key: cord-0993551-45c68pd8
authors: De Paulis, Milena; Oliveira, Danielle Bruna Leal; Thomazelli, Luciano Matsumiya; Ferraro, Alexandre Archanjo; Durigon, Edison Luiz; Vieira, Sandra E.
title: The importance of viral load in the severity of acute bronchiolitis in hospitalized infants
date: 2021-11-23
journal: Clinics (Sao Paulo)
DOI: 10.6061/clinics/2021/e3192
sha: 9264ecb4ca292ffa16fcb1b1ad597d02c82fde28
doc_id: 993551
cord_uid: 45c68pd8

OBJECTIVE: The relationship between viral load and the clinical evolution of bronchiolitis is controversial. Therefore, we aimed to analyze viral loads in infants hospitalized for bronchiolitis. METHODS: We tested for the presence of human respiratory syncytial virus (HRSV) or human rhinovirus (HRV) using quantitative molecular tests of nasopharyngeal secretions and recorded severity outcomes. RESULTS: We included 70 infants [49 (70%) HRSV, 9 (13%) HRV and 12 (17%) HRSV+HRV]. There were no differences among the groups according to the outcomes analyzed individually. Clinical scores showed greater severity in the isolated HRSV infection group. A higher isolated HRSV viral load was associated with more prolonged ventilatory support, oxygen therapy, and hospitalization days, even after adjustment for the age and period of nasopharyngeal secretion collection. In the co-infection groups, there was a longer duration of oxygen therapy when the HRSV viral load was predominant. Isolated HRV infection and co-infection with a predominance of HRV were not associated with severity. CONCLUSION: Higher HRSV viral load in isolated infections and the predominance of HRSV in co-infections, independent of viral load, were associated with greater severity. These results contribute to the development of therapeutic and prophylactic approaches and a greater understanding of the pathophysiology of bronchiolitis.

' INTRODUCTION Viral bronchiolitis (VB) is the most common infection of the lower airways in infants. Respiratory viruses are the principal causative agents, particularly human respiratory syncytial virus (HRSV) and human rhinovirus (HRV) (1) . The rate of pediatric hospitalization due to VB is approximately 18% (2) , wherein up to 20% them require intensive care unit (ICU) admission, and 2-3% need mechanical ventilation (3) (4) (5) .

Several factors may be related to the severity of VB, including the causative agent, presence of comorbidities, and environmental factors. The literature is divided into the influence of viral load (VL) on the VB severity. Previous studies have shown that higher VL influences severity, especially HRSV (2, 4, (6) (7) (8) . Nevertheless, there are differing opinions in the literature (9, 10) .

Therefore, this study aimed to analyze the association between VL and the clinical course of VB. This knowledge can improve prophylactic and therapeutic measures and aid the understanding of the pathogenetic mechanisms of VB in the future.

We included infants aged 0-6 months hospitalized from January 2013 to November 2015. The patients diagnosed with VB according to the American Academy of Pediatrics (11) criteria and nasopharyngeal aspirate samples (NPA) positive for HRSV or HRV as isolated agents or co-infected with both. We excluded those with recent (p30 days before current infection) or current use of corticosteroids, current use of antibiotics (p15 days), previous wheezing crisis, and congenital heart disease or bronchodysplasia.

NPA was collected during admission or within 72h of hospitalization. The automated extraction of the viral genetic material was performed using the Nuclisenss Iso Kit (BioMerieux, Lyon, France) in the EasyMag equipment (BioMerieux, Lyon, France), and all protocols were processed as previously described (12) . Quantification of VL was performed using quantitative polymerase chain reverse transcription (qPCR). In-house singleplex real-time (RT)-PCR assays for HRSV and HRV were performed using AgPath-IDt One-Step RT-PCR reagents (Applied Biosystems) (13, 14) , and all extracts were tested for human RNase P (RNP) gene by RT-PCR to confirm sample quality. All extracts showed RNP cycle threshold (Ct) values (range, 18.3-31.4). We used a minimum of two dilutions of standard samples with pre-defined quantification, which allowed the absolute quantification of the number of copies/mL contained in each sample. The complete methodology is described in the Appendix.

The characteristics, background, and severity outcomes were collected from medical records and analyzed according to the etiological group. Demographic characteristics included age, sex, and race. The background included exclusive breastfeeding up to 6 months of life without introducing milk formula and exposure to smoking within the household. The severity outcomes were days of hospitalization and the need for and duration of ICU stay, non-invasive and mechanical ventilation, and oxygen therapy.

The infants were divided into the following groups: isolated HRSV infection, isolated HRV infection, and HRSV and HRV co-infection. The HRV co-infection was subdivided into the following subgroups: VL of HRSV greater than HRV and VL of HRSV less than HRV. The time elapsed from the onset of symptoms and collection of NPA was used to adjust the associations of higher HRSV VL and greater severity. Infants were also divided into groups based on the duration between the onset of symptoms and NPA collection (p5 days and 45 days).

Demographic characteristics and background were analyzed using absolute and relative frequencies. The likelihood ratio test was used to calculate the associations with the etiological group. The severity outcomes were described using mean, standard deviation, median, minimum, and maximum and were compared using the Kruskal-Wallis test (Microsoft Excel 2003 software). The absolute VL was transformed to log 10 copies/mL. A clinical score based on a latent variable was created (STATA 14, StataCorp. 2015. Stata Statistical Software: Release 14. College Station, TX: StataCorp LP). We started from the measured variables to create the latent variable: ICU stay (yes or no and the number of days), orotracheal intubation (yes or no and the number of days), CPAP (yes or no and the number of days), days of oxygen therapy, and hospitalization. The correlation between the binary variables and the respective number of days and between the ICU stay and the days of hospitalization was analyzed, resulting in a clinical score. The clinical score created was then categorized into tertiles; the first, second, and third tertiles were termed low-, medium-, and highseverity, respectively. Patients who stayed a maximum of 3 days in the hospital regardless of whether they used oxygen, but did not require ICU care were considered lowseverity patients. Those who stayed for a maximum of 6 days in the hospital and required oxygen but did not require ICU care were considered medium-severity patients and those who stayed in the hospital for 46 days and required oxygen and ICU admission were considered high-severity patients.

In the univariate and multivariate analyses for the severity outcomes, adjustments were made for age (p28 days, 28-90 days, X90 days) and the time between the onset of symptoms and collection of NPA (p5 days, 45 days). Generalized linear models were built using a robust standard error estimate.

Fisher's test was used to analyze the distribution of VL categories according to severity categories. The level of significance was set at 5%.

For the sample calculation, assuming a correlation coefficient of 0.40 between VL and days of hospitalization and probability of type 1 error occurrence set at 5% and type 2 error occurrence set at 20%, 47 infants would be needed to find a significant correlation. The Research Ethics Committee approved the study of the University Hospital of the University of São Paulo (1664/17).

A convenience sample was selected, and 78 infants were eligible according to the inclusion criteria. After applying the exclusion criteria, 70 infants remained ( Figure 1 ). Among these 70 infants, 49 had isolated HRSV infection, nine had isolated HRV infection, and 12 had HRSV+HRV coinfection.

The demographic and clinical characteristics were similar between the groups according to the etiology. The mean age was 70.4 days (standard deviation=46.8). Table 1 shows the descriptions and comparisons of infants according to their demographic and clinical characteristics according to etiology. Thirteen neonates were included (groups: HRSV, nine; HRV, two; HRSV+HRV, two). The average duration of hospitalization was 5 days. Two neonates were admitted to the ICU for ventilatory support. Table 2 shows the comparative analyses of the severity outcomes according to the etiology.

According to the clinical score, isolated HRSV infection was associated with a higher number of high-severity cases than the other groups. A single HRV infection was associated with the least severe cases. In co-infections, when HRSV predominated over HRV, the cases were more severe ( Table 3 ). The distribution of VLs according to severity categories and etiology is shown in Table S1-Appendix.

The median VL in isolated HRSV infection was higher than that in co-infections (6.6 vs. 5.5 log 10 copies/mL, respectively; p=0.003). The median VLs of HRV in isolated infections and co-infections with HRV predominance were similar (4.5 vs. 4.4 log 10 copies/mL, respectively; p=0.776).

Approximately 75% of the samples were collected within the first 5 days of symptom onset (mean, 4.5 days). We collected 25% of the samples after 5 days, with an average of 7 days from the onset of symptoms. The comparison of the median VL for isolated HRSV infection of infants who had the NPA collected with up to 5 days of symptom onset and those who had the NPA collected X5 days of symptom onset were similar (6.69 vs. 6.47 log 10 copies/mL, respectively; p=0.462). This comparison showed similar results for infants with isolated HRV infection (5.04 vs. 3.98 log 10 copies/mL, respectively; p=0.121). When comparing the medians of the VL of the HRSV, in the co-infections where HRV predominated, there was no difference concerning the day of NPA (6.37 vs. 5.27 log 10 copies/mL, respectively; p=0.143). When HRV predominated, the medians for comparing HRV VL concerning the collection day were also similar (6.01 vs. 5 Á 25 log 10 copies/mL, respectively; p=1 Á 000). Table 4 shows the associations between the etiological groups and severity outcomes according to the univariate and multivariate analyses. The outcomes were adjusted for age (p28 days; 29-90 days or 490 days) and time between symptom onset and NPA collection (p5 days and 45 days). The coefficient represents the value of the average increase in days in the case of a higher VL.

This study analyzed the importance of VL in bronchiolitis and showed that greater VL of HRSV was associated with greater severity in cases of infection by an isolated agent and co-infections.

The selected sample was representative of VB in infants, with a predominance of males and HRSV as causal agents. The clinical evolution was compatible with previous studies reporting an average of 5 days of hospitalization and approximately 20% of cases in the ICU (4,5).

In hospitalized infants with bronchiolitis, the most frequent etiological approach in clinical practice is qualitative analysis without VL quantification. According to each severity outcome, the analysis comparing etiological groups was insufficient to show any difference between these groups. In contrast, the use of the severity score made it possible to differentiate the etiological groups, highlighting HRSV as the agent associated with greater severity both in isolated infection and in coinfections in which it was the predominant agent.

The severity of infection can be influenced by the host characteristics, environment, and infectious agents. Confounding factors, such as the time elapsed between the onset Regardless of the drop in VL during hospitalization, the highest VL was associated with severity. In the present study, the associations of higher HRSV VL and greater severity remained significant even after adjusting for the time elapsed between the onset of symptoms and NPA collection. This result suggests a lack of bias in our study due to differences in VL according to the time when NPA was collected.

Notably, the association between severity and VL was not observed for HRV as an isolated agent, similar to previous studies (15, 16) . It is possible that the host's immune response and the HRV species involved in the infection are more critical than VL (16, 17) . The present study did not include an analysis of VL according to HRV species.

Respiratory virus co-infections are common in infants with lower airway infections (up to 40% of cases) (18) . Other authors found greater severity in children with HRSV and HRV co-infection (6, 19, 20) . However, in a systematic review, there was no influence on the severity outcomes (21) .

Rodrigues et al. reported that the co-infection group had the predominance of HRSV, which was associated with greater severity (20) . In addition to the results found in single HRSV infection, this suggests that the pathogenic mechanisms involved in HRSV bronchiolitis are associated with more severe clinical symptoms. One possible explanation is the competition between the pathogenic mechanisms of the viruses. HRSV is a slower-growing virus compared to HRV. However, when there is a delay in the onset of HRV infection, HRSV can block its replication, with a consequent decrease in HRV VL. It is also possible that interferon produced in HRSV infection causes the inhibition of HRV, decreasing the intensity of its manifestations (22) .

The influence of age on the severity of bronchiolitis has been well described in the literature. The increase in VL in younger children, with consequently more severe clinical presentation, could be associated with indirect factors, such as exposure to infected contacts, viral serotype, and immaturity of the immune system. For example, Feikin et al. observed a tendency for VL to drop as age increased for HRSV (23) . For HRV, there was a tendency to increase VL with older age. However, this study showed no difference in VL when considering age groups, both for isolated infections and for co-infection and severity, when multivariate analysis was carried out (23, 24) . This result could be explained by the inclusion of infants aged 0-6 months, the presence of maternal transplacental IgG, especially for HRSV, up to the third month of life, and the reduction of cytokine production by Th1 and Th2 cells in infants o4 months of age, conferring an anti-inflammatory protective effect and balancing the excessive inflammatory responses (25) .

Regarding the influence of VL on the severity of bronchiolitis, other authors postulated that higher VL of HRSV is associated with less severe disease due to a more robust immune response, with faster viral clearing and decreased disease progression (10) . On the other hand, some authors believe that greater VL corresponds with greater amplification of the immune response, a greater insult to the respiratory epithelium, and a greater degree of inflammation. As a result, the clinical presentation was more severe.

This study had limitations. First, the analysis of the immune response was not performed, which may contribute to clarify the influence of VL on clinical severity in future studies. Second, the lack of analysis of the various HRSV genotypes and HRV species and their possible relationships with VL and severity outcomes. The number of positive samples limited this analysis; therefore, new studies involving larger samples would be of significant relevance. Nevertheless, we used housekeeping gene quantification (human RNase P gene) to assure the quality of nasal lavage samples, although we did not correct VL by cell count of the samples.

A higher VL of HRSV was associated with greater severity of isolated infections. In co-infections, the predominance of HRSV over HRV, independent of viral load, was associated with greater clinical severity. These results can contribute to the development of new therapeutic and prophylactic approaches and a deeper understanding of the pathophysiology of VB.

We would like to thank Fundac¸ão de Amparo à Pesquisa do Estado de São Paulo (FAPESP-12/22854-9) for the financial support.

De Paulis M and Vieira SE conceptualized and designed the study, drafted the initial manuscript, and reviewed the manuscript. Thomazelli LM, Oliveira DBL and Durigon EL were responsible for diagnostic laboratory analysis. Ferraro AA was responsible for the data analysis, and all of the authors approved the final version of the manuscript as submitted and agreed to be accountable for all aspects of the work. 

Total RNA/ and DNA extraction from nasopharyngeal aspirate samples. For the extraction of the viral genetic material, 500 mL of sample from ANP was mixed with 500 mL of lysis buffer from the Nuclisens s Iso Kit (BioMerieux, Lyon, France). In the same reaction, a negative (weather) and positive control (universal control gently provided by Dean Erdman/Atlanta). Briefly, 50 mL of magnetic silica was added to the sample/Lysis buffer mix, resulting in nucleic acid bonds. The nucleic acid-free components were removed in several washing steps performed on the Nuclisens EasyMag equipment (BioMerieux, Lyon, France). Finally, the nucleic acids were eluted from the solid phase with a Nuclisens Eluition Buffer (BioMerieux, Lyon, France) that keeps RNA intact for weeks at room temperature (23 o C).

Human respiratory syncytial virus and human rhinovirus detection using real-time quantitative polymerase chain reverse transcription. Primers and probes previously described in the literature (1) were used (noninfluenza primer sets) kindly provided by the Centers for Disease Control and Prevention, Atlanta, GA, USA, for 14 different viruses: human respiratory syncytial virus (HRSV), human metapneumovirus, adenovirus, human rhinovirus (HRV), parainfluenza 1-4, coronavirus HKU1, NL63, 229E, and OC43; and commercial primers and probes for influenza A and B (Invitrogen). All the samples were amplified separately for the different viruses tested.

Real-time ''one-step'' amplification of HRSV and HRV was performed as described by Fry et al. (2) and Lu et al. (3) The amplification occurred in the Real Time 7300 PCR System thermocycler (Applied Biosystems) from the reverse transcription step (45 o C/ 15'), followed by enzyme inactivation (94 o C/5'), and finished with 45 cycles of 94 o C for 15s for denaturing and 56 o C for 30s for primer pairing. A minimum of two dilutions of standard samples with pre-defined quantification were used in RSV and RV. This allowed the absolute quantification of the number of copies/mL contained in each sample.

Table S1 -Distribution of viral loads according to severity categories and etiology.. 

Respiratory syncytial virus load predicts disease severity in healthy infants

Virus Type and Genomic Load in Acute Bronchiolitis: Severity and Treatment Response With Inhaled Adrenaline

The impact of viral dynamics on the clinical severity of infants with respiratory syncytial virus bronchiolitis

Natural infection of infants with respiratory syncytial virus subgroups A and B: a study of frequency, disease severity, and viral load

The interdependencies of viral load, the innate immune response, and clinical outcome in children presenting to the emergency department with respiratory syncytial virus-associated bronchiolitis

Viral Load Dynamics and Clinical Disease Severity in Infants With Respiratory Syncytial Virus Infection

Clinical practice guideline: the diagnosis, management, and prevention of bronchiolitis

Infections Caused by HRSV A ON1 Are Predominant among Hospitalized Infants with Bronchiolitis in São Paulo City

The burden of hospitalized lower respiratory tract infection due to respiratory syncytial virus in rural Thailand

Realtime reverse transcription-PCR assay for comprehensive detection of human rhinoviruses

Equal virulence of rhinovirus and respiratory syncytial virus in infants hospitalized for lower respiratory tract infection

Rhinovirus-induced bronchiolitis: Lack of association between virus genomic load and short-term outcomes

Patient characteristics and severity of human rhinovirus infections in children

Impact of Human Rhinovirus Types and Viral Load on the Severity of Illness in Hospitalized Children With Lower Respiratory Tract Infections

Epidemiological characteristics and clinical outcomes of human rhinovirus infections in a hospitalized population. Severity is independently linked to RSV coinfection and comorbidities

Severe lower respiratory tract infection in infants and toddlers from a non-affluent population: viral etiology and co-detection as risk factors

Respiratory viral coinfection and disease severity in children: A systematic review and meta-analysis

Interference Between Respiratory Syncytial Virus and Human Rhinovirus Infection in Infancy

Is Higher Viral Load in the Upper Respiratory Tract Associated With Severe Pneumonia? Findings From the PERCH Study

Rhinovirus load and disease severity in children with lower respiratory tract infections

The development of the immune system during pregnancy and early life

Comparison of fast-track diagnostics respiratory pathogens multiplex real-time RT-PCR assay with in-house singleplex assays for comprehensive detection of human respiratory viruses

The burden of hospitalized lower respiratory tract infection due to respiratory syncytial virus in rural Thailand

Realtime reverse transcription-PCR assay for comprehensive detection of human rhinoviruses