonia [20, Reference Wandi, Peel and Duke27] and confirmed with radiological evidence of consolidation or patchy opacities [Reference Chisti28] by attending hospital physicians.

Severe acute malnutrition (SAM)

SAM in a child was defined if the child had severe wasting (weight for height/length Z score <−3 of median of the WHO growth standard), or nutritional oedema.

Persistent diarrhoea (PD)

PD was defined as children having acute diarrhoea lasting ⩾14 days [29].

Procedure

In the laboratory, each collected urine specimen was plated onto blood agar medium along with a selective and differential agar such as MacConkey agar for Gram-negative organisms [Reference Fung30]. Urine specimens were plated, using a 0·001 ml calibrated loop. Plates were incubated at 35 °C aerobically and examined at 18–24 h, they were further incubated for another 24 h before a negative report was issued. Cultures were quantitated, and those microorganisms isolated in the range of ⩾105 c.f.u./ml were identified. ‘Significant’ bacteriuria is defined as a clean-catch, midstream specimen containing a bacterial count of ⩾105 c.f.u./ml. Bacterial identifications were performed with the API 20E system (Analytab Products, USA) [Reference Ahmed31].

The agar diffusion technique was used for antibiotic susceptibility testing. Five colonies of the test organisms were streaked on agar plates using a sterile inoculating wire loop. The appropriate multidisc, depending on whether the test organism plated will be Gram negative or Gram positive, was then placed firmly onto the surface of the dried plates, using sterile forceps. The plates were left at room temperature for 1 h to allow diffusion of the different antibiotics from the disk into the medium. The plates were further incubated at 37 °C for 18–24 h. Susceptibility pattern was interpreted using the zone sizes according to Clinical and Laboratory Standards Institute (CLSI) guidelines [Reference Shaifali32].

The identification of blood isolates was performed following standard microbiological laboratory procedure in the Dhaka Hospital, icddr,b [Reference Shahunja33].

Analysis

Case report forms were developed, pre-tested, and finalized for data acquisition. Characteristics analysed included socio-demographics (age, gender, height and weight, low socioeconomic status, source of drinking water, formula feeding, vaccination status), history of vomiting and pre-admission antibiotic use, duration of fever, clinical signs, infection indices including: WBC and immature polymorph (B), renal function by serum creatinine level, isolated uropathogens and their sensitivity, microscopic urine analysis, clinical diagnoses (sepsis, pneumonia, SAM, PD, NI) and outcome.

All data were entered into SPSS for Windows v. 17.0 and Epi-Info v. 6.0 (USD Inc., USA). Differences in proportions were compared by χ 2 test. In normally distributed data differences of means were compared by Student's t test and Mann–Whitney test was used for comparison of data that were not normally distributed. A probability of <0·05 was considered statistically significant. Strength of association was determined by a calculating odds ratio (OR) and 95% confidence intervals (CI). We have these statistics both in our univariate analyses and logistic regression. Initially, we performed univariate analyses of the relevant characteristics (Table 1) to identify factors that were significantly associated with UTI and finally, we performed logistic regression analysis to identify the independently associated factors of UTI in children aged <5 years with diarrhoea. In the logistic regression model UTI was the dependent variable and the characteristics that were significantly associated with UTI in the univariate model were considered as independent variables.

Table 1. Characteristics of cases and controls admitted to Dhaka Hospital, icddr,b.

OR, odds ratio; CI, confidence interval; IQR, interquartile range; SAM, severe acute malnutrition; s.d., standard deviation; HPF, high-power field.

Values given are n (%) unless indicated otherwise.

Ethical standards

Our research did not involve any interviews with patients or caregivers and it was solely a chart analysis. The data were anonymized before being received by us.

RESULTS

A total of 365 children were enrolled with study criteria. There were 26 cases and 78 controls. Thus, the prevalence of culture-proven UTI in diarrhoeal children who presented with history of fever was 7% (26/365). In all the bacterial isolates of UTI in our study, 18 (69%) were E. coli, four (15%) were Klebsiella, one each was Acinetobacter, Enterococcus, and group B streptococcus. The sensitivity of E. coli was 100% for meropenem, 93% amikacin, 79% ceftazidime, 57% levofloxacin, 20% ceftriaxone and cotrimoxazole, and 0% for ampicillin.

Cases more often received antibiotics prior to admission, presented with younger age, and pneumonia, and less often presented with documented fever on admission compared to controls (Table 1). In logistic regression analysis after adjusting for potential confounders such as younger age (6 months), severe acute malnutrition, and NI, cases more often had PD, pneumonia and received antibiotics prior to admission (Table 2). Death was comparable in cases and controls (Table 1). Other variables were also comparable in the groups (Table 1).

Table 2. Results of logistic regression in exploring the independent predictors of UTI in children aged <5 years with diarrhoea

aOR, Adjusted odds ratio; CI, confidence interval

DISCUSSION

This study, although limited by small sample size, was able to describe our experience with the patients admitted for treatment of diarrhoea and UTI. We are able to identify different risk factors of UTI in children aged 0–59 months with diarrhoea. The observation of this study indicates that UTI is common in hospitalized children with diarrhoea tested for UTI. Their median age was 6 months which is consistent to our earlier observation in children without diarrhoea [Reference Heffner and Gorelick34Reference Roman, Chang and Schroeder37].

As expected, E. coli was the most common uropathogen in our study, as reported previously in a number of studies [Reference Garout10, Reference Al-Mardeni16, 20, Reference Heffner and Gorelick34]. One of the important observations of this study is the association of UTI with PD. Most of the cases of PD are associated with non-gastrointestinal infections particularly UTI and acute respiratory tract infection (ARI). Those may be missed on clinical examination unless efforts are made to investigate these children [Reference Ashraf38, Reference Chisti39]. However, frequent association of PD has been observed with UTI or ARI or both [Reference Sibal40]. Although we failed to identify any stool pathogen in PD cases, a previous study from Bangladesh revealed that the most common pathogen causing PD was E. coli [Reference Ashraf38]. In our study, PD developed during hospitalization and stool culture of all PD patients was performed after the development of PD. Initiation of antibiotics in all patients with UTI and PD might have an impact on no growth in stool culture. As these patients simultaneously presented with UTI and acute watery diarrhoea (and developed PD during hospitalization), we do not know whether diarrhoea could either be the cause or the consequence of UTI. However, a prospective study with large sample may answer this question.

Our observation that children with UTI were more likely to have received antibiotics prior to hospital admission compared to those without UTI is also consistent with other studies [Reference Arslan41, Reference Marcus42]. The use of antibiotics pre-admission might have an impact for development of increased resistance bacteria [Reference Arslan41] causing UTI or diarrhoea in our study children. However, we do not have any data that suggest the administration of antibiotics prior to hospital admission in children with diarrhoea and UTI is directly related to UTI, or that UTI is a consequence of the prior antibiotic treatment.

We observed that a higher proportion of children with diarrhoea (39%) and UTI were associated with pneumonia than those without UTI. In our study children, both UTI and pneumonia were present simultaneously during hospitalization. We can speculate that it might be due to translocation of bacteria such as E. coli through transcellular and paracellular pathways of vulnerable gut in diarrhoeal children, and this might occur prior to hospitalization. This finding of our study is consistent with an earlier observation [Reference Sood43].

UTI in febrile children has been widely studied in different parts of the world [Reference Alemu13, Reference Velez14, Reference Ibeneme21]. An 11% prevalence in febrile children aged <5 years was reported by researchers in Nigeria [Reference Ibeneme21]. In our study, children with diarrhoea and UTI presented less often with documented fever compared to those without UTI as most of them received antibiotics prior to hospital admission, which is consistent with previous observations [Reference Shaw9].

Our observation of a lack of association of low socioeconomic status, source of drinking water (tube well), formula feeding, vomiting, dehydrating diarrhoea, sepsis, NI during hospitalization with UTI in diarrhoeal patients might be due to small sample size.

Our study has some limitations, including the method of urine collection. We used clean-catch urine, rather than supra-pubic aspiration, which, especially in young children, is more likely to avoid contamination of urine with stool. Second, the retrospective design of the study potentially created a selection bias as we relied on records for enrolment criteria. Third, the same design limited the sample size and probably prevented identification of subtle differences between groups for further relevant clinical risk factors of UTI in such children. Fourth, the results could only be applicable in children with diarrhoea presenting with history of fever, but could not be generalized in all diarrhoeal children.

In conclusion, our data showed that the prevalence of UTI in children aged <5 years with diarrhoea was 7%. PD, pneumonia and history of receiving antibiotics prior to admission were independently associated with UTI in children aged <5 years with diarrhoea. Commonly isolated uropathogens found were E. coli and Klebsiella leading to UTI. Thus, identification of these simple clinical predictors of UTI may help clinicians for early diagnosis and prompt treatment with antibiotics in order to reduce morbidity in such populations.

ACKNOWLEDGEMENTS

This work was supported by icddr,b and its donors, which provide unrestricted support to the institution for its operations and research. Current donors providing unrestricted support include: Government of the People's Republic of Bangladesh; Canadian International Development Agency (CIDA), Swedish International Development Cooperation Agency (Sida), and the Department for International Development, UK (DFID).

We gratefully acknowledge the donors for their support and commitment to icddr,b's research efforts. We express our sincere thanks to all physicians, clinical fellows, nurses, members of the feeding team, and cleaners of the hospital for their invaluable support. We also gratefully acknowledge icddr,b library and SHEBA personnel for their tireless support and help.

DECLARATION OF INTEREST

None.

Footnotes

† Senior author.

References

REFERENCES

1. Tseng, MH, et al. Changing trend in antimicrobial resistance of pediatric uropathogens in Taiwan. Pediatrics International 2008; 50: 797800.CrossRefGoogle ScholarPubMed
2. Salmani, H, et al. Pathotypic and phylogenetic study of diarrheagenic Escherichia coli and uropathogenic E. coli using multiplex polymerase chain reaction. Jundishapur Journal of Microbiology 2016; 9: e28331.Google Scholar
3. Craig, JC, et al. Antibiotic prophylaxis and recurrent urinary tract infection in children. New England Journal of Medicine 2009; 361: 17481759.Google Scholar
4. Stansfeld, J. Clinical observations relating to incidence and aetiology of urinary-tract infections in children. British Medical Journal 1966; 1: 631.Google Scholar
5. Mårild, S, Jodal, U. Incidence rate of first-time symptomatic urinary tract infection in children under 6 years of age. Acta Paediatrica 1998; 87: 549552.CrossRefGoogle ScholarPubMed
6. Uhari, M, Nuutinen, M. Epidemiology of symptomatic infections of the urinary tract in children. British Medical Journal 1988; 297: 450452.Google Scholar
7. Kwok, WY, et al. Incidence rates and management of urinary tract infections among children in Dutch general practice: results from a nation-wide registration study. BMC Pediatrics 2006; 6: 10.CrossRefGoogle ScholarPubMed
8. Neumann, CG, Pryles, CV. Pyelonephritis in infants and children. Autopsy experience at the Boston City Hospital, 1933–1960. American Journal of Diseases of Children 1962; 104: 215229.CrossRefGoogle ScholarPubMed
9. Shaw, KN, et al. Prevalence of urinary tract infection in febrile young children in the emergency department. Pediatrics 1998; 102: e16.CrossRefGoogle ScholarPubMed
10. Garout, WA, et al. Urinary tract infection in children younger than 5 years. Etiology and associated urological anomalies. Saudi Medical Journal 2015; 36: 497501.Google ScholarPubMed
11. Yasemi, M, et al. Frequency of bacteria causing urinary tract infections and their antimicrobial resistance patterns among pediatric patients in Western Iran from 2007–2009. Journal of Biological Regulators and Homeostatic Agents 2014; 28: 443448.Google Scholar
12. Pitout, JDD. Extraintestinal pathogenic Escherichia coli: a combination of virulence with antibiotic resistance. Frontiers in Microbiology 2012; 3.Google Scholar
13. Alemu, A, et al. Bacterial profile and drug susceptibility pattern of urinary tract infection in pregnant women at University of Gondar Teaching Hospital, Northwest Ethiopia. BMC Research Notes 2012; 5: 197.Google Scholar
14. Velez, Echeverri C, et al. Resistance profile for pathogens causing urinary tract infection in a pediatric population, and antibiotic treatment response at a university hospital, 2010–2011. Colombia Medica (Cali, Colombia) 2014; 45: 3944.Google Scholar
15. Farajnia, S, et al. Causative agents and antimicrobial susceptibilities of urinary tract infections in the northwest of Iran. International Journal of Infectious Diseases 2009; 13: 140144.Google Scholar
16. Al-Mardeni, RI, et al. Empirical treatment for pediatric urinary tract infection and resistance patterns of uropathogens, in Queen Alia hospital and Prince A'Isha military center – Jordan. Saudi Journal of Kidney Diseases and Transplantation 2009; 20: 135139.Google Scholar
17. Al-Mendalawi, MD. Antibiotic resistance pattern and empirical therapy for urinary tract infections in children. Saudi Medical Journal 2008; 29: 1520.Google Scholar
18. Chisti, MJ, et al. A prospective study of the prevalence of tuberculosis and bacteraemia in Bangladeshi children with severe malnutrition and pneumonia including an evaluation of Xpert MTB/RIF Assay. PLoS ONE 2014; 9: e93776.Google Scholar
19. Chisti, MJ, et al. Bubble continuous positive airway pressure for children with severe pneumonia and hypoxaemia in Bangladesh: an open, randomised controlled trial. Lancet 2015; 386: 10571065.Google Scholar
20. WHO. Pocket Book for Hospital Care of Children: Guidelines for the Management of Common Illness with Limited Resources. World Health Organization, Geneva, Switzerland, 2013.Google Scholar
21. Ibeneme, CA, et al. Urinary tract infection in febrile under five children in Enugu, South Eastern Nigeria. Nigerian Journal of Clinical Practice 2014; 17: 624628.Google Scholar
22. Alam, NH, Ashraf, H. Treatment of infectious diarrhea in children. Paediatric Drugs 2003; 5: 151165.Google Scholar
23. Shahunja, KM, et al. Experience with nosocomial infection in children under 5 treated in an urban diarrheal treatment center in Bangladesh. Global Pediatric Health 2016; 3: 2333794x16634267.Google Scholar
24. Fagon, JY, et al. Nosocomial pneumonia and mortality among patients in intensive care units. Journal of American Medical Association 1996; 275: 866869.Google Scholar
25. Chisti, MJ, et al. Clinical predictors and outcome of hypoxaemia among under-five diarrhoeal children with or without pneumonia in an urban hospital, Dhaka, Bangladesh. Tropical Medicine & International Health 2012; 17: 106111.Google Scholar
26. Dellinger, RP, et al. Surviving sepsis campaign: international guidelines for management of severe sepsis and septic shock: 2012. Critical Care Medicine 2013; 41: 580637.Google Scholar
27. Wandi, F, Peel, D, Duke, T. Hypoxaemia among children in rural hospitals in Papua New Guinea: epidemiology and resource availability – a study to support a national oxygen programme. Annals of Tropical Paediatrics 2006; 26: 277284.Google Scholar
28. Chisti, MJ, et al. Clinical and laboratory features of radiologic pneumonia in severely malnourished infants attending an urban diarrhea treatment center in Bangladesh. Pediatric Infectious Disease Journal 2010; 29: 174177.CrossRefGoogle ScholarPubMed
29. Anon. WHO Guidelines Approved by the Guidelines Review Committee. In: Pocket Book of Hospital Care for Children: Guidelines for the Management of Common Childhood Illnesses. Geneva: World Health Organization, 2013.Google Scholar
30. Fung, JC, et al. Primary culture media for routine urine processing. Journal of Clinical Microbiology 1982; 16: 632636.CrossRefGoogle ScholarPubMed
31. Ahmed, D, et al. Recurrent urinary tract infection due to co-infection with extended spectrum β-lactamase-producer uropathogenic Escherichia coli and enteroaggregative E . coli. JMM Case Reports 2014; 1.Google Scholar
32. Shaifali, I, et al. Antibiotic susceptibility patterns of urinary pathogens in female outpatients. North American Journal of Medical Sciences 2012; 4: 163169.Google Scholar
33. Shahunja, KM, et al. Predictors of death in under-five children with sepsis attending an urban diarrheal treatment centre in Bangladesh. Food and Nutrition Sciences 2013; 04: 709714.Google Scholar
34. Heffner, VA, Gorelick, MH. Pediatric urinary tract infection. Clinical Pediatric Emergency Medicine; 9: 233237.Google Scholar
35. Hendaus, MA, et al. Risk of urinary tract infection in infants and children with acute bronchiolitis. Paediatrics & Child Health 2015; 20: e2529.CrossRefGoogle ScholarPubMed
36. Mirsoleymani, SR, et al. Bacterial pathogens and antimicrobial resistance patterns in pediatric urinary tract infections: a four-year surveillance study (2009–2012). International Journal of Pediatrics 2014; 2014: 126142.Google Scholar
37. Roman, HK, Chang, PW, Schroeder, AR. Diagnosis and management of bacteremic urinary tract infection in infants. Hospital Pediatrics 2015; 5: 18.Google Scholar
38. Ashraf, b H, et al. Persistent diarrhoea: associated infection and response to a low lactose diet. Journal of Tropical Pediatrics 2002; 48: 142148.Google Scholar
39. Chisti, MJ, et al. Predictors of bacteremia in infants with diarrhea and systemic inflammatory response syndrome attending an urban diarrheal treatment center in a developing country. Pediatric Critical Care Medicine 2010; 11: 9297.Google Scholar
40. Sibal, A, et al. Associated infections in persistent diarrhoea – another perspective. Journal of Tropical Pediatrics 1996; 42: 6467.CrossRefGoogle ScholarPubMed
41. Arslan, H, et al. Risk factors for ciprofloxacin resistance among Escherichia coli strains isolated from community-acquired urinary tract infections in Turkey. Journal of Antimicrobial Chemotherapy 2005; 56: 914918.CrossRefGoogle ScholarPubMed
42. Marcus, N, et al. Community-acquired Pseudomonas aeruginosa urinary tract infections in children hospitalized in a tertiary center: relative frequency, risk factors, antimicrobial resistance and treatment. Infection 2008; 36: 421426.Google Scholar
43. Sood, A, et al. Incidence, admission rates, and economic burden of pediatric emergency department visits for urinary tract infection: data from the nationwide emergency department sample, 2006 to 2011. Journal of Pediatric Urology 2015; 11: 246.e1–8.Google Scholar
Figure 0

Table 1. Characteristics of cases and controls admitted to Dhaka Hospital, icddr,b.

Figure 1

Table 2. Results of logistic regression in exploring the independent predictors of UTI in children aged <5 years with diarrhoea