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The rapid detection of respiratory pathogens in critically ill children
Critical Care volume 27, Article number: 11 (2023)
Abstract
Purpose
Respiratory infections are the most common reason for admission to paediatric intensive care units (PICU). Most patients with lower respiratory tract infection (LRTI) receive broad-spectrum antimicrobials, despite low rates of bacterial culture confirmation. Here, we evaluated a molecular diagnostic test for LRTI to inform the better use of antimicrobials.
Methods
The Rapid Assay for Sick Children with Acute Lung infection Study was a single-centre, prospective, observational cohort study of mechanically ventilated children (> 37/40 weeks corrected gestation to 18 years) with suspected community acquired or ventilator-associated LRTI. We evaluated the use of a 52-pathogen custom TaqMan Array Card (TAC) to identify pathogens in non-bronchoscopic bronchoalveolar lavage (mini-BAL) samples. TAC results were compared to routine microbiology testing. Primary study outcomes were sensitivity and specificity of TAC, and time to result.
Results
We enrolled 100 patients, all of whom were tested with TAC and 91 of whom had matching culture samples. TAC had a sensitivity of 89.5% (95% confidence interval (CI95) 66.9–98.7) and specificity of 97.9% (CI95 97.2–98.5) compared to routine bacterial and fungal culture. TAC took a median 25.8 h (IQR 9.1–29.8 h) from sample collection to result. Culture was significantly slower: median 110.4 h (IQR 85.2–141.6 h) for a positive result and median 69.4 h (IQR 52.8–78.6) for a negative result.
Conclusions
TAC is a reliable and rapid adjunct diagnostic approach for LRTI in critically ill children, with the potential to aid early rationalisation of antimicrobial therapy.
Introduction
Respiratory tract infections are the leading cause of admission onto paediatric intensive care units (PICUs). In 2019, 6174 were children admitted to UK PICUs with a primary respiratory illness [1]. At a cost of ≥ £3,713 per occupied bed day in a PICU, these cases constitute a significant burden to the National Health Service (NHS) [2]. With such severe disease presentations, PICU clinicians generally initiate early broad-spectrum antimicrobial therapy [3], which may affect routine microbiological culture results [4, 5]. Most children are likely to have viral infections, but two factors are key in the de-escalation of antimicrobial therapy in this cohort—lack of rapid diagnostic tests to determine bacterial co-infection and a low prevalence of positive respiratory cultures.
Quantitative PCR (qPCR) has been used for many years to identify respiratory viruses in nasopharyngeal swabs or aspirates for children. A recent study of critically ill adults with suspected lower respiratory tract infection (LRTI) found that the use of a qPCR-based rapid pathogen array reduced the use of inappropriate antimicrobial therapy compared to standard diagnostic microbiology [6]. The potential for respiratory pathogen qPCR arrays to detect bacterial and fungal respiratory pathogens in hospitalised children has been discussed, but the outcome of their clinical implementation is yet to be reported [7, 8].
The TaqMan Array Card (TAC) (Thermo Fisher Scientific, California) [9] is a microfluidic qPCR system which is comprised of 384 wells containing prealiquoted customised primer and probe combinations [9]. We have previously reported the use of a custom TAC to support ventilator-associated pneumonia (VAP) diagnosis in adults [10, 11]. Here we sought to assess the utility of this TAC to identify bacterial and fungal respiratory pathogens in critically ill children with suspected community acquired pneumonia (CAP) or VAP.
The primary objectives of this study were to determine the sensitivity and specificity of TAC to detect bacterial and fungal pathogens causing LRTI, and to compare time to result of TAC versus standard microbiology cultures. The secondary objectives of the study were to describe the micro-organisms detected by TAC that were not detected using microbiology culture; assess the impact of TAC on total antimicrobial prescriptions in the PICU; and describe the impact of TAC on antimicrobial decision-making according to PICU consultants.
Methods
Study design
The Rapid Assay for Sick Children with Acute Lung infection Study (RASCALS) was a single-centre prospective observational cohort study of children admitted to PICU conducted in a 13-bed general PICU in the East of England as previously described [12].
Enrolment and consent procedures
Children ≤ 18 years of age were eligible for inclusion if they were mechanically ventilated and had commenced or were commencing antimicrobial therapy for LRTI. Children aged < 37 weeks corrected gestation were excluded in addition to those predicted to have non-survivable illness. Premature infants were not included given safety, and adequacy of the sampling procedure requires further assessment in this group. Screening for eligibility was carried out by clinical staff based on the defined criteria. Patients were enrolled consecutively on weekdays based on availability of laboratory staff for sample processing. A deferred consent approach was taken for enrolment in the project, given the time-critical nature of investigations. Consent was obtained from carers, and children who had the capacity to give consent. Assent was obtained from children deemed to be Gillick competent.
Study procedures
Following enrolment, children received a non-bronchoscopic bronchoalveolar lavage (mini-BAL). This procedure involves instillation and re-aspiration of saline (1 mL/kg up to 10 mL) using an in-line suction catheter at the level of the carina. Despite the protocol recommending the mini-BAL method, endotracheal tube (ETT) aspirate samples were still included. Samples were divided in the microbiology laboratory into aliquots for routine microbiological testing in addition to extraction of nucleic acid (Fig. 1). Nucleic acid was extracted from samples using an EZ1 virus mini kit (v2.0) using an EZ1 advanced XL (Qiagen) machine and loaded onto TAC. The TAC was processed on a QuantStudio 7 qPCR machine (ThermoFisher) [12]. Results were reported by an experienced laboratory member and entered into the electronic medical record (EMR) (Epic Systems Corporation, Wisconsin). PICU consultants were surveyed regarding their actions following availability of these results via an email link to the electronic data capture instrument.
Test interpretation
The TAC incorporated molecular probes targeting species-level bacteria in addition to higher taxonomic groups. Sequences have previously undergone technical validation [10]. Each target was reported according to cycle threshold (Ct), which represents the number of cycles of PCR amplification that occurred before exponential increase in the fluorescent reporter signal; a positive result was inferred if a Ct ≤ 32 was recorded. This threshold was selected based on the median value of detection based on the former study in adults [10]. Cultures were reported as positive if ≥ 104 colony-forming units (CFU)/mL were isolated from mini-BAL samples, and ≥ 105 CFU/mL from ETT aspirate samples. Culture was used as the gold standard for comparison to TAC. Mini-BAL was the recommended sampling approach to avoid contamination from upper respiratory microbiota. Validation of bacterial pathogens was carried out using sequencing of the V3-V4 region of the bacterial 16S rRNA gene (16S sequencing) (Additional file 1).
Data collection
Data were recorded in an electronic research database, RedCAP, hosted by the University of Cambridge [13]. Demographic information (age at admission, admission source, diagnosis and comorbidities, days on mechanical ventilation, and duration of admission), all routine microbiology and virology investigations, antimicrobial prescription data, and Paediatric Index of Mortality 3 scores [14] were collected. Investigation results and clinical characteristics at the time of mini-BAL sample were also recorded [14]. The duration of PICU stay is reported as days-free-of-PICU 28 days following admission. The duration of treatments are reported as days-free-of-treatment 28 days following admission to PICU. These are standard composite measures that capture the impact of mortality, with days following death considered unliberated from treatment and/or admission for the purposes of the calculations [15].
Sample size
The sample size was calculated to detect a 60% increase in the sensitivity of TAC to detect bacteria in the samples compared to microbiological culture. A previous investigation on this PICU identified that the prevalence of positive respiratory cultures was 22% [5]. The power calculation determined that 85 participants were required, which was rounded to 100 to account for loss to follow-up and sample failure.
Statistical analysis
Demographic data were reported with mean and standard deviation, unless the distribution of data was skewed in which case median and interquartile range were used. As there was no ideal ‘gold standard’ test for comparison, TAC and culture results were pooled to determine overall sensitivity and specificity. To determine the sensitivity and specificity of TAC for the detection of bacterial and fungal species, we analysed 25 species on the array which are detectable with the microbiology culture techniques advised for respiratory samples [16]. Genus- or family-level targets were not included in the calculations of diagnostic performance. The detection of bacteria found only by TAC (without a positive culture) underwent secondary validation by 16S sequencing.
The time to reported TAC or microbiology culture result was measured as the time of sample collection to the documented result time in the EMR and compared using the Wilcoxon signed-rank test.
To determine impact of TAC on antimicrobial prescribing, study patients were matched to control patients with suspected LRTI admitted to the same PICU between October 2019 and February 2020 [5]. Demographic features were compared using the Mann–Whitney U test for nonparametric data and the Student’s t-test for normally distributed data. Proportions were compared using the Chi-square test for independence. Antimicrobial use was compared by the Fisher’s exact test. Graphs were generated with R studio v7.1, R version 4.2.0 using ggplot2 [17, 18] and the figures created using Biorender.com.
Antimicrobial use was reported according to the number and percentage of days of the PICU stay in which the patient was exposed to treatment. Exposure to a single dose of an antimicrobial between 00:00 and 23:59 h was one day of exposure. Given that many patients were on multiple courses of antimicrobial therapy, antimicrobial data were also reported according to an antimicrobial spectrum index (ASI). ASI is an approach that allocates a score to systemic antimicrobials according to the range of organisms for which they have therapeutic benefit [19, 20]. The ASI score was multiplied by the number of days of exposure to each antimicrobial in the PICU and summed to estimate total antimicrobial usage. Three antimicrobials used in PICU were not included in the published ASI tools: ceftolozane–tazobactam, flucloxacillin, and teicoplanin; therefore, a score was determined independently for these antimicrobials (Additional file 1: Table S1).
Results
Study population
During the study period (April 2020–January 2022), 971 children were screened for study eligibility and 100 children were enrolled (Fig. 2).
Patient characteristics
The most common primary diagnosis was respiratory illness (Table 1). This included bronchiolitis (46%), followed by pneumonia (25%), asthma/viral-induced wheeze (10%), and other respiratory illnesses (19%) including severe bronchopulmonary dysplasia, drowning, pulmonary oedema, structural airway problems, acute respiratory distress syndrome, and pneumonitis. Patients spent a mean 75% of days on the PICU (SD 27) receiving antimicrobial therapy.
Bacterial and fungal detections on TAC
One hundred respiratory samples were obtained: 91 mini-BAL and 9 ETT aspirate samples (Additional file 1). 99/100 TAC passed quality control. Bacteria were detected more frequently on TAC (56/99 (57%)) than microbiology cultures (16/91(18%)) (p < 0.001) (Additional file 1: Table S2). This were also the case for fungi, found on 17/99 (17%) of TAC compared to 2/91 (2%) (p < 0.001) of microbiology cultures.
Sensitivity and specificity of TAC
We excluded 9/100 (9%) of samples from the analysis in which microbiology culture was not obtained from the same sample as the TAC.
Positive microbiology cultures were reported in eighteen samples (Table S3). In four of these, there was a discrepancy with the TAC result. In one case, Coagulase-negative Staphylococcus was grown but not detected by TAC, although a linked detection of mecA (Ct 29) was noted. In two cases, TAC detected the organism but above our cut-off Ct of ≥ 32 (Pseudomonas aeruginosa with a Ct of 37 and an Enterococcus faecalis with a Ct of 35). The fourth was an off-panel organism, Candida dubliniensis; however, this was associated with genus-level Candida spp (Ct 23) and pan-fungal 18 s rRNA gene (Ct 24).
Using our predefined criteria, TAC sensitivity was 89.5% (CI95 66.9–98.7), with a specificity of 97.9% (CI95 97.2–98.5), a positive likelihood ratio of 43.4 (CI95 31.2–60.5), and negative likelihood ratio of 0.1 (CI95 0.0–0.4) (Additional file 1: Fig. S1).
Time to result
TAC took a median of 25.8 h (IQR 9.1–29.8 h) from sample collection to a reported result and 8.9 h (IQR 5.5–24.3 h) from laboratory registration to result (Fig. 3a). Cultures took a median 110.4 h (IQR 85.2–141.6 h) from sample collection to a reported positive result and 69.4 h (IQR 52.5–78.6 h) from sample collection to a reported negative result. Compared with microbiology culture, TAC was significantly quicker for both positive (Z = -3.593, p < 0.001) and negative results (Z = − 7.424, p < 0.001).
Positive results reported by TAC only
An additional 44 bacterial and fungal species (in 29 samples) were detected on TAC at Ct ≤ 32 (median Ct 28.0, IQR 26.0–30.8) (Fig. 3b). They included Haemophilus influenzae (n = 8), P. aeruginosa (n = 6), Moraxella catarrhalis (n = 6), Streptococcus pneumoniae (n = 6), Staphylococcus aureus (n = 4), Staphylococcus epidermidis (n = 3), Candida albicans (n = 3), Stenotrophomonas maltophilia (n = 2), and individual samples with Acinetobacter baumannii, E. faecalis, Enterococcus faecium, Enterobacter cloacae, Escherichia coli, and Klebsiella pneumoniae.
TAC identified an additional 35 bacterial species, validated using 16S sequencing, that were not identified by microbiology culture (Additional file 1: Table S4), representing a 184% relative increase in detection. The Ct value of bacterial species was lower in those that had a corresponding positive culture (Ct 22.5, IQR 20.0–27.0) in comparison with those that were culture negative and confirmed with 16S sequencing (Ct 28.0, IQR 26.0–30.0, p < 0.001). Five bacterial species were identified by TAC that were not identified by culture nor met the 16S sequencing validation criteria (median Ct 28.0, IQR 27.5–31.5).
Viral detections on TAC
Viral targets on the TAC were not formally validated against respiratory virus PCR due to reduced availability of the reference test during the COVID-19 pandemic. However, at least one viral pathogen was found on 46/99 (46%) TACs with Ct ≤ 32 (Additional file 1: Table S2). There were 31 patients who received a routine viral respiratory multiplex test, of which 22/31 (71%) were concordant with TAC results (Additional file 1: Table S5). Concordance increased to 6/7 (86%) restricting to ETT aspirate and mini-BAL samples, matching the sampling method used for TAC.
The impact of TAC on antimicrobial decision-making
Consultants reported a change in prescription in 44/94 (47%) of cases based on reported TAC results. Antimicrobial therapy duration was reduced or stopped in 24/94 (26%) of children, and prolonged in 15/94 (16%) of children (Fig. 4). Of the 86 children that continued antimicrobial therapy, the spectrum of treatment was broadened in 15/86 (17%) and reduced in 15/86 (17%).
The impact of TAC on total antimicrobial prescriptions
Due to a higher proportion of suspected VAP in our prospective cohort (Additional file 1: Table S6), the case–control analysis of antimicrobial utilisation was limited to children with suspected CAP (Additional file 1: Table S7). We found no significant difference in the proportion of days on antimicrobial therapy in children with suspected CAP in our cohort (n = 80, 75.9% mean PICU days, SD 33.0) compared to the controls (n = 49, 65.9% mean PICU days, SD 29.3). Additionally, we found no significant difference in ASI between the those in our cohort (median 38.5, IQR 23.3–58.9), versus controls (ASI 30.0, IQR 18.0–64.5, Z = − 1.084, p = 0.298). We did, however, observe a reduction in the use of aminoglycosides (2.6% vs. 5.1% treatment days) and macrolides (16.6% vs. 21.9% treatment days) in our cohort with suspected CAP compared to controls; this trend was reversed for beta-lactams (61.4% vs. 54.4% treatment days) (Additional file 1: Table S8).
Discussion
In this study, we found that TAC identified bacteria and fungi more quickly than routine microbiology culture and increased the detection of bacterial species substantially. This result is important in view of the low yield of respiratory cultures in PICU, which may be compounded by the early administration of broad-spectrum antimicrobials and lack of routine culture techniques for atypical organisms. Having a diagnostic test with greater sensitivity for bacterial organisms has the potential to reassure clinicians that they can identify bacterial co-infection.
The present study determined a similar sensitivity and specificity of TAC as compared to adults with suspected VAP (sensitivity 92% (CI95 83–98) and specificity 97% (CI95 97–98)) [10]. This suggests that the smaller volume mini-BAL samples obtained in children are still reliable when compared to bronchoscopic samples obtained in adults. Of the four organisms found on culture, but were not significant on TAC, there were two that were likely commensals (E. faecalis and C. dubliniensis). We utilised 16S sequencing to assess the detection of additional bacteria by TAC, an approach that is only accurate to genus level of taxonomy. Of these additional bacteria identified, 35/40 (87.5%) were highly likely to be true positives according to the 16S sequencing data, whilst qPCR is more sensitive than sequencing, we cannot be certain about the validity of the remaining five (12.5%).
Numerous adult studies have found rapid molecular tests to be sensitive in detection of respiratory pathogens [21,22,23,24,25], but they have not yet been clinically evaluated in critically ill children. TAC was slower that other reported tests such as the Biofire Film Array (bioMérieux) and Unyvero Pneumonia Panel (Curetis) [23, 26]. However, our study was conducted in a clinical setting, with laboratory staff only available to process samples in business hours, which was a factor in the time from clinical sampling to result.
Consultants reported that they changed both the spectrum and the duration of antimicrobial therapy based on 47% of TAC results. This was not reflected in a reduction in the proportion of PICU days spent on antimicrobial therapy or the burden of treatment according to total ASI in children with CAP. There are several potential reasons for this. We measured total antimicrobial prescriptions, not just prescriptions for LRTI. Given that critically ill children are often treated for multi-system infections, the impact of the test may have been masked. Additional antimicrobial therapy may have been administered due to false positives or due to the high sensitivity of TAC result and the possibility that colonisation is reported as infection. Escalation of therapy is beneficial in the avoidance of antimicrobial resistance (AMR) if it prevents under treatment of infection. We therefore suggest that future studies evaluate the number of days in which patients receive appropriate antimicrobial therapy in addition to assessing total antimicrobial use.
Given that TAC is highly sensitive, mini-BAL was advised in the protocol to avoid irrelevant pathobionts found in the upper airway and ETT biofilms. Previous reports have predominantly used swabs or tracheal aspirates [8, 26, 27]. Nine samples were obtained via ETT aspiration despite this. In addition, samples were obtained by a range of physiotherapy, nursing, and medical staff. These factors may have introduced sample heterogeneity but did not impact on the validity of our findings given that analysis was carried out only on samples where TAC and microbiology culture were completed on the same specimen.
An alternative rapid diagnostic method is next-generation metagenomic sequencing (NGS), which has the advantage of being unrestricted in the potential pathogens it may detect. Paediatric studies of NGS describe it as a sensitive test, but it is difficult to determine its clinical application given that studies tend to report positive detection rates in comparison with culture rather than sensitivity and specificity [28,29,30]. The relevance of low prevalence pathogens and fluctuations in the composition of the respiratory microbiome remains a challenge for the interpretation of molecular diagnostics [31, 32].
It was not possible to reliably measure the performance of TAC for the detection of viral species in comparison with routine multiplex qPCR testing. This was firstly due to the PICU having severely restricted access to viral investigations during the COVID-19 pandemic, during which the laboratory prioritised SARS-CoV-2 testing. Secondly, viruses are shed more heavily in the upper airway than lower airway; hence, discordance between these sample locations is common [33]. Only 7/31 children enrolled to RASCALS that received routine viral multiplex tests had samples obtained from the lower airway; hence, caution should be applied to the comparison with samples which underwent TAC. Respiratory viral RNA can be shed for many weeks after the virus is viable; hence, implications of a positive test can be unclear [34]. Given that bacterial co-infection occurs in up to 33% of CAP [35] and 38% of bronchiolitis [36], the detection of viral species alone is unlikely to reassure PICU clinicians that antimicrobial therapy may be ceased [37]. Given that viral respiratory multiplex qPCR tests have been extensively investigated [38], this study focused on bacterial and fungal pathogen detection to aid antimicrobial decision-making.
This study was not large enough to analyse the Ct threshold at which growth occurred on microbiology culture for specific organisms; therefore, we reported the presence of any organism. A future study investigating what is found by TAC in respiratory samples from patients without clinical suspicion of pneumonia may help further determine significance of micro-organisms detected at low levels (i.e. high Ct values) which may represent colonisation rather than infection.
TAC is unique among commercially available rapid diagnostic tests [6, 26], in that the configuration of the card can be adapted according to the needs of the PICU. We modified the TAC to incorporate diagnostic primers for SARS-CoV-2 during the pandemic. Depending on the number of targets desired per sample, multiple samples can be loaded onto the card to improve cost-effectiveness. This flexibility allows the card to be used for a range of medical indications and be tailored to local pathogens. However, this is currently only possible in research studies as it is not an accredited in vitro diagnostic (IVD) assay.
To our knowledge, this is the first study of a rapid diagnostic test for bacterial and fungal causes of both CAP and VAP in ventilated, critically ill children. We propose TAC be used as an adjunct rather than a replacement for microbiology culture in services which have a microbiology facility that can assist with test interpretation. TAC may provide an early diagnosis to direct antimicrobial therapy, but microbiological cultures should occur in parallel to provide antimicrobial susceptibility data.
Conclusions
TAC can be used to reliably detect pathogens quicker than routine culture in critically ill children with suspected LRTI. The equipment required to undertake TAC is likely to be available in most tertiary hospitals with a molecular diagnostic laboratory. A multi-centre study to determine actions following TAC report, including the impact of viral pathogen detection, would be beneficial for determining whether TAC should have more widespread implementation. Future studies should incorporate antimicrobial decision support and economic analysis.
Availability of data and materials
With the exception of potentially identifying information, study data are available at the Open Science Framework: The rapid detection of respiratory pathogens in critically ill children [Internet]. OSF; 2022. Available from: osf.io/yczuf.
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Acknowledgements
We express our deepest thanks to the families that volunteered to take part in RASCALS. This study could not have taken place without the support of all the staff of the Paediatric Intensive Care Unit and Addenbrooke’s Hospital, Cambridge. We also wish to acknowledge physiotherapists Helen Starace and Colin Hamilton for assisting with developing mini-BAL sampling procedure and scientist Claire Jenkins for assisting with sample workflow.
Funding
This project is funded by the Addenbrooke’s Charitable Trust, Cambridge University Hospitals (900240) (JAC, NP, MET, IRLK and SB) which provided funding for consumables and 16S rRNA gene sequencing of samples, in addition to the NIHR Cambridge Biomedical Research Centre. The authors also receive support from the Gates Cambridge Trust (OPP1144) (JAC); the Academy of Medical Sciences and the Health Foundation Clinician Scientist Fellowship (MET); Wellcome Trust (215515) (SB); Wellcome Trust Clinical Research Career Development Fellowship (WT 2055214/Z/16/Z) (ACM) MRC Clinician Scientist Fellowship (MR/V006118/1) (ACM); and Action Medical Research (NP, SB, MET) (GN2751, GN2903).This work was supported, in whole or in part, by the Bill & Melinda Gates Foundation (OPP1144). Under the grant conditions of the Foundation, a Creative Commons Attribution 4.0 Generic License has already been assigned to the Author Accepted Manuscript version that might arise from this submission.
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Contributions
JAC, ACM, MDC, VN, MET, SB, and NP were involved in conceptualisation; JAC, ACM, MDC, DW, ED, VN, RB, SB, and NP were responsible for methodology; JAC, DW, and ED curated the data; JAC, MDC, DW, ED, IRLK, ZZ, and FK undertook the investigation; JAC, DW, ED, and NP participated in project administration; JAC wrote and prepared the original draft; JAC, ACM, MDC, DW, ED, IRLK, JBS, MM, RB, MET, DI, ZZ, SA, CK, FK, TG, SB, and NP took part in writing—reviewing and editing; JAC, IRLK, MET, SB, and NP acquired the funding; SB and NP contributed to supervision. All authors read and approved the final manuscript.
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The study was sponsored by Cambridge University Hospitals NHS Foundation Trust and the University of Cambridge. Approval was granted by the Yorkshire and Humber-Bradford Leeds Research Ethics Committee (REC ref 20/YH/0089 on 26 March 2020). The trial was registered prior to commencement on ClinicalTrials.gov (NCT04233268).
Competing interests
MDC is the inventor on a patent held by the Secretary of State for Health (UK government) EP2788503, which covers some of the genetic sequences used in this study. VN is a founder, director, and shareholder in Cambridge Infection Diagnostics (CID) which is a commercial company aimed at developing molecular diagnostics in infection and antimicrobial and AMR stewardship. ACM and SB are members of the Scientific Advisory Board of CID. ACM receives speaking fees from Boston Scientific. All other authors declare no conflict of interest.
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Supplementary Information
Additional file 1
. Additional methods and results for the Rapid Assay for Sick Children with Acute Lung infection Study.
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Clark, J.A., Conway Morris, A., Curran, M.D. et al. The rapid detection of respiratory pathogens in critically ill children. Crit Care 27, 11 (2023). https://doi.org/10.1186/s13054-023-04303-1
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DOI: https://doi.org/10.1186/s13054-023-04303-1