Which technique should the nurse utilize when collecting a clean catch urine specimen for culture and sensitivity in a client with a suspected urinary tract infection?

Abstract

Urinary tract infection is a commonly occurring paediatric infection associated with significant morbidity. Diagnosis is challenging as symptoms are non-specific and definitive diagnosis requires an uncontaminated urine sample to be obtained. Common techniques for sampling in non-toilet-trained children include clean catch, bag, pad, in-out catheterisation and suprapubic aspiration. The pros and cons of each method are examined in detail in this review. They differ significantly in frequency of use, contamination rates and acceptability to parents and clinicians. National guidance of which to use differs significantly internationally. No method is clearly superior. For non-invasive testing, clean catch sampling has a lower likelihood of contamination and can be made more efficient through stimulation of voiding in younger children. In invasive testing, suprapubic aspiration gives a lower likelihood of contamination, a high success rate and a low complication rate, but is considered painful and is not preferred by parents. Urine dipstick testing is validated for ruling in or out UTI provided that leucocyte esterase (LE) and nitrite testing are used in combination.

Introduction

Urinary tract infection (UTI) is a common bacterial infection and, as such, a common presentation to paediatric health services. 5.9% of children presenting acutely to UK General Practitioners (family doctors) will have a UTI, rising to 7.3% if the population is restricted to those < 3 years old [1] and 7% of those < 2 years with urinary symptoms [2].

There are several common pathogens, with > 70% of cases due to E. coli, with c.10% involving other coliforms (including Klebsiella and Enterobacter species) and c. 5% Proteus species [3,4,5]. UTIs are not trivial infections, with detectable bacteraemia of the same organism in 10% of cases, rising to 17% in those < 1 month old [3]. 2.8–16% of individuals may develop kidney scarring following their first episode of UTI, with 8.4% of these developing hypertension, and a small proportion progressing to kidney failure [6,7,8]. Kidney scarring and damage can be prevented if UTI is treated in a timely manner, with delay leading to increasingly likely scarring [9, 10].

With this potentially avoidable morbidity, it is crucial to have the correct diagnosis. Clinical diagnosis is not straightforward and symptoms are non-specific, complicated by the fact that those who are most susceptible are least able to report symptoms. There is a reduction in incidence of UTI with advancing age, which is of significance given the higher prevalence of UTI in non-toilet-trained children. Meta-analysis of females with UTI shows a reduction in prevalence with advancing age, from 7.5% at 0–3 months, 5.7% at 3–6 months, 8.3% at 6–12 months and 2.1% in those > 12 months [2]. Overall, if there is significant suspicion, such that a urine sample is sent, then females are around three times more likely to have a UTI compared with males [4].

Given the high prevalence of UTI, diagnostic difficulty and associated severe morbidity with delayed treatment, it is important to use the optimal approach to obtain urine samples to confirm or exclude this important diagnosis. This is challenging in non-toilet-trained children.

Once obtained, urine needs to be tested and, although the definitive diagnosis is confirmed on urine culture, more immediate results are key for clinical decisions to be made, usually provided by dipstick testing or laboratory microscopy.

Publications were identified through searching Google Scholar, PubMed and Crossref with search terms relevant to paediatric urine collection. Inclusion for full review was based on abstract review. Reference lists of included publications were then hand searched for further relevant material.

In this review, we explore the relative merits of different methods of obtaining urine samples from non-toilet-trained children as well as reviewing the use of dipstick testing and microscopy in this patient group.

Key guidance

Given the high prevalence and potential for morbidity from UTIs, there are several sources of key guidance published internationally, with several countries referencing the UK and US guidance.

UK NICE guidance [11] advises that clean catch urine sampling is the recommended methodology but that if this is unobtainable, then other non-invasive methods such as a urine collection pad (but not gauze, cotton wool or sanitary towels) should be used.

Where it “is not possible or practical” to collect urine non-invasively then catheter sampling or suprapubic aspiration (SPA) should be used. If SPA is used, then an ultrasound should be performed first to confirm urine in the bladder [11].

The American Academy of Paediatrics (AAP) guidance [12] recommends that for diagnosis of UTI if antibiotics are to be given, then the “specimen needs to be obtained through catheterization or SPA, because the diagnosis of UTI cannot be established reliably through culture of urine collected in a bag.”

If immediate antibiotics are not required, then they advise that there are two options: either “to obtain a urine specimen through catheterization or SPA for culture and urinalysis” or “to obtain a urine specimen through the most convenient means and to perform a urinalysis.” If the urinalysis results suggest a UTI (positive leucocyte esterase or nitrite test or microscopic analysis positive for leucocytes or bacteria), then a urine specimen should be obtained through catheterization or SPA and cultured. They do not recommend clean catch, pad or bag sampling.

Other international guidelines from Australia, Canada, the European Society for Paediatric Urology, Israel, Italy and New Zealand suggest the use of bag sampling in systemically well children, with an alternate method of collection required (clean catch, catheter or SPA) if dipstick from bag samples is suggestive of infection [13,14,15,16,17,18].

In unwell children, catheter or SPA sampling is recommended by Australian, Canadian, European, Italian, New Zealand, UK and US guidance [11,12,13, 15,16,17, 19].

There is a clear difference between international guidelines in how they advise urine is to be collected, with differing levels of technical challenge depending on the method employed. We review the benefits and disadvantages of each method of urine collection.

Methods of collection

Clean catch urine

Clean catch urine (CCU) samples are obtained by holding a sterile container beneath the urethra with the nappy off, until a void begins, with care taken to avoid any skin contact with the specimen container. Voiding can be stimulated as detailed in a later section of this review.

Contamination rate is a key differentiator determining collection approaches as it is estimated that 30% of contaminated samples are masking true UTIs [20]. Reported contamination rates differ significantly by approach and vary widely between sources. Published rates are collated in Table 1 for ease of comparison.

Table 1 Comparison of contamination rates by collection method

Full size table

NICE recommends clean catch sampling and SPA as the most diagnostically accurate sampling methods. As shown in Table 1, there are several sources demonstrating catheterisation as having a lower contamination rate than that reported for clean catch sampling, but in direct comparison clean catch compares well to catheter sampling with a contamination rate of 5%, compared with 8% for catheter samples [32]. In sources without direct comparison, perineal cleaning can also reduce the contamination rate comparable with that published for catheter sampling, as discussed below.

Contamination rates seem to differ by gender with 10.5% of male samples and 16.4% of female samples being contaminated [25]. Other sources also find contamination is significantly higher in females and in those aged 0–3 months and over 12 years or if the urine sample is collected at home [4, 33].

SPA is generally used as the comparator for contamination rates as it involves the least exposure to non-sterile sites such as the distal urethra. When clean catch sampling is compared directly to SPA, sensitivity ranges from 75 to 100% and specificity ranges from 57 to 100% [34]. A separate examination of clean catch sampling compared with SPA as a gold standard reported a sensitivity of 88.9% and a specificity of 95.0%, giving false-positive rates of 5% and false-negative rates of 12% compared with SPA [35].

By its nature, clean catch sampling is time consuming, with a median time to sample of 30.5 min and an interquartile range of 11–66 min [28]. Seventy-five percent of CCUs are obtained in 1 h and 25% of these within 7 min [36]. It is also relatively easy to “miss” collecting a sample from a voiding event, occurring in around 16% of attempts [28]. A combination of these factors may contribute to failed collection with families abandoning attempts in 20% of cases [28]. If a sample is not achieved by 1 h, then additional time taken is unlikely to lead to a sampling success [28], a useful parameter to consider in busy departments where patients may be kept from going home while awaiting a sample.

Clean catch samples, as expected, are easier to obtain in older children. The DUTY (Diagnosis of UTI in Young Children) study found a significant difference in method of collection by age in UK primary care cases: of 2884 children aged < 3 years, 26.3% of samples were collected using clean catch vs. 96.7% of children aged 3–5 years [37].

Perineal cleaning

Practice differs between centres as to if and how the perineum should be cleaned before a clean catch sample is collected, with some centres using saline, soap or chlorhexidine.

Interventional studies have shown that a staff education package highlighting the importance of cleaning did not change contamination rates in an emergency department but as monthly clinical activity increased, so did the likelihood of contamination, suggesting it is an avoidable occurrence [33]. A randomised trial of cleaning with soap vs. not cleaning in 350 patients found significantly lower contamination rates in the cleaning group (7.8%) vs. the non-cleaning group (23.9%) [38]. In a different study, perineal cleaning reportedly improved contamination rates with a contamination rate of 5% after cleaning, lower than most reported rates [30].

A study focussed on targeted cleaning in uncircumcised boys found no change in contamination rates [39]. However, a systematic review provided overall support for perineal cleaning and collection of a mid-stream rather than initial stream sampling [40].

Bag sampling

Bag sampling involves attaching a sterile plastic bag to the perineum, usually with adhesive around the bag opening, such that voided urine falls within the bag.

While actively recommended against by the AAP, bag sampling remains a highly utilised method of sampling, especially in the community. It is the preferred method of collection in Europe: of 1129 paediatricians surveyed, 53% selected a bag as their first choice for infants < 3 months and 59% for children 4–36 months of age [41], whereas in the USA, 25% of samples for 3066 infants were collected by bag, 70% by catheter, 3% by SPA and 2% by clean catch [3]. The ease of bag sampling lends itself well to a community setting.

There is a clinician concern that the adhesion of the bag to sensitive skin causes moderate to severe pain when assessed on visual pain scales [42]. A study of French doctors reported bag removal as “equally to more painful” than catheter removal for females and “equally to less painful” for males [43]. Reports on the practicalities of sampling note that the bag pulls away from the skin when full and heavy, leading to sample loss [44].

Contamination rates in Table 1 are higher than for clean catch sampling but rates are not correlated with the time taken to obtain the sample [28]. The AAP guideline states that bag cultures have “an unacceptably high false-positive rate and are valid only when they yield negative results”, stating that the rate of false positives range from 88 to 99% of tests [12].

In centres where suprapubic aspiration is rarely performed, catheter samples may be used as a reference standard. When directly compared with catheter samples in the same children, 7.5% of bag samples were false positives and 29% false negatives [45], compared with a false-positive rate of 18% and false-negative rate of 24% in another study [46].

Pad sampling

Pad sampling involves the insertion of an absorbent material into the child’s nappy from which urine is later aspirated after voiding. There are custom designed pads for this purpose, such as the Newcastle urine collection pad (UCP).

The main advantages of the pad collection are that the process is passive and requires less parental effort with less disruption to the child. There is decreased likelihood of missing a sample compared with clean catch collection, with overall sampling success of 96% [22]. It is the preferred collection method of parents [26].

In direct comparison the time taken to obtain a pad sample is shorter than for clean catch, with a median of 30 vs. 107.5min, however this duration is comparable to the 30.5 min median collection time for clean catch sampling reported by other publications [21, 28]. One source reports a longer median collection time for pad sampling of 45 min [47].

UCPs trap and retain a substantial amount of cellular material, reducing cell counts on microscopy but dipstick testing for blood and leucocyte esterase remains reliable [48]. Several sources have shown microscopy of pad samples gives a lower white cell count [49,50,51].

Some centres use cotton wool in place of specific UCPs. This is problematic as cotton wool balls have antibacterial properties. In one study, E. coli was shown to be unaffected by cotton wool, but colony counts of Enterococcus faecalis fell by up to 75% after 30 min of contact, with complete elimination of the organism after 2 h [50]. Cotton wool also impacts on viral studies: absorption of CMV onto cotton and the inhibitory effect of formalin reduce CMV counts on rapid culture but do not alter PCR results [52].

Contamination is the main concern in the use of UCPs, with prolonged contact between the pad and perineum thought to increase the likelihood of contamination with skin or gut flora. Measures to reduce this risk have been trialled including use of moisture-sensitive alarms, which do not reduce contamination [53] and changing the pad every 30 min. In a randomised controlled trial, changing the pad every 30 min gave a contamination rate of 3%, compared with 29% when a single pad was left in place [47].

Likelihood of sample contamination has been found to be significantly increased in pads when compared directly with clean catch samples, with pads contaminated in 12.2–26.3% of cases vs. 1.8–6.4% for clean catch [37]. In the DUTY study of 2740 clean catch vs. 2277 nappy pad samples, the risk ratio of contamination was 6.66 for pads [4]. The probability of sample contamination was not increased by delay in the time taken for samples to arrive at laboratories nor the presence of a nappy rash. However, it was increased in female patients or with parents collecting samples at home by either method [4]. In the same study, the contamination rate with coagulase-negative Staphylococcus in pads was 1.8 times higher than for clean catch urine but contamination with faecal organisms (E. coli and Enterococcus) was not significantly increased [4]. Contamination with E. coli is especially problematic as it is both a common contaminant and the most common UTI pathogen.

The prevalence of UTIs diagnosed was lower for nappy pad (1.3%) than for clean catch (2.3%) samples, suggesting that UTIs are missed in nappy pad samples because of contamination [4]. The presence of squamous epithelial cells on microscopy helps predict contamination in clean catch urine (indicating passage of urine over the skin) but not in nappy pad samples (where there is sustained skin contact) and, as such, the presence or absence of squamous cells should be ignored in nappy pad sampling [4].

Urinalysis from pad samples

While paediatric practice commonly requires sterile collection of urine for potential bacterial culture, there are other reasons that urine may be collected. If sterility is not required, then pad collection can be advantageous.

Importantly, pads have been shown not to clinically impact levels of nitrites, glucose, ketones, urea, electrolytes, creatinine, osmolality, calcium, phosphate, magnesium, urate, oxalate, pH, toxicology for drugs of abuse, catecholamines, amino acids, organic acids and glycosaminoglycans [48, 54]. Pads show good concordance to other methods of sampling for diagnostic urinary metabolites in patients with metabolic disorders including phenylketonuria, cystinuria, mucopolysaccharidoses II and III, organic acid disorders and altered urine simulating urea cycle disorders [54].

However, it is important to note that some nappy materials and cotton wool balls selectively absorb creatinine [55] and protein [56]. Albumin binding to pads is very variable and can be up to 10–40% of sample content, with retinal binding protein also adhering to pads within 15 min of contact [48, 56]. Protein retention increases the longer the urine is left in a pad, reaching 20–30% after 90 min [48].

In-out catheterisation

In-out catheterisation describes the temporary insertion of a urinary catheter to obtain a sample, with the catheter then being removed. Theoretical benefits are that this avoids some contamination from colonising bacteria in the distal urethra compared with voided samples and may be less likely to lead to complications than suprapubic aspiration. Best practice is to discard the initial few drops of urine which are thought to have a higher likelihood of contamination from urethral bacteria, but this was not described in most of the sources reviewed. A randomised comparison of early sampling or late sampling found significantly higher sample contamination if the first drops of urine collected were cultured [57].

Test performance for cultures from in-out catheterisation is better than for non-invasive methods, with urine obtained for culture by catheter having a sensitivity of 95% and a specificity of 99%, compared with urine obtained through SPA [58,59,60].

One study examined the clinical impact of a contamination rate of 9.1% in catheter sampling. They found that the odds ratios of adverse events were 4.9 for unnecessary recall for further testing, 4.8 for unnecessary treatment, 15.6 for unnecessary prolonged treatment, 4.1 for unnecessary radiologic investigation and 12.4 for unnecessary hospital admission [29]. When SPA is performed to confirm organisms cultured from a catheter sample, it has identified a false-positive rate of 71% from catheter samples [61].

Catheterisation is a less variable procedure than suprapubic aspiration, with authors reporting a 92.3% [45] to 100% success rate [62]. Use in a neonatal population reports an 81.2% [63] to 83.3% success rate [64].

Significant complications are rarely described, with transient microscopic haematuria in 17% [65]. One study found that previous catheterisation was a risk factor for septicaemia in neonates [66].

Practitioner perception is that catheterisation is painful with most European centres surveyed using some form of analgesia [41]. However, intermittent self-catheterisation is well tolerated by children with intact sensation suggesting that it is not inherently painful [67, 68]. Staff confidence is reported to be low with half of junior doctors and nurses surveyed not having had training in how to catheterise children [69].

Suprapubic sampling

Suprapubic aspiration is undertaken through the insertion of a 22G needle through the anterior abdominal wall and into the bladder, usually aided by ultrasound guidance, with urine aspirated into a syringe.

Suprapubic sampling is often described as the gold standard for urine sampling due to the theoretical minimal likelihood of contamination [44], avoiding bacteria which colonise the distal urethra as normal flora [70].

However, SPA is also considered the most invasive and painful method by practitioners and parents [61]. In contemporaneous scoring by parents and nurses in infants < 60 days old, it was rated as more painful than catheterisation [64].

The success rate varies by whether ultrasound guidance is used. Reported success rates in unguided attempts were 46% [62] to 64% [70]. Under guidance success improves from 79% [71] to 90% [70]. In direct comparison, there is reported improvement with guidance from 36 to 100% [72], 60 to 96% [73], 62 to 93% [35] and 52 to 79% [71]. As in many procedures, experience is beneficial, with improved success rates noted as the study progressed [70].

Patient selection and preparation are also important. There was no difference in success noted with or without guidance in one study if the patients were prehydrated and had identifiable dullness on suprapubic percussion: first attempt success was 60% in both groups, rising to 87% guided vs. 80% unguided if 3 attempts were made [74]. In one study employing bladder measurements, there were no successful attempts if the antero-posterior diameter of the bladder on ultrasound was < 2 cm [75].

In neonatal patients, an unguided approach gave 64.7% success on the first tap [63]. Guidance may be of less benefit in the neonatal population with a success rate of 75% guided vs. 74% unguided in those under 28 days old [70].

Complications are rare, occurring with a rate of only 0.22% of 4985 SPAs performed in one study [76]. However, other studies have noted aspiration of gut lumen contents in 1 in 140 aspirations [70]. Microscopic haematuria has been seen for 24 h post aspiration in 3.6% of patients [70].

Any growth on urine cultured from SPA may be taken as significant given the sterile nature of the procedure [77, 78], but some centres still apply a culture threshold, but at a lower level than for sampling by other routes. The Italian Society for Paediatric Nephrology recommends a threshold of 1 × 104 cfu/ml from catheter or SPA samples, 5 × 104 cfu/ml from clean catch and 1 × 105 cfu/ml from bag samples [17]. The American Academy of Paediatrics suggests 5 × 104 cfu/ml as the threshold for UTI in children (regardless of collection method) under the age of 2 years [12], used in combination with pyuria to determine if the organism is a true culture, or a contaminant if pyuria is absent. Laboratory standards for the UK advise that 103 cfu/mL of a single species “may be diagnostic of UTI” and 104–105 cfu/mL “is indicative of UTI in a carefully taken specimen” [78].

Stimulation of voiding

Non-invasive testing relies on spontaneous voiding by the child. Stimulation of voiding could help achieve samples in a timely manner, allowing less time for contamination to occur.

In neonates, where central inhibition of spinal reflex arcs is less developed, voiding can be stimulated by holding the baby upright under both armpits with the legs dangling, tapping the abdomen suprapubically at 100 taps/min for 30 s, followed by circular lumbosacral massage for 30 s, alternating for up to 5 min. This has been shown to promote voiding, especially if performed 30 min post feeding [79]. Using this technique in those < 7 days old led to voiding within 5 min in 90% of infants [80].

In a population with mean age of 6–7 days, this technique gave a median collection time of 45 s with success in 86.3% [79]. In direct comparison of infants < 10 days old, 78% voided in 5 min with stimulation vs. 33% of controls without stimulation [31].

The effectiveness of the technique declines with age. In an older population of those < 6 months, 49% voided within 5 min of stimulation with a median collection time of 45 s [81]. A different study found that in a population with a median age of 10 months, the success rate was 27%, with most successful attempts occurring within 2 min [82]. They also found that likelihood of success decreased as the weight of the child increased [82].

Suprapubic and lumbosacral stimulation is not the only method of voiding stimulation that has been investigated. The “Quick-Wee” technique has been reported where chilled (2.8°), saline-soaked gauze is rubbed on the suprapubic area. In children aged 1–12 months, if it was stimulated for up to a 5-min period 31% of children voided vs. 12% of unstimulated control patients [83]. Fewer possible collection opportunities were missed: only 2 in the stimulation group vs. 5 in the control group [83]. There was no reported difference in the contamination rate, being around 27%, which is similar to other clean catch sample studies [83]. Use of ultrasound to determine bladder fullness before attempting stimulation did not lead to improved sample collection within 5 min [84].

Dipstick testing for UTI

Following successful sampling, the urine can be tested using point of care dipstick analysis and/or sent to the laboratory for microscopy and culture. The advantage of point of care dipstick testing is that this provides information to guide clinical decision-making immediately. The panel of routine tests for infection includes leucocyte esterase and nitrite.

Leucocyte esterase

Leucocyte esterase (LE) is an enzyme produced by white cells and is found in urine where white cells have been active (pyuria), such as when there is active infection.

Use of LE testing should be taken in the context of the clinical picture, with a high rate of false negatives in neutropenic patients [85] and in younger children whose frequent voiding reduces LE accumulation in stored urine [86]. As LE is not exclusively raised in children with UTI, the presence of pyuria does not entirely exclude that an organism cultured is a contaminant [4].

The sensitivity and specificity of LE for UTI varies by sample collection method. If a positive result for LE is taken as “+” or above, then sensitivity/specificity is reported as 86%/80% from clean catch [30], 86–88%/94–100% from catheter sampling [30, 66] and 76%/84% [66] from bag sampling with an overall sensitivity/specificity of 84%/91% [66]. A different study found no change in sensitivity/specificity of LE after urine was left for 2 h in contact with incontinence pads [87].

A meta-analysis examining LE reported significant heterogeneity between the studies with sensitivity ranging from 37.5% (specificity 96.4%) to 100% (specificity 92%) and specificity ranging from 69.3% (sensitivity 93.5%) to 97.8% (sensitivity 70%). The pooled positive likelihood ratio (LR+) for UTI was 5.5 and the pooled negative likelihood ratio (LR−) was 0.26 [34].

The extent of positivity (trace to +++) is also a useful parameter to assess. The DUTY study of over 7163 patients found that from samples collected from pads, the odds ratios of UTI are outlined in Table 2.

Table 2 Odds ratio of urinary tract infection (UTI) by extent of leucocyte esterase (LE) positivity for pad and clean catch sampling

Full size table

Asymptomatic bacteriuria as well as contamination should be considered in children with a positive culture result but a negative LE result [12]. This is an uncommon phenomenon, with a meta-analysis including 49,806 children showing asymptomatic bacteriuria in 0.18% of boys and 0.38% of girls [88].

Nitrite

Nitrite is produced from dietary nitrate in the bladder through metabolism by bacteria. It compares with LE in having lower sensitivity but higher specificity for UTI testing [12]. Nitrite is not associated with all organisms as it is not produced by Pseudomonas species or gram-positive organisms such as Enterococcus [85].

Nitrite testing is also impacted by age, as the more frequent voiding of younger children allows less time for nitrite to accumulate prior to sampling [86]. Original studies quote a dwell time of 4 h in the bladder to convert dietary nitrates to nitrites [89]. However, one paper goes against this trend, finding an increased nitrite positivity in those < 3 years with UTI 12.9% vs. 2.2% in those over 3 years [90]. Children may also have diets too poor in fruit and vegetables to provide sufficient urinary nitrate for conversion [91] or the nitrate ions present may degrade due to the lower sodium concentrations, more acidic pH or presence of urobilinogen more commonly seen in younger children [92].

As it is a product of bacterial metabolism, nitrite continues to be produced in urine samples after voiding, potentially changing a false-negative to a true-positive result over time. A study in adults found 0.5% of samples went from negative to positive after 2 h in an incontinence pad [93].

A meta-analysis covering 95,703 children found the sensitivity/specificity of nitrite testing to be 49%/98% [94], a different meta-analysis found wider ranges of sensitivity, from 16.2 to 88.1% with specificity ranging from 75.6 to 100%; all but two estimates of specificity were above 90% [34]. Smaller individual studies report sensitivity/specificity of 24–50%/98–100% [30, 66, 85].

A different meta-analysis found the pooled LR+ for UTI from positive nitrite testing to be 15.9 with a LR− of 0.51 [95]. The DUTY study found that from samples collected from pads, the odds ratios of UTI for nitrite positivity was 3.16 [37] compared with 38.4 for clean catch urine samples [4].

Combination testing

Taking these parameters in combination can improve the sensitivity and specificity compared with testing each in isolation. A dipstick can be taken as indicating UTI if LE or nitrite is positive or alternately can only be considered positive if both LE and nitrite results are positive. Table 3 collates information from a variety of meta-analyses. While the LR+ is repeatedly reported as significantly better for the “and” comparison, the LR− is not significantly different between “and” and “or” in some of the meta-analyses.

Table 3 Likelihood ratio of urinary tract infection (UTI) depending on interpretation of leucocyte esterase (LE) and nitrite results

Full size table

In the DUTY study, dipstick negative for both LE and nitrite had a pooled LR− of 0.22, suggesting that a dipstick negative for both nitrite and LE may be useful in ruling out a diagnosis of UTI [4]. Likewise, the pooled LR+ was 22.8, suggesting that a dipstick positive for both LE and nitrite may be useful for ruling in a UTI [4]. Individually however, the sensitivity/specificity of LE and nitrite was too variable to allow them to be of any use in exclusion or inclusion of UTI [4].

The method of sample collection also influences combined sensitivity/specificity, with bag sample dipstick testing shown to be more sensitive than catheter testing: 85% vs. 71% [97] but less specific. 62% vs. 97%, respectively [97]. This likely represents the trade-off of lower specificity giving higher sensitivity, with fortuitous capture of UTI in some contaminated bag samples. There was no significant difference between clean catch and catheter sampling in the performance of combined LE/nitrite testing in those under 90 days old with sensitivity/specificity of 86%/80% for clean catch and 91%/95% for catheter samples [30].

Overall, a combination of positive results for LE and nitrite is most accurate for ruling in disease, and a negative test for both nitrite and LE is the most accurate for ruling out disease [34]. However, the DUTY study of over 6390 samples identified that dipstick testing led to 3.3% of children without UTI being incorrectly treated for UTI vs. a rate of 2.3% for lab microscopy [98].

A meta-analysis by Whiting et al. showed that dipstick negative for LE and nitrite or microscopy negative for pyuria and bacteriuria can be reasonably used to exclude UTI in urine obtained from clean catch, bag or pad samples [95].

Age-related test performance

The sensitivity and specificity of combined analysis changes with increasing age, with test performance improving. This, combined with the greater prevalence of UTI and likelihood of bacteraemia in young infants, impacts on how dipstick testing should be used.

NICE recommends that urine dipstick testing is not used in patients < 3 months old due to worse diagnostic performance in younger age groups. For 3 months–3 years of age, they recommend that dipstick testing can be used to rule in UTI and rule it out in otherwise well children, without prior recurrent UTI. In those over 3 years, dipstick testing can be used to rule in and out UTI with positive nitrite being more indicative of UTI and necessitating treatment immediately, whereas positive LE can await culture results [11].

This reflects work by Sharief et al. and Shaw et al. who showed poor performance for LE and nitrite in those younger than 2 years [99, 100]. In meta-analysis, these two sources show that using LE and nitrite give a LR+ of 7.74 for children < 2 years and 28.79 for children > 2 years. Likewise, the LR− is 0.32 in the younger group and 0.19 in the older group [11]. A different meta-analysis also incorporating these studies and comparing dipstick performance to microscopy with stratification for age found that the highest LR+ was for dipstick testing in children over 2 years old (dipstick 27.1 vs. microscopy 1.69) and for microscopy in those under 2 years (dipstick 6.24 vs. microscopy 15.6). To rule out infection, the lowest LR− was for microscopy in all age groups (< 2 years = 0.27, > 2 years = 0.04) but in those under 2 years, it was comparable with dipstick testing (LR− 0.31 for dipstick vs. 0.27 for microscopy) [101].

A meta-analysis of eighteen papers by Coulthard examining age-related performance of nitrite testing [102] found that every study showed lower mean sensitivity of nitrite in UTI for children < 2 years old, with significantly poorer pooled sensitivity values of 0.38 vs. 0.72 for those >2 years old. The included RCTs showed an even more marked difference when analysed separately (0.23 vs. 0.81). There was no clinically significant impact of age on nitrite specificity. A separate meta-analysis found no difference in the sensitivity of combined dipstick testing in those above and below 2 years of age, noting significant heterogeneity between the sources within each age group [103].

In additional work, sensitivity/specificity in patients aged 0–2 years was 87.5%/39.7% vs. 100%/39.7% in those 2–10 years old, with a negative predictive value of 100% [96]. Given the 100% sensitivity, this suggests UTI can be adequately excluded in children 2–10 years with negative combined testing.

A further study reports that combined nitrite and LE urinalysis shows sensitivity increasing as patient age increases, from 75% in less than 2 months to 83.5% in those over 2 years, with specificity decreasing from 90.3 to 75.1%, respectively [5]. Likewise, a separate paper showed an increase in sensitivity from 69% in infants < 90 days old to 88% in those older than 90 days [97].

Blood

Haematuria is strongly associated with UTI, independent of LE and nitrite [4, 104]. However, haematuria cannot be used to rule in or rule out UTI, with a meta-analysis reporting an estimated sensitivity of 53.3% and specificity of around 85% [34].

Some bacterial peroxidases may cause false-positive results for blood where no haemoglobin is present in the urine [105]. Dipstick results positive for blood are also associated with higher likelihood of the sample growing contaminants when cultured [4, 105].

Microscopy

Microscopy of a urine sample in the context of infection can provide information about the presence of bacteriuria and pyuria. In isolation, bacteriuria is superior to pyuria in ruling in and out UTI (LR+/LR− of 14.7/0.19 vs. 5.9/0.27, respectively) [95]. However, the best test performance comes from combining pyuria and bacteriuria with both being present giving a LR+ of UTI of 37.0 and the absence of both giving a LR− of 0.21 [95]. The meta-analysis of 39 studies by Whiting et al. noted significant variance in the quality of reporting of pyuria between studies and centres [95].

Meta-analysis of attempts to combine dipstick and microscopy testing showed such high variance in the positive and negative likelihood ratios that no overall conclusion can be drawn [95].

In a different meta-analysis, microscopy for bacteriuria post gram stain was found to be the most accurate of any dipstick or microscopy parameter with sensitivity/specificity of 91%/96%, including comparison with LE and nitrite in combination [94]. Even this as the best parameter still has a high false-negative rate of 9% [94]. The same analysis highlighted that LE dipstick performance was identical to microscopy for pyuria, while being technically much easier and faster. However, a different meta-analysis found that the LR− of absence of pyuria and bacteriuria was 0.11, vs. a LR− for LE and nitrite of 0.37, suggesting microscopy is superior to dipstick in ruling out UTI [34].

Costs

The DUTY study extensively examined the economic and clinical costs of urine testing in a primary care setting. They directly compared laboratory testing and dipstick testing, finding that for children deemed to have an intermediate risk of UTI, dipstick testing was less cost effective than laboratory-based testing, due to the greater number of children incorrectly started on antibiotics (3.3% vs. 2.3%) and the additional time and cost of dipstick testing. However, the clinical benefits and quality-adjusted life days were very similar between each strategy [98].

The greatest determinant of the economic cost of testing a urine sample in secondary care is the time spent occupying a hospital bed rather than the equipment used [106]. The costs calculated in 2020 to obtain an uncontaminated sample are as follows: catheterisation £49.39, SPA £51.84, stimulated void £52.25, clean catch £64.82 and urine bag £112.28 [106]. This reflects a lower likelihood of contamination resulting in less repeated testing and more rapid sample collection requiring less time in the hospital.

As with any cost analysis, the expense of over-investigation (estimated 2011 cost of an ultrasound scan being £50 and micturating cystourethrogram (MCUG) being £137) is offset against reduction in long-term clinical and economic costs of under-investigation (dialysis costing £21,655 a year) [98]. The DUTY study found that while more sensitive urine sampling strategies identify a higher proportion of vesicoureteric reflux (VUR) initially, the benefits are not significant at a population level given the moderate effectiveness of treatment for (VUR) and the low likelihood that kidney scarring progresses to kidney failure [98]. The best approach was to carefully select the children for whom a sample would be sent, with the study providing a model to support this decision, which performed superiorly compared with clinical judgement and gave a net benefit of £0.42 per patient with marginally better short- and long-term outcomes [98].

Conclusion

Diagnosis of UTI requires an uncontaminated urine sample for microscopy and culture. This is challenging in non-toilet-trained children and several approaches exist. No methodology is perfect but we recommend clean catch sampling, in combination with techniques to stimulate voiding and perineal cleaning, as this canprovide rapid, non-invasive urine samples that can be sent for microscopy and culture. The contamination rate of clean catch sampling compares well to invasive catheterisation and outperforms pad and bag sampling.

In a primary care setting, clean catch sampling as guided by parent-reported symptoms, physical examination and dipstick testing is a cost-effective and appropriate approach for clinical decision-making.

In secondary care, the major cost of diagnosing UTI is the time spent in hospital obtaining a sample. There is potential for this period to be reduced through the increased use of voiding stimulation techniques.

When invasive collection is required in an unwell child or when non-invasive methods are unsuccessful, catheter samples show higher levels of contamination than suprapubic aspiration but are better tolerated by patients and families.

Once a sample is obtained, urine dipstick testing can be used in children over 3 months old and positive or negative results for both leucocyte esterase and nitrite on testing should be used to rule in and out a UTI, respectively. A negative urinary nitrite alone should not be used to exclude UTI in children less than 2 years old while a positive nitrite in any child is very strongly supportive of UTI.

Microscopy for pyuria and bacteriuria performs better than dipstick in ruling out UTI in children overall, but is comparable with dipstick testing in those under 2 years of age, performing sufficiently well to exclude UTI however urine has been collected. This is significant in that bag, pad or clean catch samples can be dipped and children with negative results excluded from further investigation, as supported by a key meta-analysis by Whiting et al. Although microscopy performs well, it is not offered by all laboratories nor generally available at the point of care.

However, it should be noted that there is significant variation in the results of the sources referenced in this review which examine the performance of all aspects of urine testing. We have made our recommendations on the best evidence available. There is a need for more tightly controlled and highly powered research, such as the DUTY study, examining the relative performance of collection methods and urine analysis to help address this.

The main message to take away from this review is that clinicians practicing within paediatrics should balance the risk of sample contamination, patient age, ease of sampling and acceptability to patients in selecting their collection method. Although pad and bag samples can be dipstick tested to exclude children from further investigations, sending possibly contaminated urine samples results in more invasive testing for children without UTI. We therefore recommend clean catch sampling following perineal cleaning and with the use of voiding stimulation techniques as representing an evidence backed, diagnostically accurate and acceptable choice in most cases.

Change history

• 23 November 2020

  A Correction to this paper has been published: https://doi.org/10.1007/s00467-020-04824-9

References

1. O’Brien K, Edwards A, Hood K, Butler CC (2013) Prevalence of urinary tract infection in acutely unwell children in general practice: a prospective study with systematic urine sampling. Br J Gen Pract 63:e156–e164

   PubMed  PubMed Central  Google Scholar 

2. Shaikh N, Morone NE, Bost JE, Farrell MH (2008) Prevalence of urinary tract infection in childhood: a meta-analysis. Pediatr Infect Dis J 27:302–308

   PubMed  Google Scholar 

3. Newman TB, Bernzweig JA, Takayama JI, Finch SA, Wasserman RC, Pantell RH (2002) Urine testing and urinary tract infections in febrile infants seen in office settings: the Pediatric Research in Office Settings’ Febrile Infant Study. Arch Pediatr Adolesc Med 156:44–54

   PubMed  Google Scholar 

4. Hay AD, Birnie K, Busby J, Delaney B, Downing H, Dudley J, Durbaba S, Fletcher M, Harman K, Hollingworth W, Hood K, Howe R, Lawton M, Lisles C, Little P, MacGowan A, O’Brien K, Pickles T, Rumsby K, Sterne JAC, Thomas-Jones E, van der Voort J, Waldron C-A, Whiting P, Wootton M, Butler CC, DUTY team (2016) The Diagnosis of Urinary Tract infection in Young children (DUTY): a diagnostic prospective observational study to derive and validate a clinical algorithm for the diagnosis of urinary tract infection in children presenting to primary care with an acute illness. Health Technol Assess 20:1–294

   PubMed  PubMed Central  Google Scholar 

5. Kazi BA, Buffone GJ, Revell PA, Chandramohan L, Dowlin MD, Cruz AT (2013) Performance characteristics of urinalyses for the diagnosis of pediatric urinary tract infection. Am J Emerg Med 31:1405–1407

   PubMed  Google Scholar 

6. Shaikh N, Ewing AL, Bhatnagar S, Hoberman A (2010) Risk of renal scarring in children with a first urinary tract infection: a systematic review. Pediatrics 126:1084–1091

   PubMed  Google Scholar 

7. Hooman N, Isa-Tafreshi R, Mostafavi S-H, Hallaji F, Tavasoli A, Otukesh H (2017) The prevalence of hypertension in children with renal scars. Minerva Pediatr 69:200–205

   PubMed  Google Scholar 

8. Shaikh N, Haralam MA, Kurs-Lasky M, Hoberman A (2019) Association of renal scarring with number of febrile urinary tract infections in children. JAMA Pediatr. https://doi.org/10.1001/jamapediatrics.2019.2504

9. Oh MM, Kim JW, Park MG, Kim JJ, Yoo KH, Moon DG (2012) The impact of therapeutic delay time on acute scintigraphic lesion and ultimate scar formation in children with first febrile UTI. Eur J Pediatr 171:565–570

   PubMed  Google Scholar 

10. Hiraoka M, Hashimoto G, Tsuchida S, Tsukahara H, Ohshima Y, Mayumi M (2003) Early treatment of urinary infection prevents renal damage on cortical scintigraphy. Pediatr Nephrol 18:115–118

    PubMed  Google Scholar 

11. NICE (2007) Urinary tract infection in under 16s: diagnosis and management

12. Subcommittee on Urinary Tract Infection, Steering Committee on Quality Improvement and Management, Roberts KB (2011) Urinary tract infection: clinical practice guideline for the diagnosis and management of the initial UTI in febrile infants and children 2 to 24 months. Pediatrics 128:595–610

    Google Scholar 

13. Stein R, Dogan HS, Hoebeke P, Kočvara R, RJM N, Radmayr C, Tekgül S, European Association of Urology, European Society for Pediatric Urology (2015) Urinary tract infections in children: EAU/ESPU guidelines. Eur Urol 67:546–558

    PubMed  Google Scholar 

14. Desai DJ, Gilbert B, McBride CA (2016) Paediatric urinary tract infections: diagnosis and treatment. Aust Fam Physician 45:558–563

    PubMed  Google Scholar 

15. Starship Child Health (2020) Clinical guideline- urinary tract infection. https://www.starship.org.nz/guidelines/urinary-tract-infection/. Accessed 6 Jun 2020

16. Robinson JL, Finlay JC, Lang ME, Bortolussi R (2014) Urinary tract infections in infants and children: diagnosis and management. Paediatr Child Health 19:315–319

    PubMed  PubMed Central  Google Scholar 

17. Ammenti A, Alberici I, Brugnara M, Chimenz R, Guarino S, La Manna A, La Scola C, Maringhini S, Marra G, Materassi M, Morello W, Nicolini G, Pennesi M, Pisanello L, Pugliese F, Scozzola F, Sica F, Toffolo A, Montini G, Italian Society of Pediatric Nephrology (2020) Updated Italian recommendations for the diagnosis, treatment and follow-up of the first febrile urinary tract infection in young children. Acta Paediatr 109:236–247

    PubMed  Google Scholar 

18. Israeli Medical Association- Guideline Section (2014) Diagnosis and treatment of first infection of the urinary tract in children

19. The Royal Children’s Hospital Melbourne (2019) Clinical practice guidelines- urinary tract infection. https://www.rch.org.au/clinicalguide/guideline_index/Urinary_Tract_Infection_Guideline/#Notes. Accessed 9 Jun 2020

20. Karacan C, Erkek N, Senel S, Akin Gunduz S, Catli G, Tavil B (2010) Evaluation of urine collection methods for the diagnosis of urinary tract infection in children. Med Princ Pract 19:188–191

    PubMed  Google Scholar 

21. Ho IVA, Lee CH, Fry M (2014) A prospective comparative pilot study comparing the urine collection pad with clean catch urine technique in non-toilet-trained children. Int Emerg Nurs 22:94–97

    PubMed  Google Scholar 

22. Alam MT, Coulter JBS, Pacheco J, Correia JB, Ribeiro MGB, Coelho MFC, Bunn JEG (2005) Comparison of urine contamination rates using three different methods of collection: clean-catch, cotton wool pad and urine bag. Ann Trop Paediatr 25:29–34

    CAS  PubMed  Google Scholar 

23. Tosif S, Baker A, Oakley E, Donath S, Babl FE (2012) Contamination rates of different urine collection methods for the diagnosis of urinary tract infections in young children: an observational cohort study. J Paediatr Child Health 48:659–664

    PubMed  Google Scholar 

24. Macfarlane PI, Houghton C, Hughes C (1999) Pad urine collection for early childhood urinary-tract infection. Lancet 354:571

    CAS  PubMed  Google Scholar 

25. Teo S, Cheek JA, Craig S (2016) Improving clean-catch contamination rates: a prospective interventional cohort study. Emerg Med Australas 28:698–703

    PubMed  Google Scholar 

26. Liaw LC, Nayar DM, Pedler SJ, Coulthard MG (2000) Home collection of urine for culture from infants by three methods: survey of parents’ preferences and bacterial contamination rates. BMJ 320:1312–1313

    CAS  PubMed  PubMed Central  Google Scholar 

27. Li PS, Ma LC, Wong SN (2002) Is bag urine culture useful in monitoring urinary tract infection in infants? J Paediatr Child Health 38:377–381

    CAS  PubMed  Google Scholar 

28. Tosif S, Kaufman J, Fitzpatrick P, Hopper SM, Hoq M, Donath S, Babl FE (2017) Clean catch urine collection: time taken and diagnostic implication. A prospective observational study. J Paediatr Child Health 53:970–975

    PubMed  Google Scholar 

29. Al-Orifi F, McGillivray D, Tange S, Kramer MS (2000) Urine culture from bag specimens in young children: are the risks too high? J Pediatr 137:221–226

    CAS  PubMed  Google Scholar 

30. Herreros ML, Tagarro A, García-Pose A, Sánchez A, Cañete A, Gili P (2018) Performing a urine dipstick test with a clean-catch urine sample is an accurate screening method for urinary tract infections in young infants. Acta Paediatr 107:145–150

    CAS  PubMed  Google Scholar 

31. Altuntas N, Tayfur AC, Kocak M, Razi HC, Akkurt S (2015) Midstream clean-catch urine collection in newborns: a randomized controlled study. Eur J Pediatr 174:577–582

    PubMed  Google Scholar 

32. Herreros ML, Tagarro A, García-Pose A, Sánchez A, Cañete A, Gili P (2015) Accuracy of a new clean-catch technique for diagnosis of urinary tract infection in infants younger than 90 days of age. Paediatr Child Health 20:e30–e32

    PubMed  PubMed Central  Google Scholar 

33. Jacob R, John-Denny B, Donaldson K, White B, Outhred A, McCaskill ME (2019) Educational intervention does not reduce non-invasive urine contamination rates in children presenting to the emergency department. J Paediatr Child Health. https://doi.org/10.1111/jpc.14542

34. Whiting P, Westwood M, Bojke L, Palmer S, Richardson G, Cooper J, Watt I, Glanville J, Sculpher M, Kleijnen J (2006) Clinical effectiveness and cost-effectiveness of tests for the diagnosis and investigation of urinary tract infection in children: a systematic review and economic model. Health Technol Assess 10:iii–iv, xi–xiii, 1–iii–iv, xi–xiii154

    Google Scholar 

35. Ramage IJ, Chapman JP, Hollman AS, Elabassi M, McColl JH, Beattie TJ (1999) Accuracy of clean-catch urine collection in infancy. J Pediatr 135:765–767

    CAS  PubMed  Google Scholar 

36. Harari M (2020) Investigation into clean catch urine collection. Personal Communication

37. Butler CC, Sterne JA, Lawton M, O’Brien K, Wootton M, Hood K, Hollingworth W, Little P, Delaney BC, van der Voort J, Dudley J, Birnie K, Pickles T, Waldron C-A, Downing H, Thomas-Jones E, Lisles C, Rumsby K, Durbaba S, Whiting P, Harman K, Howe R, MacGowan A, Fletcher M, Hay AD (2016) Nappy pad urine samples for investigation and treatment of UTI in young children: the “DUTY” prospective diagnostic cohort study. Br J Gen Pract 66:e516–e524

    PubMed  PubMed Central  Google Scholar 

38. Vaillancourt S, McGillivray D, Zhang X, Kramer MS (2007) To clean or not to clean: effect on contamination rates in midstream urine collections in toilet-trained children. Pediatrics 119:e1288–e1293

    PubMed  Google Scholar 

39. Saez-Llorens X, Umana MA, Odio CM, Lohr JA (1989) Bacterial contamination rates for non-clean-catch and clean-catch midstream urine collections in uncircumcised boys. J Pediatr 114:93–95

    CAS  PubMed  Google Scholar 

40. LaRocco MT, Franek J, Leibach EK, Weissfeld AS, Kraft CS, Sautter RL, Baselski V, Rodahl D, Peterson EJ, Cornish NE (2016) Effectiveness of preanalytic practices on contamination and diagnostic accuracy of urine cultures: a laboratory medicine best practices systematic review and meta-analysis. Clin Microbiol Rev 29:105–147

    PubMed  Google Scholar 

41. Hadjipanayis A, Grossman Z, Del Torso S (2015) Current primary care management of children aged 1–36 months with urinary tract infections in Europe: large scale survey of paediatric practice. Arch Dis Child 100:341–347

    PubMed  Google Scholar 

42. Lamy C, Loizeau V, Couquet C, Sturtzer C, Fluteau C, Dugas M, Labrunie A, Marin B, Desfougères J-L, Bahans C, Guigonis V, Beloni P (2019) Pain experienced by infants and toddlers at urine collection bag removal: a randomized, controlled, clinical trial. Int J Nurs Stud 95:1–6

    PubMed  Google Scholar 

43. Cousin E, Ryckewaert A, de Jorna Lecouvey C, Arnaud AP (2019) Urine collection methods used for non-toilet-trained children in pediatric emergency departments in France: a medical practice analysis. Arch Pediatr 26:16–20

    CAS  PubMed  Google Scholar 

44. May OW (2018) Urine collection methods in children: which is the best? Nurs Clin North Am 53:137–143

    PubMed  Google Scholar 

45. Etoubleau C, Reveret M, Brouet D, Badier I, Brosset P, Fourcade L, Bahans C, Garnier F, Blanc P, Guigonis V (2009) Moving from bag to catheter for urine collection in non-toilet-trained children suspected of having urinary tract infection: a paired comparison of urine cultures. J Pediatr 154:803–806

    PubMed  Google Scholar 

46. Kim G-A, Koo J-W (2015) Validity of bag urine culture for predicting urinary tract infections in febrile infants: a paired comparison of urine collection methods. Korean J Pediatr 58:183

    CAS  PubMed  PubMed Central  Google Scholar 

47. Rao S (2004) An improved urine collection pad method: a randomised clinical trial. Arch Dis Child 89:773–775

    CAS  PubMed  PubMed Central  Google Scholar 

48. Macfarlane PI, Ellis R, Hughes C, Houghton C, Lord R (2005) Urine collection pads: are samples reliable for urine biochemistry and microscopy? Pediatr Nephrol 20:170–179

    PubMed  Google Scholar 

49. Ahmad T, Vickers D, Campbell S, Coulthard MG, Pedler S (1991) Urine collection from disposable nappies. Lancet 338:674–676

    CAS  PubMed  Google Scholar 

50. Vernon S, Redfearn A, Pedler SJ, Lambert HJ, Coulthard MG (1994) Urine collection on sanitary towels. Lancet 344:612

    CAS  PubMed  Google Scholar 

51. Feasey S (1999) Are Newcastle urine collection pads suitable as a means of collecting specimens from infants? Paediatr Nurs 11:17–21

    CAS  PubMed  Google Scholar 

52. Ross SA, Ahmed A, Palmer AL, Michaels MG, Sánchez PJ, Stewart A, Bernstein DI, Feja K, Novak Z, Fowler KB, Boppana SB, National Institute on Deafness and Other Communication Disorders CHIMES Study (2015) Urine collection method for the diagnosis of congenital cytomegalovirus infection. Pediatr Infect Dis J 34:903–905

    PubMed  PubMed Central  Google Scholar 

53. Rao S (2003) A new urine collection method; pad and moisture sensitive alarm. Arch Dis Child 88:836–836

    CAS  PubMed  PubMed Central  Google Scholar 

54. Crofton PM, Squires N, Davidson DF, Henderson P, Taheri S (2008) Reliability of urine collection pads for routine and metabolic biochemistry in infants and young children. Eur J Pediatr 167:1313–1319

    CAS  PubMed  Google Scholar 

55. Mock DM (1992) Rayon balls and disposable-diaper material selectively adsorb creatinine. Am J Clin Nutr 55:326–330

    CAS  PubMed  Google Scholar 

56. Smith GC, Taylor CM (1992) Recovery of protein from urine specimens collected in cotton wool. Arch Dis Child 67:1486–1487

    CAS  PubMed  PubMed Central  Google Scholar 

57. Peniakov M, Antonelli J, Naor O, Miron D (2004) Reduction in contamination of urine samples obtained by in-out catheterization by culturing the later urine stream. Pediatr Emerg Care 20:418–419

    CAS  PubMed  Google Scholar 

58. Pryles CV, Atkin MD, Morse TS, Welch KJ (1959) Comparative bacteriologic study of urine obtained from children by percutaneous suprapubic aspiration of the bladder and by catheter. Pediatrics 24:983–991

    CAS  PubMed  Google Scholar 

59. Kramer MS, Tange SM, Drummond KN, Mills EL (1994) Urine testing in young febrile children: a risk-benefit analysis. J Pediatr 125:6–13

    CAS  PubMed  Google Scholar 

60. Bonadio WA (1987) Urine culturing technique in febrile infants. Pediatr Emerg Care 3:75–78

    CAS  PubMed  Google Scholar 

61. Eliacik K, Kanik A, Yavascan O, Alparslan C, Kocyigit C, Aksu N, Bakiler AR (2016) A comparison of bladder catheterization and suprapubic aspiration methods for urine sample collection from infants with a suspected urinary tract infection. Clin Pediatr 55:819–824

    Google Scholar 

62. Pollack CV Jr, Pollack ES, Andrew ME (1994) Suprapubic bladder aspiration versus urethral catheterization in ill infants: success, efficiency and complication rates. Ann Emerg Med 23:225–230

    PubMed  Google Scholar 

63. Tobiansky R, Evans N (1998) A randomized controlled trial of two methods for collection of sterile urine in neonates. J Paediatr Child Health 34:460–462

    CAS  PubMed  Google Scholar 

64. Kozer E, Rosenbloom E, Goldman D, Lavy G, Rosenfeld N, Goldman M (2006) Pain in infants who are younger than 2 months during suprapubic aspiration and transurethral bladder catheterization: a randomized, controlled study. Pediatrics 118:e51–e56

    PubMed  Google Scholar 

65. Hockberger RS, Schwartz B, Connor J (1987) Hematuria induced by urethral catheterization. Ann Emerg Med 16:550–552

    CAS  PubMed  Google Scholar 

66. Schroeder AR, Newman TB, Wasserman RC, Finch SA, Pantell RH (2005) Choice of urine collection methods for the diagnosis of urinary tract infection in young, febrile infants. Arch Pediatr Adolesc Med 159:915–922

    PubMed  Google Scholar 

67. Pohl HG, Bauer SB, Borer JG, Diamond DA, Kelly MD, Grant R, Briscoe CJ, Doonan G, Retik AB (2002) The outcome of voiding dysfunction managed with clean intermittent catheterization in neurologically and anatomically normal children. BJU Int 89:923–927

    CAS  PubMed  Google Scholar 

68. Van Savage JG, Sackett CK, Wilhelm CL, Sessions RP, Mesrobian HG (1997) Indications for and outcomes of clean intermittent catheterization in children with normal genital sensation. J Urol 157:1866–1868

    PubMed  Google Scholar 

69. Fox H, Gupta M (2017) G375(P) Analysis of doctors and nurses confidence with the use of in and out urinary catheters for collection of urine samples. British Association of General Paediatrics and Paediatric Education Special Interest Group

70. Ozkan B, Kaya O, Akdağ R, Unal O, Kaya D (2000) Suprapubic bladder aspiration with or without ultrasound guidance. Clin Pediatr 39:625–626

    CAS  Google Scholar 

71. Gochman RF, Karasic RB, Heller MB (1991) Use of portable ultrasound to assist urine collection by suprapubic aspiration. Ann Emerg Med 20:631–635

    CAS  PubMed  Google Scholar 

72. O’Callaghan C, McDougall PN (1987) Successful suprapubic aspiration of urine. Arch Dis Child 62:1072–1073

    PubMed  PubMed Central  Google Scholar 

73. Kiernan SC, Pinckert TL, Keszler M (1993) Ultrasound guidance of suprapubic bladder aspiration in neonates. J Pediatr 123:789–791

    CAS  PubMed  Google Scholar 

74. Chu R-P, Wong Y-C, Luk S-H, Wong S-N (2007) Comparing suprapubic urine aspiration under real-time ultrasound guidance with conventional blind aspiration. Acta Paediatr 91:512–516

    Google Scholar 

75. Ugarte JM, Hidalgo C, Ruiz M (1986) Contribution of ultrasound to the results of suprapubic vesical puncture in infants and newborn infants. Rev Chil Pediatr 57:252–255

    CAS  PubMed  Google Scholar 

76. Hildebrand WL, Schreiner RL, Stevens DC, Gosling CG, Sternecker CL (1981) Suprapubic bladder aspiration in infants. Am Fam Physician 23:115–118

    CAS  PubMed  Google Scholar 

77. McTaggart S, Danchin M, Ditchfield M, Hewitt I, Kausman J, Kennedy S, Trnka P, Williams G, Kidney Health Australia - Caring for Australasians with Renal Impairment (2015) KHA-CARI guideline: diagnosis and treatment of urinary tract infection in children. Nephrology 20:55–60

    PubMed  Google Scholar 

78. Public Health England (2019) Investigation of urine. UK Standards for Microbiology Investigations

79. Herreros Fernández ML, González Merino N, Tagarro García A, Pérez Seoane B, de la Serna Martínez M, Contreras Abad MT, García-Pose A (2013) A new technique for fast and safe collection of urine in newborns. Arch Dis Child 98:27–29

    PubMed  Google Scholar 

80. Kumar R, Rudrappa S (2019) Mid-stream clean catch urine collection in newborns: a non-invasive and safe technique. International Journal of Contemporary Pediatrics 6:349–351

    Google Scholar 

81. Labrosse M, Levy A, Autmizguine J, Gravel J (2016) Evaluation of a new strategy for clean-catch urine in infants. Pediatrics 138:e20160573. https://doi.org/10.1542/peds.2016-0573

    Article  PubMed  Google Scholar 

82. Valleix-Leclerc M, Bahans C, Tahir A, Faubert S, Fargeot A, Abouchi S, Dallocchio A, Mussgnug M, Guigonis V (2016) Prospective evaluation of a cutaneous stimulation technique to induce on-demand urination in non-toilet-trained infants. Arch Pediatr 23:815–819

    CAS  PubMed  Google Scholar 

83. Kaufman J, Fitzpatrick P, Tosif S, Hopper SM, Donath SM, Bryant PA, Babl FE (2017) Faster clean catch urine collection (Quick-Wee method) from infants: randomised controlled trial. BMJ 357:j1341

    PubMed  PubMed Central  Google Scholar 

84. Weill O, Labrosse M, Levy A, Desjardins MP, Trottier ED, Gravel J (2019) Point-of-care ultrasound before attempting clean-catch urine collection in infants: a randomized controlled trial. CJEM 21:646–652

    PubMed  Google Scholar 

85. Tsai J-D, Lin C-C, Yang SS (2016) Diagnosis of pediatric urinary tract infections. Urological Science 27:131–134

    Google Scholar 

86. Price E, Pallett A, Gilbert RD, Williams C (2010) Microbiological aspects of the UK National Institute for Health and Clinical Excellence (NICE) guidance on urinary tract infection in children. J Antimicrob Chemother 65:836–841

    CAS  PubMed  Google Scholar 

87. Midthun S, Paur R, Bruce AW (2003) Pyuria detection using a dipstick applied to urine in incontinence pads. Urol Nurs 23(430–5):437

    Google Scholar 

88. Shaikh N, Osio VA, Wessel CB, Jeong JH (2020) Prevalence of asymptomatic bacteriuria in children: a meta-analysis. J Pediatr 217:110–117.e4

    CAS  PubMed  Google Scholar 

89. Powell HR, McCredie DA, Ritchie MA (1987) Urinary nitrite in symptomatic and asymptomatic urinary infection. Arch Dis Child 62:138–140

    CAS  PubMed  PubMed Central  Google Scholar 

90. Birnie K, Hay AD, Wootton M, Howe R, MacGowan A, Whiting P, Lawton M, Delaney B, Downing H, Dudley J, Hollingworth W, Lisles C, Little P, O’Brien K, Pickles T, Rumsby K, Thomas-Jones E, Van der Voort J, Waldron C-A, Harman K, Hood K, Butler CC, Sterne JAC (2017) Comparison of microbiological diagnosis of urinary tract infection in young children by routine health service laboratories and a research laboratory: diagnostic cohort study. PLoS One 12:e0171113

    PubMed  PubMed Central  Google Scholar 

91. Bednar C, Kies C (1994) Nitrate and vitamin C from fruits and vegetables: impact of intake variations on nitrate and nitrite excretions of humans. Plant Foods Hum Nutr 45:71–80

    CAS  PubMed  Google Scholar 

92. James GP, Paul KL, Fuller JB (1978) Urinary nitrite and urinary-tract infection. Am J Clin Pathol 70:671–678

    CAS  PubMed  Google Scholar 

93. Midthun S, Bruce AW (2006) Are true-negative nitrite results affected by a two-hour delay in dipstick/pad analysis of urine in incontinence pads? J Wound Ostomy Continence Nurs 33:292–295

    PubMed  Google Scholar 

94. Williams GJ, Macaskill P, Chan SF, Turner RM, Hodson E, Craig JC (2010) Absolute and relative accuracy of rapid urine tests for urinary tract infection in children: a meta-analysis. Lancet Infect Dis 10:240–250

    PubMed  Google Scholar 

95. Whiting P, Westwood M, Watt I, Cooper J, Kleijnen J (2005) Rapid tests and urine sampling techniques for the diagnosis of urinary tract infection (UTI) in children under five years: a systematic review. BMC Pediatr 5:4

    PubMed  PubMed Central  Google Scholar 

96. Doley A, Nelligan M (2003) Is a negative dipstick urinalysis good enough to exclude urinary tract infection in paediatric emergency department patients? Emerg Med 15:77–80

    Google Scholar 

97. McGillivray D, Mok E, Mulrooney E, Kramer MS (2005) A head-to-head comparison: “clean-void” bag versus catheter urinalysis in the diagnosis of urinary tract infection in young children. J Pediatr 147:451–456

    PubMed  Google Scholar 

98. Hollingworth W, Busby J, Butler CC, O’Brien K, Sterne JAC, Hood K, Little P, Lawton M, Birnie K, Thomas-Jones E, Harman K, Hay AD (2017) The diagnosis of urinary tract infection in young children (DUTY) study clinical rule: economic evaluation. Value Health 20:556–566

    PubMed  PubMed Central  Google Scholar 

99. Sharief N, Hameed M, Petts D (1998) Use of rapid dipstick tests to exclude urinary tract infection in children. Br J Biomed Sci 55:242

    CAS  PubMed  Google Scholar 

100. Shaw KN, Hexter D, McGowan KL, Schwartz JS (1991) Clinical evaluation of a rapid screening test for urinary tract infections in children. J Pediatr 118:733–736

     CAS  PubMed  Google Scholar 

101. Mori R, Yonemoto N, Fitzgerald A, Tullus K, Verrier-Jones K, Lakhanpaul M (2010) Diagnostic performance of urine dipstick testing in children with suspected UTI: a systematic review of relationship with age and comparison with microscopy. Acta Paediatr 99:581–584

     CAS  PubMed  Google Scholar 

102. Coulthard MG (2019) Using urine nitrite sticks to test for urinary tract infection in children aged< 2 years: a meta-analysis. Pediatr Nephrol 34:1283–1288

     PubMed  PubMed Central  Google Scholar 

103. Gorelick MH, Shaw KN (1999) Screening tests for urinary tract infection in children: a meta-analysis. Pediatrics 104:e54

     CAS  PubMed  Google Scholar 

104. Anderson J, Fawcett D, Feehally J, Goldberg L, Kelly MJ, MacTier R; Sussex Kidney Unit (2008) Joint consensus statement on the initial assessment of haematuria. BAUS/RA Guidelines 2008:1–5

105. Lam MH (1995) False “hematuria” due to bacteriuria. Arch Pathol Lab Med 119:717–721

     CAS  PubMed  Google Scholar 

106. Kaufman J, Knight AJ, Bryant PA, Babl FE, Dalziel K (2020) Liquid gold: the cost-effectiveness of urine sample collection methods for young precontinent children. Arch Dis Child 105:253–259

     PubMed  Google Scholar 

Download references

Author information

Authors and Affiliations

1. Department of Paediatrics, Whittington Hospital, London, UK

   James Diviney & Mervyn S. Jaswon

2. Azrieli Faculty of Medicine, Bar-Ilan University, Safed, Israel

   Mervyn S. Jaswon

Authors

1. James Diviney

   You can also search for this author in PubMed Google Scholar

2. Mervyn S. Jaswon

   You can also search for this author in PubMed Google Scholar

Corresponding author

Correspondence to James Diviney.

Ethics declarations

Conflict of interest

The authors declare that they have no conflict of interest.

Additional information

Publisher’s note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

The original online version of this article was revised: the initial version of this article unfortunately contained a mistake. The catheterisation cost cited in the paper was corrected to £49.39 instead of the previously cited cost of £25.98.

Rights and permissions

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

Reprints and Permissions

About this article

Cite this article

Diviney, J., Jaswon, M.S. Urine collection methods and dipstick testing in non-toilet-trained children. Pediatr Nephrol 36, 1697–1708 (2021). https://doi.org/10.1007/s00467-020-04742-w

Download citation

• Received: 23 April 2020

• Revised: 03 July 2020

• Accepted: 16 July 2020

• Published: 12 September 2020

• Issue Date: July 2021

• DOI: https://doi.org/10.1007/s00467-020-04742-w

Keywords

• UTI
• Urinary tract infection
• Urine sampling
• Clean catch
• In-out catheterisation
• Suprapubic aspiration
• Dipstick testing

What is the best method of collecting urine for a culture and sensitivity?

What is a clean catch method of collecting urine from a patient?

Which urine collection technique is typically used for a urine culture?