Systematic Literature Review of Respiratory Syncytial Virus Laboratory Testing Practices and Incidence in United States Infants and Children <5 Years of Age

Abstract

Background

Respiratory syncytial virus (RSV) can cause serious illness in those aged <5 years in the United States, but uncertainty remains around which populations receive RSV testing. We conducted a systematic literature review of RSV testing patterns in studies published from 2000 to 2021.

Methods

Studies of RSV, medically attended RSV lower respiratory tract infections (LRTIs), and bronchiolitis were identified using standard methodology. Outcomes were clinical decisions to test for RSV, testing frequency, and testing incidence proportions in inpatient (IP), emergency department (ED), outpatient (OP), and urgent care settings.

Results

Eighty good-/fair-quality studies, which reported data from the period 1988–2020, were identified. Twenty-seven described the clinical decision to test, which varied across and within settings. Two studies reported RSV testing frequency for multiple settings, with higher testing proportions in IP (n = 2, range: 83%–85%, 1996–2009) compared with ED (n = 1, 25%, 2006–2009) and OP (n = 2, 15%–25%, 1996–2009). Higher RSV testing incidence proportions were observed among LRTI infant populations in the ED (n = 1, 74%, 2007–2008) and OP (n = 2, 54%–69%, 1995–2008). Incidence proportions in LRTI populations were not consistently higher in the IP setting (n = 13). Across studies and time, there was heterogeneity in RSV testing patterns, which may reflect varying detection methods, populations, locations, time periods, and healthcare settings.

Conclusions

Not all infants and children with LRTI are tested for RSV, highlighting underestimation of RSV burden across all settings.

Respiratory syncytial virus (RSV) affects nearly all infants and children aged <5 years and can cause serious illness including lower respiratory tract infections (LRTIs) such as bronchiolitis and pneumonia [1]. A retrospective cohort study based on nationally representative datasets of United States (US) infant hospitalizations and emergency department (ED) encounters in 2011–2019 found that annual average infant RSV LRTI hospitalizations and ED visits were 56 927 (range, 43 845–66 155) and 131 999 (range, 89 809–177 680), respectively [2]. Additionally, RSV remains the leading cause of US infant hospitalizations for the past 2 decades [3–7], indicating the ongoing burden RSV poses on the infant and the health system.

However, the epidemiology of RSV in infants and children outside of the inpatient (IP) hospital setting is understudied [8]. RSV laboratory testing patterns are also not systematically summarized in the current literature; it is unclear at the population level which infants and children are being tested for RSV or why they are tested. Hence, this systematic literature review (SLR) describes RSV laboratory testing patterns, testing frequency, and testing incidence across all healthcare settings (IP, ED, outpatient [OP], urgent care) for US infants and children aged <5 years.

METHODS

The Preferred Reporting Items for Systematic Reviews and Meta-Analysis (PRISMA) guidelines were followed [9]. The protocol for this SLR was registered with the International Prospective Register of Systematic Reviews (PROSPERO identifier CRD42020162991) before the study began.

Eligibility Criteria

Study population, exposure, comparator, outcomes, and study design (PECOS) criteria were used to identify studies of US infants and children aged <5 years (population) with RSV and bronchiolitis (exposure) [10]. A comparator was not relevant for this review. Studies reporting outcomes of interest (predetermined to be RSV laboratory testing practices, testing frequency, and testing incidence proportion) were included. RSV laboratory testing practices were described as the study-reported clinical decisions to test for RSV (eg, physician judgment, presentation of symptoms such as fever, cough, and wheezing during the medical encounter, bronchiolitis diagnosis). RSV testing frequency was defined as the percentage tested for RSV among the enrolled population. RSV laboratory testing incidence proportion was defined as the percentage of RSV-positive infants and children among those tested for RSV. When available, outcomes reported for LRTI populations were summarized, given that RSV is one of the leading causes of medically attended LRTI infections [4, 11]. Outcomes stratified by sociodemographic and clinical variables such as chronological age, weeks’ gestational age (wGA), race/ethnicity, and insurance payer were summarized when available.

Randomized controlled trials (RCTs) and observational studies (surveillance, cohort, case-control, and cross-sectional) were included. Case reports with <20 cases, studies not published in English, and studies not meeting the PECOS criteria were excluded. To identify additional studies not captured by the literature searches, reference lists of relevant reviews were checked to ensure that all studies meeting the PECOS criteria were identified and included.

Study Identification, Screening, and Abstraction

Literature searches in the PubMed, Embase, and Web of Science databases were conducted to capture RSV and bronchiolitis literature published from 1 January 2000 to 11 June 2021. Literature search terms are provided in Supplementary Table 1. DistillerSR [12] was used to de-duplicate the search results and conduct the review. One reviewer examined the titles and abstracts using the predefined PECOS criteria. The articles deemed to be relevant at the abstract stage were reviewed for full text by 2 reviewers independently. Data were abstracted from the included full-text studies in DistillerSR; abstraction elements included study characteristics (eg, design, time period, location, setting), population characteristics (eg, sample size, age, wGA, sex, race/ethnicity), and outcomes (overall and by sociodemographic variables when available). After one reviewer abstracted the data elements, a second reviewer checked them independently; all conflicts were resolved by the senior reviewers. Data visualizations were done using Microsoft Excel for Mac (version 16.56).

Risk of Bias

For observational studies, a modified version of the Newcastle-Ottawa Scale was used to evaluate the study quality. The Cochrane Risk of Bias (RoB) tool was used to determine the study quality of the RCTs. Detailed description of the assessments and study quality determination is reported elsewhere [8]. This SLR considered good- and fair-quality studies and did not include the poor-quality studies.

RESULTS

Article Identification

The PRISMA study flow diagram is presented in Figure 1, and the PRISMA checklist is provided in the Supplementary Materials. At the title and abstract level, 5153 publications were screened. References cited in 34 relevant reviews were reviewed, and 91 additional publications were identified. At the full-text level, 1206 publications were reviewed. Of the 1126 publications eliminated at the full-text stage, 23 were non-RSV populations, 215 had populations aged ≥5 years, 82 had no primary data, 277 had no outcomes of interest, 34 were reviews, 329 were conducted outside the US, 45 were poor-quality studies, 79 had overlapping data, 5 were excluded study designs (ie, case reports or case series with ≤20 cases), 2 were not human, and 35 were unable to be obtained as full-text articles. Eighty good- and fair-quality studies with testing data were identified.

Risk of Bias of Included Studies (n = 80)

Of the 3 RCTs identified, 1 was good quality and 2 were fair quality as assessed with the Cochrane RoB tool (Supplementary Table 2). Among the 77 observational studies (75 cohort studies, 2 case-control), 39 and 38 studies were of good and fair quality, respectively. RoB scores for the 75 cohort studies are summarized in Supplementary Figure 1. RoB was apparent in the comparability of cohorts on the basis of design or analysis (45% did not control for >1 factor) and adequacy of follow-up (11% did not describe losses to follow-up or losses were >10%, when described).

Study and Population Characteristics

The 80 included studies were published between January 2000 and June 2021 and reported 1 or more years of data from 1988 to 2020 (Figure 2A). Eight studies (10%) reported data between 2015 and 2020, while 13 (16%) provided data that included years earlier than 2015 and up to 2020 (Supplementary Table 2). Eleven studies were surveillance, 38 were prospective cohorts, 24 were retrospective cohorts, 2 were case-control, 1 was a study of passive surveillance and prospective cohort design, 1 was a post hoc analysis of surveillance, and 3 were RCTs (Supplementary Table 2). Studies were conducted in various states across the US (Supplementary Table 2). More than half of the studies (n = 52 [65%]) provided data from the IP setting or IP combined with other settings (Figure 2B). Eighteen studies presented ED-specific data, and 4 studies provided ED data combined with other settings. Eighteen studies provided data specific to the OP setting, whereas 4 studies presented OP data combined with other settings. There were no data available for urgent care.

RSV Laboratory Testing Practices: Clinical Decisions to Test for RSV

Twenty-seven studies [13–39] provided descriptive data on the clinical decisions to test for RSV in various settings: 16 provided data for IP [13–16, 18–29], 1 for IP and for ED [17], 9 for ED [30–38], and 1 for OP [39] (Supplementary Table 3A and 3B). Thirteen studies describing laboratory testing practice for combined settings (ie, IP with other settings, ED with other settings, or OP with other settings) are listed in Supplementary Table 3C. These studies reported that RSV laboratory testing was done as part of routine care, at the discretion of the provider, based on symptoms, or per institutional guidelines. However, the clinical decision to test for RSV was not consistent across or within settings.

RSV Laboratory Testing Frequency in the IP, ED, and OP Settings: RSV Testing Among the Enrolled Populations

Seven studies reported testing frequency for a single setting (ie, IP, ED, or OP) [15, 22, 34, 40–43]; due to differences in geographical locations, time periods, population characteristics, and test types, comparisons across studies and settings could not be done, and thus, they were not described further (see Supplementary Table 4 for additional details).

Only 2 retrospective cohort studies conducted in infants and children enrolled in the Kaiser Permanente Northern California health system reported RSV testing frequency for multiple settings [44, 45] (Table 1). One Kaiser study identified 717 bronchiolitis episodes in the IP setting, 425 in the ED setting, and 9269 in the OP setting from 2006 to 2009 among infants aged 0–12 months using International Classification of Diseases, Ninth Revision (ICD-9) codes 466.11, 480.1, and 466.19 [44]. Eighty-three percent of the IP bronchiolitis episodes were laboratory tested for RSV, whereas 29% and 25% of the ED and OP bronchiolitis episodes, respectively, were tested. Another Kaiser study conducted from 1996 to 2004 among infants and children aged <2 years described similar trends in testing by setting; this study reported RSV testing frequency among IP and OP bronchiolitis episodes (ICD-9 codes 466.1, 466.1x, 466.0, 480.0–480.2, 079.0, and 079.6) with and without antibiotic use to examine the association between RSV testing and antibiotic use [45]. Testing frequency was 85% for the IP bronchiolitis episodes regardless of antibiotic use and 15% for the OP bronchiolitis episodes regardless of antibiotic use [45].

In Turi et al [44], antigen, culture, or polymerase chain reaction (PCR) tests were used from 2006 to 2009; Flaherman et al [45] used direct fluorescent antibody tests from 1996 to 2004, indicating utilization changes in RSV test types across time.

RSV Laboratory Testing Incidence Proportion in the IP Setting: Percentage of RSV-Positive Results Among Those Tested for RSV

In the IP setting, 12 studies provided RSV laboratory testing incidence proportion data for LRTI populations only [14, 41, 46–55] (Table 2). One study reported data for LRTI and upper respiratory illness populations separately [56]. One study combined data for LRTI with other respiratory distress [13], 6 studies grouped data by acute respiratory infections (ARI) or symptomatic (eg, fever) populations [40, 57–61], 1 study included healthy infants [62], and 4 studies provided information among populations of unknown respiratory conditions [24, 63–65]. Higher RSV testing incidence proportions among studies with LRTI populations were not consistently observed in the IP setting compared with studies among ARI, symptomatic, healthy, or unknown respiratory condition populations, likely due to differences in study designs, time periods, test types, locations, and other population characteristics (Table 2).

RSV Laboratory Testing Incidence Proportion in the ED Setting: Percentage of RSV-Positive Results Among Those Tested for RSV

Seven studies [30, 33, 35, 38, 66–68] reported RSV laboratory testing incidence proportion in the ED (Figure 3; Supplementary Table 5A). The highest RSV laboratory testing incidence proportion was observed in infants aged <1 year with LRTI seen at a single ED in Wisconsin (74% among 85 infants, 2007–2008) [35]. Among the 6 studies [30, 33, 38, 66–68] describing populations with symptoms or unknown respiratory conditions, RSV laboratory testing incidence proportion ranged between 6% among 378 febrile infants aged ≤28 days seen at an urban, pediatric ED in New York from 2008 to 2014 [33] and 44% among 82 infants aged 1–2 months intubated for respiratory failure with a suspected infection at an urban, pediatric ED in Ohio from 2012 to 2017 (underlying respiratory condition not reported) [66]. This study of intubated infants also provided testing incidence proportion stratified by chronological age, noting a higher incidence among younger populations (underlying respiratory condition of the population not reported) (<28 days: 31%; 1–2 months: 44%; 2–12 months: 27%; 12–24 months: 11%) [66].

RSV Laboratory Testing Incidence Proportion in the OP Setting: Percentage of RSV-Positive Results Among Those Tested for RSV

Six studies [39, 42, 56, 62, 69, 70] reported RSV laboratory testing incidence proportions in the OP setting (Figure 4; Supplementary Table 5A). The highest RSV laboratory testing incidence proportion was observed in 2 studies with LRTI infant populations [42, 56]. Incidence proportions of 54% among 63 bronchiolitis infants aged 0–12 months in a 2004–2008 Tennessee Children’s Respiratory Initiative cohort [56] and 69% among 102 bronchiolitis infants aged <3 months seen across 219 practices in 44 states from 1995 to 1998 [42] were observed. Among ARI, symptomatic, or healthy populations, the lowest RSV laboratory testing incidence proportion was 4% among 148 infants and children aged <5 years with influenza-like symptoms seen from 2013 to 2015 in New York [69], and the highest was 24% among 174 infants aged <3 months without bronchiolitis seen across 219 practices in 44 states from 1995 to 1998 [42].

RSV testing incidence proportion data further stratified by wGA, race/ethnicity, comorbidity conditions, or insurance payer were not provided for any healthcare setting.

Studies describing RSV laboratory testing incidence proportion for combined settings (ie, IP with other settings, ED with other settings, or OP with other settings) are listed in Supplementary Table 5C but were not described further due to the lack of setting-specific data.

DISCUSSION

This SLR reviewed studies published between January 2000 and June 2021 (data from 1988 to 2020), reporting RSV laboratory testing practices, testing frequency, and testing incidence proportion across all healthcare settings in US infants and children aged <5 years. Clinical decision to test for RSV was variable and often unclear across and within settings, with only a proportion of infants and children being laboratory tested, suggesting that those tested for RSV may not be representative of total US infant and pediatric RSV populations. Only 2 studies conducted in Northern California [44, 45] provided RSV laboratory testing frequency data for multiple settings to allow for comparisons across settings and the findings elucidate that testing occurs less frequently in the ED and OP compared to the IP setting. This SLR also showed the changes in RSV testing types over time with earlier studies utilizing tests such as direct fluorescent antibody and cultures while more recent studies reported greater utilization of PCR tests. Moreover, not all infants and children were tested for RSV and this pattern held across all healthcare settings, suggesting there may be heterogeneity in RSV laboratory testing practice with differences in testing frequency by setting that could potentially underestimate RSV. However, the data were >10 years old, not available for all healthcare settings, and pertained to select infant and pediatric populations within a closed health system. Further research using current data and conducted within other health systems in various geographical locations is urgently needed to fill the knowledge gaps identified by this SLR.

Varying pediatric populations by chronological age, setting, respiratory symptoms, time periods, locations, testing practices, and test types were included in the studies identified in this SLR, making it difficult to summarize the RSV laboratory testing frequency and incidence proportion data across studies. Stratified data by sociodemographic and clinical variables such as wGA, insurance status, and comorbidity conditions were also not available by setting. Hence, there are potential uncertainties around assessing the impact of new immunization strategies to prevent RSV due to these data gaps in the existing literature landscape. As new RSV prevention strategies are on the horizon [71], models used to estimate the impact of potential new immunoprophylaxis on the RSV disease burden will need laboratory testing data inputs, overall and by sociodemographic and clinical variables. Specifically, the number of infants and children who test positive for RSV among LRTIs and the number of LRTIs among RSV-positive infants and children for multiple settings should be described. Studies conducted among all infants and children aged <5 years across all settings, with detailed sociodemographic and clinical data collection, will allow for a complete perspective of RSV disease in the US and are urgently needed.

This SLR had several strengths including rigorous study methodology that registered the study protocol a priori before SLR conduct, adherence to the PRIMSA guidelines, and use of validated RoB tools to evaluate the quality of the included studies. Because the SLR was specific to infants and children aged <5 years in the US, our findings may not be generalizable to those outside of the US or to populations >5 years of age. Furthermore, there were changes in detection methods over time, which were not accounted for, and there is the possibility of testing bias across the studies given the variability in the clinical decisions to test. The impact of coronavirus disease 2019 on RSV epidemiology was not considered in this review.

This SLR highlights the substantial variability in RSV laboratory testing practices, testing frequency, and testing incidence proportions. Furthermore, the limited number of studies detailing RSV laboratory testing frequency emphasizes the lack of routine testing in the US, especially outside of the IP setting. Studies exploring the intersection between RSV laboratory testing results and ICD diagnosis codes are needed to inform the extent of underestimation of RSV. Prospective studies with active, routine testing across all healthcare settings are needed to comprehensively describe the true burden of RSV among infants and children in the US.

Supplementary Data

Supplementary materials are available at The Journal of Infectious Diseases online (http://jid.oxfordjournals.org/). Supplementary materials consist of data provided by the author that are published to benefit the reader. The posted materials are not copyedited. The contents of all supplementary data are the sole responsibility of the authors. Questions or messages regarding errors should be addressed to the author.

Notes

Acknowledgments. Editorial assistance was provided by inScience Communications (Philadelphia, Pennsylvania). This work was performed in accordance with current Good Publication Practice guidelines and was supported/funded by Sanofi.

Financial support. This collaborative study with EpidStrategies was supported/funded by Sanofi and AstraZeneca.

Supplement sponsorship. This article appears as part of the supplement “Respiratory Syncytial Virus Disease Among US Infants,” sponsored by Sanofi and AstraZeneca.

References

Author notes