Recommended use of palivizumab to reduce complications of respiratory syncytial virus infection in infants

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Organization: Public Health Agency of Canada

Published: June 1, 2022

Published: June 1, 2022

Preamble
Summary of information contained in this NACI statement
Introduction
Methods
Epidemiology
Product
Economics
- V.1 Systematic review
- V.2 Cost-effectiveness study in Nunavik, Quebec
Ethics, equity, feasibility and acceptability considerations
Recommendations
Research priorities
Surveillance issues
- Ranking individual studies, strength of recommendations, grade of evidence
Abbreviations
Acknowledgements
Appendix A: Current criteria for receipt of Palivizumab in Canadian provinces and territories and internationally
Appendix B: Palivizumab safety
Appendix C: Palivizumab effectiveness: additional data table
References

Preamble

The National Advisory Committee on Immunization (NACI) provides the Public Health Agency of Canada (PHAC) with ongoing and timely medical, scientific, and public health advice relating to immunization.

In addition to burden of disease and vaccine characteristics, PHAC has expanded the mandate of NACI to include the systematic consideration of programmatic factors in developing evidence-based recommendations to facilitate timely decision-making for publicly funded vaccine programs at provincial and territorial levels.

The additional factors to be systematically considered by NACI include: economics, ethics, equity, feasibility, and acceptability. Not all NACI Statements will require in-depth analyses of all programmatic factors. While systematic consideration of programmatic factors will be conducted using evidence-informed tools to identify distinct issues that could impact decision-making for recommendation development, only distinct issues identified as being specific to the vaccine or vaccine-preventable disease will be included.

PHAC acknowledges that the advice and recommendations set out in this statement are based upon the best current available scientific knowledge and is disseminating this document for information purposes. People administering the vaccine should also be aware of the contents of the relevant product monograph(s). Recommendations for use and other information set out herein may differ from that set out in the product monograph(s) of the Canadian manufacturer(s) of the vaccine(s). Manufacturer(s) have sought approval of the vaccine(s) and provided evidence as to its safety and efficacy only when it is used in accordance with the product monographs. NACI members and liaison members conduct themselves within the context of PHAC's Policy on Conflict of Interest, including yearly declaration of potential conflict of interest.

Summary of information contained in this NACI statement

The following highlights key information for immunization providers. Please refer to the remainder of the Statement for details.

1. What

Respiratory syncytial virus disease

Respiratory syncytial virus (RSV) causes yearly outbreaks of respiratory tract disease, in Canada from late fall to early spring. It is the most common cause of lower respiratory tract illness in young children worldwide. While many infections are simple colds, children less than 2 years of age are at risk of severe disease such as bronchiolitis or pneumonia and may be hospitalized. Underlying health conditions, especially premature birth, chronic lung disease and congenital heart disease (CHD) redispose to severe RSV illness. Reinfections occur throughout life as infection produces only partial and temporary immunity, although reinfections are usually milder than the initial one.
Palivizumab

At present there is no vaccine available to prevent RSV. The only means of prophylaxis against RSV disease is temporary passive protection with the monoclonal antibody preparation Palivizumab (SynagisTM). Palivizumab (PVZ) has only been studied in children less than 2 years of age with underlying health conditions. Efficacy in early studies was 38-78% in different patient groups, and further studies, mainly observational, showed wide variation in effect with some studies showing no benefit. PVZ has been used for over 2 decades in many countries and has a good safety record, with very rare cases of anaphylaxis being the major serious adverse event (SAE) It is an expensive product, with wide ranging estimates of cost-effectiveness (or value for money). Estimated incremental effectiveness ratios (ICERs) ranged from less than $1,000 per quality-adjusted life year (ALY) to over 2 million dollars per QALY in various scenarios. In various high risk groups, 64% to 100% of estimates were < $50,000 per QALY. In rare scenarios it may be dominant (i.e. less costly and more effective). RSV vaccines are currently under study.

2. Who

NACI makes the following recommendations for public health program level decision-making:

PVZ should be offered to premature infants of < 30 weeks gestational age (wGA) and < 6 months of age at onset of or during the RSV season; children aged < 24 months with chronic lung disease of prematurity who require ongoing oxygen therapy within the 6 months preceding or during the RSV season; infants aged < 12 months with haemodynamically significant CHD and infants born at < 36 wGA and age < 6 months old living in remote northern Inuit communities who would require air transport for hospitalization. For children with both CHD and chronic lung disease, recommendations for chronic lung disease should be followed.
PVZ may be considered for premature infants of 30-32 wGA and age <3 months who are at high risk for exposure to RSV; selected children <24 months of age with severe chronic lung disease due to cystic fibrosis or other etiology who require ongoing oxygen therapy or assisted ventilation in the 6 months preceding or during the RSV season; infants <12 months of age with haemodynamically significant chronic cardiopathy other than congenital; children aged 12-24 months awaiting heart transplant or having received a heart transplant within 6 months of onset of the RSV season; and children aged <24 months with severe immunodeficiency. It may also be considered for term infants aged <6 months living in remote Inuit communities with very high rates of hospitalization for RSV among term infants and for infants of < 36 weeks gestational age and age <6 months living in other remote communities with high rates of hospitalization for RSV and where air transport would be required for hospitalization. PVZ may be considered when all other measures to control a RSV outbreak in a NICU have failed.
PVZ should not be offered to otherwise healthy infants born at or after 33 wGA; or to siblings in multiple births who do not otherwise qualify for prophylaxis. It should not be offered routinely for children <24 months of age with cystic fibrosis; for children <24 months of age with Down syndrome without other criteria for PVZ; or for healthy term infants living in remote northern Inuit communities, unless hospitalization rates for RSV are very high. It should not be used for the prevention of recurrent wheezing or asthma in the absence of other indications.
PVZ should not be given to prevent hospital-associated RSV infection in eligible children who remain in hospital. It may be considered when all other measures have failed to control an RSV outbreak in a neonatal intensive care unit.

Since in Canada PVZ is not readily available for purchase, no specific recommendations are made for individual-level decision making.

3. How

The dose of PVZ is 15 mg/kg by intramuscular injection, starting with the onset of the local RSV season. Eligible children who are in hospital should receive their first dose on discharge (or within 48-72 hr before discharge to facilitate vial sharing). The interval between the first and second doses should be 21-28 days and between subsequent doses 28-35 days, for a maximum of 4 doses.
An extra dose should be given after cardiac bypass or extracorporeal membrane oxygenation. An extra dose may be considered in remote Northern areas where RSV outbreaks may continue longer than is usual elsewhere.
PVZ should be discontinued for the season if a child is hospitalized for RSV infection.
If feasible, clinics or appointments should be organized to facilitate vial sharing, to reduce costs.
PVZ is contraindicated in individuals with known significant hypersensitivity reaction to PVZ or any component of the product (humanized monoclonal antibody, glycine, histidine). Moderate to severe illness, with or without fever, is a reason to consider deferring PVZ, to avoid superimposing adverse effects from PVZ on the underlying illness, or mistakenly identifying a manifestation of the underlying illness as a complication of PVZ. The decision to delay PVZ depends on the severity and etiology of the underlying disease. Minor illnesses such as the common cold, with or without fever, are not contraindications to use of PVZ.
PVZ contains antibody only against RSV and may be co-administered with any other live or inactivated vaccines.

4. Why

PVZ is recommended for infants and young children with health conditions that make them more vulnerable to severe RSV disease requiring hospitalization and possibly admission to an intensive care unit and mechanical ventilation.

Although the risk of severe RSV disease is reduced, PVZ does not prevent all hospitalizations for RSV. It is thought to prevent 40 to 80% of hospitalizations, depending on age and underlying health condition. Therefore other means of protection against RSV (limiting exposure of high risk children to persons with cough and colds, appropriate hand hygiene, preventing exposure to cigarette smoke) are important.

Although any young child may be hospitalized with RSV, most will not have severe illness. PVZ is not recommended for children at lower risk of severe disease, in some instances because of cost, in others because of lack of information about whether it will work.

Introduction

Respiratory syncytial virus (RSV) is the most common cause of lower respiratory tract illness in young children worldwide^{Footnote 1} ^{Footnote 2}.

At present the only immunizing agent available for the prevention of serious RSV disease is PVZ, a monoclonal anti-RSV antibody. Several active vaccine candidates are currently undergoing clinical trials in infants, pregnant women and adults^{Footnote 3}. RSV vaccines will not be addressed in this Statement.

In June 2002, Health Canada approved PVZ (SynagisTM) for the prevention of serious lower respiratory tract disease caused by RSV in infants at high risk of serious RSV disease. In 2003, the National Advisory Committee on Immunization (NACI) published recommendations on the use of PVZ or the prevention of RSV disease^{Footnote 4}. At that time, NACI recommended PVZ be used during the RSV season for premature infants (less than or equal to 32 weeks' gestational age (wGA) who would be less than six months of chronological age at the start of RSV season, children less than 24 months of age with chronic lung disease of prematurity (CLD) requiring oxygen and/or medical therapy in the previous six months or other pulmonary disorders requiring oxygen therapy, and children less than 24 months of age with hemodynamically significant congenital heart disease (hsCHD). PVZ prophylaxis could also be considered for children born at less than 35 wGA who are less than 6 months of age at the start of RSV season and who live in remote northern communities^{Footnote 4}. Since the 2003 statement, NACI recommendations have been modified in the Canadian Immunization Guide (CIG) but no new Statement has been issued. From 2013, in addition to the above recommendations, the CIG stated that PVZ prophylaxis may benefit selected infants between 33 and 35 wGA who are less than 6 months of age at the start of the RSV season and may be considered for infants in this gestational age group who live in rural or remote communities according to an assessment of access to medical care (e.g., requirement for air transportation to hospital facilities) and other factors known to increase risk. In addition, PVZ prophylaxis should be considered for all Inuit children in northern remote communities who are younger than 6 months of age at the start of RSV season, regardless of wGA.

Since the publication of the NACI statement in 2003, there have been a series of updated PVZ guidance documents published by expert committees including the American Academy of Pediatrics (AAP) in 2009 and 2014^{Footnote 5} ^{Footnote 6} ^{Footnote 7} and the Canadian Paediatric Society (CPS) in 2015^{Footnote 8} which have made PVZ prophylaxis recommendations that differ significantly from the 2003 NACI guidance and highlight the need to reassess NACI’s recommendations. A summary of current criteria for PVZ eligibility in Canadian provinces and territories and in ten other northern hemisphere countries, “Recommendations for use of Palivizumab in Canada and internationally”, is presented in Appendix A.

The purpose of this document is to update previous NACI recommendations for the use of PVZ, taking into consideration recent data on burden of illness due to RSV disease, the efficacy and effectiveness of PVZ in infants at risk of more severe RSV disease and economic implications of PVZ use.

Guidance Objective:

The objective of this advisory committee statement is to review evidence and develop guidance on strategies to prevent severe consequences of RSV infection in children at high risk of severe RSV disease by administration of monoclonal antibody.

Methods

NACI's recommendation development process is described in detail elsewhere^{Footnote 9} .

In brief, the broad stages in the preparation of this NACI advisory committee statement included:

Knowledge synthesis
Synthesis of the body of evidence of benefits and harms, considering the quality of the synthesized evidence and magnitude and certainty of effects observed across the studies
Translation of evidence into recommendations.

Further information on NACI's evidence-based methods is available in: Evidence-Based Recommendations for Immunization: Methods of the NACI, January 2009, CCDR.

To meet the objective of this Statement, three systematic literature reviews were carried out using standard NACI methodology:

The burden of RSV disease in young children in high-income countries comparable to Canada

An initial search of the literature from 2000 to February 2017 retrieved 2389 records. Because of the large number of records, further assessment was limited to systematic reviews of which 6, with ratings of 6 to 7 (average) using A Measurement Tool to Assess Systematic Reviews (AMSTAR)^{Footnote 10}, were retained; there were none with higher ratings. These reviews included literature from 1995 to 2015.

A second search of the literature from 2014 to September 2018 yielded 1022 records, of which 29 were retained for final quality assessment and data extraction. The start date was chosen to provide data from the time of the 2014 AAP change in recommendation for PVZ use. Two reviewers independently assessed the risk of bias (ROB) for each study, using a modified tool based on the Quality Assessment Tool for Observational Cohort and Cross-sectional Studies and the Quality in Prognosis Studies (QUIPS). For within-study comparisons, two reviewers independently assessed the certainty of evidence for each outcome (as high, moderate, low, or very low), using the principles of Grading of Recommendations Assessment, Development and Evaluation (GRADE). Disagreements were resolved through consensus. Details of methodology and results of this search are presented in the manuscript by Wingert et al 2021^{Footnote 11} and summarized in Sections III.1 and III.2 of this Statement.

A third search, using the same strategy, of literature from September 1, 2018 to July 29, 2020 identified an additional 699 records, with 14 retained for quality assessment and data extraction.

Because search of the more recent literature did not provide data on some issues for which recommendations were needed, relevant earlier references identified in the systematic reviews or in the papers accepted from the 2014-2018 search were assessed. Fifteen studies were retained for quality assessment. Information from these studies and from the 2018-2020 search are presented in Section III.1 and III.2 of this document.
The effectiveness of PVZ prophylaxis on reducing the complications associated with RSV in infants

For details of methodology and results in the document “NACI Literature Review on the Effects of PVZ Prophylaxis on Reducing the Complications Associated with Respiratory Syncytial Virus in Infants” which will be forthcoming. Data are summarized in Section IV.2 of this Statement^{Footnote 12}.
The cost-effectiveness of PVZ prophylaxis for RSV

For details of methodology and results see “Cost-Effectiveness of PVZ Prophylaxis for Respiratory Syncytial Virus (RSV): A Systematic Review.” Data are summarized in Section V.1 of this Statement.

In addition to these systematic reviews, other literature searches included:

An environmental scan of recommendations for use of PVZ in Canadian provinces and territories and in other Northern hemisphere countries
A rapid literature review on the safety of PVZ
Informal literature reviews when information was needed to address specific questions.

Results of (4) and (5) are added to this document as Appendices A and B. Information and data from the informal reviews (6) are presented in the text of this document.

In order to develop comprehensive, appropriate immunization program recommendations, NACI considers a number of factors. In addition to critically appraising evidence on burden of disease and vaccine characteristics such as safety, efficacy, immunogenicity and effectiveness, NACI uses a published, peer-reviewed framework and evidence-informed tools to ensure that issues related to ethics, equity, feasibility, and acceptability (EEFA) are systematically assessed and integrated into its guidance^{Footnote 13}. The NACI Secretariat applied this framework with accompanying evidence-informed tools (Ethics Integrated Filters, Equity Matrix, Feasibility Matrix, Acceptability Matrix) to systematically consider these programmatic factors for the development of clear, comprehensive, appropriate recommendations for timely, transparent decision-making. For details on the development and application of NACI’s EEFA Framework and evidence-informed tools (including the Ethics Integrated Filters, Equity Matrix, Feasibility Matrix, and Acceptability Matrix), please see https://doi.org/10.1016/j.vaccine.2020.05.051.

For this Statement, NACI reviewed the key questions for the systematic literature reviews as proposed by the RSV Working Group. Following literature searches and critical appraisal of individual studies, proposed recommendations for PVZ use were developed. The RSV Working Group chair and PHAC medical specialist presented the evidence and proposed recommendations to NACI on February 5, 2020. Following thorough review of the evidence and consultation at the NACI meetings of February 5, 2020, September 24, 2020 and October 22, 2021, the committee voted on specific recommendations. The description of relevant considerations, rationale for specific decisions, and knowledge gaps are described in the text.

Epidemiology

RSV is an enveloped RNA virus belong to the family Paramyxoviridae. There are 2 subgroups based on differences in the G surface protein, and numerous genotypes within these subgroups. Humans are the only source of infection and transmission occurs from direct or indirect exposure to respiratory secretions containing the virus^{Footnote 14}.

RSV infects almost all infants by 2 years of age^{Footnote 1} ^{Footnote 2}. The most common clinical presentations of RSV in young children requiring hospitalization are bronchiolitis (an acute lower respiratory tract infection associated with tachypnea, cough, and wheezing), and pneumonia^{Footnote 14} ^{Footnote 15}. Primary infection does not confer complete protective immunity. Reinfections occur throughout life but are usually less severe, mainly presenting as upper respiratory tract illness in older children and adults^{Footnote 14}.

Hospitalization rates are highest in children < 1 year of age and especially in the first 2 months of life^{Footnote 16}. Hospitalization rates per 1000 children per year in high income countries are reported as 26.3 (95% CI 22.8, 30.2), 11.3 (95% CI 6.1, 20.9) and 1.4 (95% CI 0.9, 2.0) for age groups 0-5 months, 6-11 months and 12-59 months respectively^{Footnote 2}. In Canada, similar rates of 20, 10.2, and 4.8 per 1000 per year are reported for children aged < 6 months^{Footnote 15}, <1year, and 1-3 years, respectively^{Footnote 17}. In Ontario, 9% of annual hospital admissions of children <1 year of age were attributed to RSV^{Footnote 17}. The case-fatality rate in high income countries is usually <0.5%, with higher rates in infants with co-morbidities^{Footnote 1} ^{Footnote 18}. Eighty-two percent of deaths in one Canadian study were in children with underlying risk factors for severe RSV disease^{Footnote 19}.

Most children less than 2 years of age hospitalized with RSV infection have no co-morbidities^{Footnote 1} ^{Footnote 17}, but higher rates and durations of hospitalization and more intensive care unit admissions have been reported in premature infants and in those with CLD or CHD^{Footnote 1} ^{Footnote 8} ^{Footnote 17}. Children with other lung diseases not associated with prematurity such as cystic fibrosis^{Footnote 20} or with other chronic conditions including immunodeficiency^{Footnote 21} ^{Footnote 22} and children living in indigenous communities in the far north^{Footnote 23} may also be at increased risk of severe RSV disease. RSV is being increasingly recognized as an important cause of morbidity and mortality in the elderly^{Footnote 24}.

In temperate climates, RSV causes epidemics every winter. In Canada the RSV season typically begins in October or November and lasts until April or May, with most cases occurring in December through March^{Footnote 25}. Studies of temporal trends in RSV hospitalization rates have shown conflicting results, likely due to differences in testing policies, sensitivity of diagnostic tests used, and criteria for hospitalization^{Footnote 1}. One recent US study reported decreased RSV hospitalization rates from 1997 to 2012 for all infants and for infants with CLD and high risk CHD but not for other high risk infants^{Footnote 26}.

III.1 Burden of disease in specific high risk groups

Data from the burden of RSV illness systematic review performed for the development of this statement are summarized and integrated into the relevant sections below. In view of the small numbers of articles identified and heterogeneity in the methodology used and outcomes studied, the interpretation of the findings must be viewed with caution. Information from earlier studies and from the 2018-2020 literature review is also presented here.

III.1.1 Preterm infants without CHD or CLD

IIII.1.1.1 Hospitalization

Risk of hospitalization for RSV infection increases with lower gestational age. In a prospective population-based study of young children hospitalized with laboratory confirmed RSV lower respiratory tract disease from 2000-2005, Hall et al. reported RSV hospitalization (RSVH) rates per 1000 infants < 24 months of age of 19.3, 18.7, 6.3, 6.9, and 5.3 for gestational ages of <29, 29-31, 32-34,≥ 35 weeks and term infants respectively. In their study, 38% of the infants had other high risk conditions and 20% received PVZ^{Footnote 16}.

The systematic literature review on the burden of RSV disease in young children (BODsr), limited to publications from 2014 to September 2018, and the 2020 updated review yielded no studies of burden of RSV illness in premature infants of <29 wGA. Data from studies of less premature infants are summarized here.

In study-level comparisons, one study of moderate to low certainty of evidence (COE) found similar RSVH rates for infants of 29-32 wGA and 33-36 wGA during their first RSV season (RR 1.20, 95% CI 0.92, 1.56)^{Footnote 27}. Another, also rated as moderate to low COE, found a relative risk of RSVH of 2.05 (95% CI 1.89, 2.22) between infants of 33-36 wGA and term infants age <24 months^{Footnote 28}. Very low COE was found for RSVH in one study of infants <33 wGA compared to term infants in their first RSV season (RR 3.88, 95% CI 1.13, 13.30)^{Footnote 29}.

Single arm pooled proportions for RSVH (Table 1) were 5.1%, 2.8%, 3.3% and 4.1 for infants of 29 to <33 wGA^{Footnote 27} ^{Footnote 29} 32-34 wGA^{Footnote 30}, 32/33 to 35 wGA^{Footnote 27} ^{Footnote 28} ^{Footnote 30} ^{Footnote 31} ^{Footnote 32} ^{Footnote 33} ^{Footnote 34} ^{Footnote 35} and 35 wGA^{Footnote 30} respectively. RSVH rate for healthy term infants was 1.2%. Three of four studies in this group reported RSVH during the first year of life (0.8% to 1.5%) ^{Footnote 29} ^{Footnote 36} ^{Footnote 37}, and one study reported RSVH to age 24 months (1.3%)^{Footnote 28}.

Table 1. RSV hospitalizations: single arm pooled proportions by gestational age
wGA	% RSVH	95% CI	No. studies	Risk of bias
29 - <33^{Footnote 27} ^{Footnote 29}	5.1	4.0, 6.3	2	Moderate
32 - 34^{Footnote 30}	2.8	1.6, 4.0	1	High
32/33 – 35 ^{Footnote 27} ^{Footnote 28} ^{Footnote 30} ^{Footnote 31} ^{Footnote 32} ^{Footnote 33} ^{Footnote 34} ^{Footnote 35}	3.3	2.7, 4.1	8	Moderate (5), High (3)
35^{Footnote 30}	4.1	2.8, 5.4	1	High
Healthy term ^{Footnote 28} ^{Footnote 29} ^{Footnote 36} ^{Footnote 37}	1.2	1.1, 1.2	4	Moderate

Between-study comparisons using pooled data (all assessed by GRADE at very low COE due to the indirect nature of the evidence) showed RR for RSVH for premature infants versus term infants of 4.3 (95% CI 3.7, 4.8, p=0.000) for infants of 29-32 to <33 wGA and 2.8 (95% CI 2.5, 3.1, p=0.000) for infants of 32-35 wGA. Actual risk differences were 3.9% (95% CI 2.7, 5.1) and 2.1% (95% CI 1.4, 2.8) respectively.

The 2020 literature update identified two studies that reported on RSVH in otherwise healthy premature infants. In a multinational RCT assessing efficacy of nirsevimab (a new monoclonal antibody active against RSV), RSVH rates in the 150 days following administration of placebo were 4.3% and 4.0 % in infants of ≥29 to ≤32 wGA and > 32 wGA respectively (ROB low)^{Footnote 38}. RSVH rate during RSV season was 3.4% in infants of 33-35 wGA in a 2015-2017 retrospective cohort study in Quebec by Papenburg et al. (ROB moderate)^{Footnote 39}. In addition, a systematic review, rated by AMSTAR as average, reported on seven observational prospective studies carried out between 2000 and 2008. The pooled RSVH rate for otherwise healthy infants of 33-<35 wGA was 3.4% or 5.5 per 100 patient-seasons^{Footnote 40}.

Earlier literature was reviewed for data about more severely premature infants. RSVH rates for infants during their first RSV season in the placebo arm of a 1996-1997 PVZ RCT were (% and 95% CI) 10.0 (2.8, 23.7), 7.7 (3.6, 14.1), 10.1 (5.1, 17.3) and 8.2 (3.1, 17) for gestational ages of <29, 29-32, 32-35, and 33-35 weeks respectively (ROB low)^{Footnote 41}. In a historical cohort study from the pre- PVZ era, Stevens et al. reported RSVH rates to 1 year corrected age in premature infants without CLD of 10.2%, 8.6%, 6.8%, and 4.3% for infants of ≤ 26, 27-28, >28-30 and >30-32 weeks of gestational age (wGA) respectively. For all infants of ≤ 30 wGA, RSVH rate was 8.1% (ROB moderate)^{Footnote 42} Boyce et al., using Tennessee Medicaid data from 1989-93, estimated RSVH rates in the first 6 months of life of 93.8, 81.8 and 79.8 per 1000 children for infants of ≤ 28, 29 to <33 and 33 to <36 wGA respectively and 44.1 per 1000 children for low risk infants (term infants without CLD or CHD or other chronic disease). Hospitalization rates in the second 6 months of life were 46.1, 50 and 34.5 per 1000 children for those of ≤ 28, 29 to <33 and 33 to 36 wGA respectively and 15 for low risk infants (ROB moderate)^{Footnote 43}. Other observational studies, ROB low^{Footnote 44} or moderate ^{Footnote 45} ^{Footnote 46} ^{Footnote 47}, have reported RSVH rates of 10.4%, 7.7%, 13% and 13.5% in the first year of life for infants born at <29, <28, <29 or ≤30 wGA without other co-morbidities. These early preterm infants receive little or no maternal antibody and their narrower airway passages increase their vulnerability to the effects of RSV infection.

Infants of 29-32 wGA are also at increased risk of RSVH in comparison to healthy term infants but RSVH rates are lower than those for more premature infants, at 5.7 to 9.9% in their first RSV season (ROB moderate)^{Footnote 45} ^{Footnote 46}. Infants of 32 or 33 to 35 wGA have reported RSVH rates of 2.8 to 6.5% in their first year of life or first RSV season (ROB moderate)^{Footnote 45} ^{Footnote 48}. In the study of Boyce et al., RSVH rates for premature infants in the second 6 months of life were similar to those for low risk term infants in the first 6 months (ROB moderate)^{Footnote 43}. In another study, RSVH rates for preterm infants of 32-34 of wGA (20% of whom received PVZ), were similar to those of 1 month old term infants by 4.2 - 4.5 months of age (ROB moderate)^{Footnote 49}.

Chronological age is an important risk factor for RSVH (ROB moderate) ^{Footnote 16} ^{Footnote 43} ^{Footnote 49} with overall RSVH rates highest at age <3 months^{Footnote 16}.

III.1.1.2 Length of stay for RSVH

From the BODsr, study-level comparison of length of hospital stay (LOS) was available in two studies. In one, of moderate to low COE, the mean difference in LOS between infants age <24 months of 33-36 wGA and term infants was 1.0 day (95% CI 0.88, 1.12)^{Footnote 28} while in the other, of very low COE, the mean difference in LOS between infants age <12 months of 29-32 wGA and 33-35 wGA was 4.0 days (95% CI 1.54, 6.46)^{Footnote 50}.

Mean LOS from pooled single arm studies were 10 days, 7.7 days, 5.5 days, 4.5 days and 7 days, for 29 to 32 wGA^{Footnote 50}, 29 to 34/35 wGA^{Footnote 50} ^{Footnote 51}, 33-34 wGA^{Footnote 28} ^{Footnote 50}, 32/33 to 35 wGA^{Footnote 28} ^{Footnote 30} ^{Footnote 33} and 35 wGA^{Footnote 50} respectively. LOS for healthy term infants was 3.5 days ^{Footnote 28} ^{Footnote 37} ^{Footnote 52} ^{Footnote 53}. (Table 2)

Table 2. RSVH LOS: Single arm pooled hospital LOS by gestational age
wGA	Mean LOS (days)	95% CI	No. studies	Risk of bias
29 - 32^{Footnote 50}	10.0	7.7,12.3	1	Moderate
29-34/35^{Footnote 50} ^{Footnote 51}	7.7	6.1,9.2	2	Moderate
33 - 34^{Footnote 28} ^{Footnote 50}	5.5	0.6-10.4	2	Moderate, Low
32/33 - 35 ^{Footnote 28} ^{Footnote 30} ^{Footnote 33}	4.5	2.3-6.8	3	Moderate (1), Low (2)
35^{Footnote 50}	7.0	4.9-9.1	1	Moderate
Healthy term^{Footnote 28} ^{Footnote 37} ^{Footnote 52} ^{Footnote 53}	3.5	2.3,4.7	4	High (1), Moderate (2), Low (1)

Between-study comparisons (all at very low COE) using pooled data showed mean differences in LOS between premature versus term infants of 6.5 days (95% CI 3.9, 9.1, p<0.000), 1.0 days (95% CI -8.6, 10.6) and 4.2 days (95% CI -5.3, 13.7) for infants of 29-32 wGA, 32/33-35 wGA, and 29-35 wGA respectively.

The 2020 literature update identified three studies that reported this outcome. Median LOS was 7.0 days (range 2-20) in 29-<36 wGA infants (ROB low)^{Footnote 38} and 7.0 days (IQR 3-12) in 29-34 wGA infants (ROB moderate)^{Footnote 54}. Anderson et al. reported median LOS of 6 (IQR 3-11), 5 (IQR 3-10) and 5 (IQR 3-8) days in infants of 29-32 wGA, 33-34 wGA and 35 wGA respectively (ROB low)^{Footnote 55}. In addition, and for comparison, four studies reported LOS for healthy term infants. Median LOS was 4 days (range 1-23) (ROB moderate)^{Footnote 56} and 1.9 days (IQR 1.1-2.9) (ROB low)^{Footnote 57}. Mean (SD) LOS was 5 (2.2) days (ROB moderate)^{Footnote 58} and 5.9 (2.99), 5.4 (2.89) and 5.84 (3.13) days for different RSV genotypes in a study by Midulla et al. (ROB low)^{Footnote 59}.

In earlier literature, premature infants have also been reported to have longer median hospital stays than term infants^{Footnote 60}. In a prospective cohort study in 2008-9, infants of 28 to < 33 wGA with confirmed RSVH had a mean LOS of 7.2 ± 3.3 days (ROB low)^{Footnote 61}.

III.1.1.3. ICU admission and mechanical ventilation

In the BODsr, one study looked at ICU admission, ICU LOS, mechanical ventilation (MV) and duration of MV in infants of 29-32 versus 33-35 wGA. There was no significant difference in any of these parameters (low to very low COE)^{Footnote 50}.

Single arm pooled proportions of patients hospitalized for RSV that were admitted to ICU were 51.7, 19.1, 31.5 and 13.9 for infants of 29-32 wGA^{Footnote 50}, 32-34 wGA^{Footnote 30}, 32-35 wGA ^{Footnote 30} ^{Footnote 35} ^{Footnote 50} and 35 wGA^{Footnote 30}, respectively. Rate of ICU admission for hospitalized healthy term infants was 15.8% ^{Footnote 37} ^{Footnote 52} ^{Footnote 53}. (Table 3)

Table 3. Hospitalizations for RSV: Single arm pooled proportions admitted to ICU by gestational age
wGA	% ICU	95% CI	No. studies	Risk of bias
29 - 32^{Footnote 50}	51.7	41.3, 62.1	1	Moderate
33 - 34^{Footnote 30}	19.1	2.3, 35.8	1	Moderate
32 - 35 ^{Footnote 30} ^{Footnote 35} ^{Footnote 50}	31.5	13.1, 53.6	3	Moderate (2) Low (1)
35^{Footnote 30}	13.9	2.6, 25.2	1	Moderate
Healthy term^{Footnote 37} ^{Footnote 52} ^{Footnote 53}	15.8	5.4, 30.0	3	Moderate (2), High (1)

Between-study comparisons (all at very low COE) using pooled data showed RR for ICU admission among hospitalized premature versus term infants of 3.3 (95% CI 1.9, 5.7, p=0.000), 2.0 (95% CI 1.0, 4.0, p=0.000) and 3.3 (95% CI 1.9, 5.6, p=0.000) for infants of 29-32 wGA, 32-35 wGA, 29-35 wGA respectively. Actual risk differences were 35.9% (95% CI 19.8, 52.0, p=0.000), 15.7% (95% CI -8.0, 39.4, p=0.194) and 36.2% (95% CI 22.5, 49.9, p=0.000) respectively.

For ICU LOS, single arm pooled data showed ICU LOS of 9.0, 7.0, and 6.7 for infants of 29-32 wGA^{Footnote 50}, 29-34/35 wGA^{Footnote 50} ^{Footnote 51} and 33-35 wGA^{Footnote 35} ^{Footnote 50} respectively. There were no studies showing ICU LOS stay for healthy term infants. (Table 4)

Table 4. RSV ICU length of stay: Single arm pooled LOS by gestational age
wGA	Mean LOS (days)	95% CI	No. studies	Risk of bias
29 - 32^{Footnote 50}	9.0	7.0, 11.0	1	Moderate
29 – 34/35^{Footnote 50} ^{Footnote 51}	7.0	4.7, 9.2	2	Moderate
33 - 35^{Footnote 35} ^{Footnote 50}	6.7	5.5, 8.0	2	Moderate, Low

Single arm pooled proportions of hospitalized patients that underwent MV were 27.0%, 22% and 14.0 for infants of 29-32 wGA^{Footnote 50}, 29-34/35 wGA^{Footnote 50} ^{Footnote 51}, 32/33-35 wGA ^{Footnote 30} ^{Footnote 35} ^{Footnote 50}, respectively. MV rate for healthy term infants was 14.0%^{Footnote 52} ^{Footnote 53}. (Table 5)

Table 5. Hospitalizations for RSV: Single arm pooled proportions undergoing MV by gestational age
wGA	% MV	95% CI	No. studies	Risk of bias
29 - 32^{Footnote 50}	27.0	17.8, 36.2	1	Moderate
29-34/35^{Footnote 50} ^{Footnote 51}	22.0	18.0, 26.0	2	Moderate
32/33 - 35^{Footnote 30} ^{Footnote 35} ^{Footnote 50}	14.0	10.0, 18.0	-3	Moderate (2), Low
Healthy term^{Footnote 52} ^{Footnote 53}	14.0	9.0-21.0	2	Moderate, High

Between-study comparisons (all at very low COE) using pooled data showed RR for MV among hospitalized premature versus term infants of 1.9 (95% CI 1.4, 2.6, p<0.000), 2.3 (95% CI 1.8, 2.9, p<0.000) and 1.0 (95% CI 0.76, 1.32, p<-.000) for infants of 29-32 wGA, 29-35 wGA and 33-35 wGA respectively. Actual risk differences were 13.0% (2.0, 24.0, p=0.020), 18.0% (9.9, 26.1, p=0.000) and 0.00% (-7.2, 7.2, p=1.000) respectively.

Mean duration of MV from pooled single arm studies was 10 days (95% CI 7.6, 12.4), 8.6 days (95% CI 7.3, 9.8) and 6.5 days (95% CI 3.5, 9.4) for infants of 29-32 wGA (one study, ROB moderate)^{Footnote 50}, 29-35 wGA (two studies, moderate ROB)^{Footnote 50} ^{Footnote 51} and 33-35 wGA (two studies, ROB moderate, low)^{Footnote 35},^{Footnote 50} respectively. There were no studies reporting duration of MV for healthy term infants.

The 2020 literature search update identified three studies that reported on ICU admission. ICU care among infants with RSVH was 25% of infants of 29-<35 wGA (ROB low)^{Footnote 38}, 64.2% of infants of 29-34 wGA (ROB moderate)^{Footnote 54} and 48%, 46% and 49% of infants of 28-32, 33-34, and 35 wGA respectively (ROB low).^{Footnote 55} Six studies reported on ICU care for healthy term infants. Percentages were 29%^{Footnote 57}, 43.3%^{Footnote 62}, 20%^{Footnote 63} and 9%^{Footnote 59} in studies of ROB low and 3.4%^{Footnote 56} and 2%^{Footnote 58} in studies of moderate ROB.

Median (IQR) ICU LOS was 6 days in infants of 29-34 wGA (ROB moderate)^{Footnote 54} and 6 (3-11) 5 (3-10) and 5 (3-6) days for infants of 29-32, 33-34 and 35 wGA respectively (ROB low)^{Footnote 55}. For healthy term infants median ICU LOS was reported as 4 days (IQR 3, 7.6) (ROB low)^{Footnote 57} and 0 days (range 0-15) (moderate ROB)^{Footnote 56}.

MV among infants with RSVH was 5% for infants of 29-<35 wGA (ROB low)^{Footnote 38}, 31.8% for infants of 29-34 wGA (moderate ROB)^{Footnote 54}, and 22%, 20% and 15% for infants of 28-32, 33-34, and 35 wGA respectively (ROB low)^{Footnote 55}.

In earlier literature, premature infants have also been reported to have an increased risk for ICU admission compared to term infants^{Footnote 60}. In a prospective cohort study in 2008-9, 5.9% of infants of 28 to < 33 wGA required admission to the ICU (ROB low)^{Footnote 61}. A later systematic review of studies from 2000-2014, rated as average by AMSTAR, of infants of 33-35 wGA without comorbidities reported that 22.2% of infants required ICU admission for a median of 8.3 days and 12.7% required MV for a median of 4.8 days^{Footnote 40}. Younger age is associated with higher rates of ICU admission. In a report of infants of 32-35 wGA, no infants >6 months of age required intensive care, but 14% of those aged 3 to <6 months and 27% of those aged < 3 months were admitted to ICU (actual ages)^{Footnote 64}.

III.1.1.4. Mortality

In a meta-analysis of studies from 1990-2007, all-cause mortality during their first RSV season was 0.99% and 0.13% for infants of ≤32 wGA and 32-35 wGA respectively. RSV attributable mortality was 0.03% for the two groups combined (AMSTAR rating average)^{Footnote 65}. In another systematic review of literature from 1975 to 2011, the weighted mean case fatality rate for children aged ≤ 24 months hospitalized with RSV was 1.2% (range, 0–8.3%; median, 0%; n = 10) for preterm infants <37 wGA versus a weighted mean of 0.2% (range 0-1.5%; median, 0.0%; n = 6) for children with no risk factors for severe RSV (AMSTAR rating poor)^{Footnote 66}. In the BODsr, one study of very low COE reported one death attributed to RSV in infants of 29-32 wGA and no deaths in the 33-35 wGA group, not significantly different^{Footnote 50}.

III.1.1.5. Risk scores

While prematurity of any degree may increase risk of RSV hospitalization to some extent, providing prophylaxis for all is not feasible. In Canada 7.7-8.0% of births annually are of < 37 wGA^{Footnote 67} and it has been estimated that 5% of the birth cohort may be born at 32-35 wGA^{Footnote 34}. Risk scores have been developed in attempts to identify otherwise healthy premature infants of > 29-30 wGA or > 32 wGA who are at significantly increased risk of severe RSV disease, which are currently used in several Canadian provinces and territories and internationally (see Appendix A below). The risk factors identified as significant and used in these risk scores vary widely. The validity of such scores, especially those validated with data from several years ago or from different geographical settings, has been questioned ^{Footnote 7} ^{Footnote 34} ^{Footnote 68} ^{Footnote 69} ^{Footnote 70} ^{Footnote 71}.

Young chronological age during the RSV season is the most consistent risk factor identified. Other factors include environmental and host factors that increase risk of exposure to RSV or of more severe RSV disease. The risk of RSV hospitalization associated with these individual factors has been difficult to determine because of inconsistent results in different studies. Most environmental and host factors increase the risk for RSVH only slightly and their individual contribution to the burden of RSV disease is limited^{Footnote 7} ^{Footnote 70}. In a multiple logistic-regression analyses of risk factors which included male gender, child care attendance, smoke exposure, lack of breastfeeding, and other children in the house, only preterm birth and young chronologic age independently correlated with more severe RSV disease after adjusting for other covariates^{Footnote 69}.

III.1.2 Chronic lung disease of prematurity and other chronic lung diseases

CLD has been defined by the AAP as "born at gestational age of <32 weeks with need for supplemental O₂ for at least the first 28 days after birth"^{Footnote 6}. Some studies defined CLD as the need for O₂ at 36 weeks post conceptual age. The BODsr and the 2020 updated literature search did not identify any studies of this risk group.

In a systematic review of data to December 2015, rated average by AMSTAR, RSVH rates for children with CLD in the first 2 years of life without prophylaxis were 12-21% with a weighted mean of 16.8%. CLD was associated with a higher rate of RSVH than other high-risk groups and was a significant independent risk factor for RSVH with odds ratios of 2.2 to 7.2^{Footnote 72}. The Canadian Paediatric Society statement reported RSVH of 6.0 to 22.6 % in studies carried out between 1995 and 2009^{Footnote 8}.

RSVH rate of 16.8% in the first year of life was reported in a 1992-6 retrospective cohort study (ROB moderate)^{Footnote 42}. RSVH rate was 12.8% for children ≤ 24 months of age with CLD in the control arm of a PVZ RCT (ROB moderate)^{Footnote 48} and 15.7 % for children within 12 months of initial discharge in the control arm of a PVZ observational study (ROB moderate)^{Footnote 44}. A 1989-93 study reported higher rates in the first year of life than in the second (38.8% vs. 7.3%) (ROB moderate)^{Footnote 43}. Winterstein et al. compared RSVH rates in infants with CLD and in healthy term infants with siblings. The peak RSVH rate for those with CLD was 15.3 /1000 patient-seasons at age 9 months. The RSVH rate for infants with CLD at 18.5 months was similar to that of healthy term infants aged 1 month (9/1000 patient-seasons)^{Footnote 73}. In that study, 42.7% of the infants with CLD had received PVZ.

There are limited data on outcomes other than hospitalization. In the systematic review of Paes, rated by AMSTAR as average, the mean length of hospital stay for RSV was 4-11 days, with one study reporting 29% of those hospitalized admitted to ICU and 24% undergoing mechanical ventilation^{Footnote 72}. In the retrospective cohort study of Stevens et al. (ROB low) the mean LOS was 9.4 days and 9.1% were admitted to ICU^{Footnote 42}. A meta-analysis, rated by AMSTAR as average, reported an all-cause mortality rate of 0.34% during the first RSV season^{Footnote 74}. In a systematic review of literature from 1975 to 2011, the weighted mean case fatality rate for infants age ≤ 24 months hospitalized with RSV was 4.1% (range, 0–10.5%; median, 7.0%; n = 6) for children with CLD (rated by AMSTAR as poor)^{Footnote 66}.

Data on RSV risk in children with chronic lung disease of etiology other than prematurity are limited. The BODsr identified two studies. Increased rates of RSVH were reported in infants < 24 months old with congenital cystic lung disease (CCLD) (8.3%, 95% CI 0.5, 16.2)^{Footnote 75} (ROB moderate) and in children with chronic interstitial lung disease (chILD) receiving corticosteroids (30%, 95% CI 9.9, 50.1)^{Footnote 76} (ROB high). In between-study comparisons (all at very low COE), RR for RSVH in comparison to term infants ^{Footnote 28} ^{Footnote 29} ^{Footnote 36} ^{Footnote 37} (all ROB moderate) were 6.9 (95% CI 5.3, 8.9, p=0.000) for CCLD, and 25.0 (95% CI 14.3, 43.6 p=0.000) for chILD. Actual risk differences were 7.1% (95% CI 1.5, 12.7 p=0.013) for CCLD and 28.8(95% CI 8.7, 48.9, p=0.005) for chILD. Mean LOS was 11.25 days (95% CI 9.29, 13.21) for CCLD (ROB low), and 6 days (95% CI -0.6, 12.6) for chILD (ROB moderate). In between-study comparisons (very low COE), mean differences in LOS versus term infants were 7.8 days (95% CI -1.8, 17.3, p<0.112) for CCLD and 2.5 days (95% CI -4.2, 9.2 p=0.465) for chILD. None of the patients in these two studies were admitted to ICU because of RSV.

In an earlier report, Kristensen et al. reported RSVH rates for children age < 24 months with chILD (27.3%), congenital lung malformations (13.7%), other congenital airway abnormalities (8.3%, 9.3%) and some neuromuscular conditions that affect ability to clear airway secretions (9.9%-15.9%), while the overall rate in the population of this age was 2.8% (ROB moderate)^{Footnote 21}.

III.1.3 Cystic fibrosis

The BODsr identified two studies of infants with cystic fibrosis (CF). Pooled proportion for RSVH was 12.3% (95% CI 1.3, 30.8) (ROB high)^{Footnote 77} ^{Footnote 78}. In between-study comparisons, RR for RSVH in comparison to term infants was 10.3 (95% CI 3.3, 31.6, p<0.000) and actual risk difference was 11.1% (95% CI -3.7, 25.9, p=0.140). One study, with a small number of admissions, reported a mean LOS of 47.00 (12.53, 81.47) (ROB moderate) much higher than in previously published studies but not commented on by the authors^{Footnote 77}. The other study (moderate ROB) reported a mean LOS of 10 days^{Footnote 78}. Due to a lack of data (standard deviation not reported by Groves et al), pooling was not conducted from these studies for this outcome.

In the study of Bjornson, the proportion of the population at risk that was admitted to ICU because of RSV was 2.4% (95% CI -0.9, 5.6) (ROB moderate)^{Footnote 77}. Of the 5 admitted to hospital, 2 were admitted to ICU (40%) and one required mechanical ventilation. Mean duration of ICU admission was 5.00 days (95% CI -2.84, 12.84) (ROB moderate)^{Footnote 77}. The other study did not report on ICU admissions^{Footnote 78}.

Earlier reports also indicate that RSVH occurs more frequently in children with cystic fibrosis than in healthy children. In a systematic review rated as average by AMSTAR, rates of RSVH were 6.4-18.1%, 2.5-4.3 times higher than in healthy children. Average LOS was 2-11 days and ICU admission was reported in 12.5 % (1 of 8 hospitalized patients)^{Footnote 22}. Another systematic review of PVZ prophylaxis in cystic fibrosis, rated as good by AMSTAR, reported RSVH rates in patients not receiving PVZ of 7.5-11.7%^{Footnote 20}.

III.1.4 Congenital heart disease

Children with hsCHD were at high risk of RSV morbidity and mortality in the era when corrective surgery was usually delayed. As repair early in infancy became the norm, the risk of severe RSV disease is expected to have decreased although data to support this are sparse. A US study showed decreasing RSVH rates before PVZ prophylaxis was recommended for this group of patients^{Footnote 79}.

The BODsr identified one study of children with hsCHD. Using combined data from 1997 and 2000, RSVH incidence per 1000 births of infants with hsCHD was 23 (95% CI 20, 26) (ROB moderate)^{Footnote 79}. Between-study comparison with RSVH rates for healthy term infants could not be made. For other reported hospitalization-related outcomes, only combined data including years after PVZ became available was presented, and therefore these outcomes were excluded from analysis.

In earlier studies, a systematic review of data from 1995 to 2015, rated as average by AMSTAR, reported RSVH rates of 3.8 to 10.2 % in children < 2 years of age with hsCHD^{Footnote 65}. The Canadian Paediatric Society statement reported RSVH rates of 1.3 to 15% in studies carried out between 1992 and 2008^{Footnote 8}.

RSVH rates decreases with age. Rates in the placebo arm of a 1998-2002 RCT were 9.7% for all infants (< 24 months old), 12.2% for infants < 6 months old, 7.3% for those 6 to 12 months old and 4.3% for those 1-2 years old (ROB low)^{Footnote 80}. In observational studies, the RSV hospitalization rate in infants with hsCHD is also significantly higher in those aged <12 months than in those aged 12-24 months. In the study identified in the BODsr, reporting on RSVH in the USA from 1997 to 2012 and spanning the pre and post PVZ eras, 85% of hospitalizations occurred in the 1st year of life^{Footnote 79}. Chiu et al. in Taiwan in 2005-10 reported RSVH rates of 4.8% and 2.1% with cyanotic and acyanotic hsCHD respectively in the first year of life and 0.9% and 0.56% in the second year (ROB moderate)^{Footnote 81}. Resch reported a 9.6% hospitalization rate in 2004-08 study including children with hsCHD and non-hemodynamically significant CHD, some of whom received PVZ, with 56 of 58 infections occurring in the 1st year of life^{Footnote 82}. In a study of children with CHD (not necessarily hemodynamically significant) using Medicaid data from 1989-93, estimated RSVH rate was 9.2% in the 1st year and 1.8% in the 2nd year (ROB moderate)^{Footnote 43}.

In the systematic review of Checchia, median LOS for RSVH for children with hsCHD was 7 to 9.7 days. The proportion of hospitalised patients admitted to ICU was 30.4 - 46%, median ICU LOS was 10 days and the proportion receiving mechanical ventilation was 30%^{Footnote 65}. In the placebo arm of the1998-2002 RCT, mean LOS was 13.3 days, 38.1% of those hospitalized were admitted to ICU for a mean of 19.2 days and 22.2% required MV for a mean of 25.3 days (ROB low)^{Footnote 80}. In the study of Chu, children with hsCHD (with or without PVZ prophylaxis) hospitalized for RSV had longer mean hospital LOS (12.1 versus 3.4 days, p<0.001), higher rates of MV (21.9% vs 2.3%, p<0.001) and higher rates of respiratory syncytial virus-associated mortality (2.8 versus 0.1%, p<0.001) when compared with children without hsCHD^{Footnote 79}.

Feltes et al. reported RSV-related deaths among hospitalized infants with hsCHD of 0.6% (ROB low)^{Footnote 80}. In a meta-analysis of studies from 1990 to 2007 all-cause mortality rate in the first RSV season was 4.17% and RSV-attributable mortality was 0.62% (AMSTAR rating average)^{Footnote 74}. In a systematic review of literature from 1975 to 2011, the weighted mean case fatality rate for infants age ≤ 24 months hospitalized with RSV was 5.2% (range, 2.0–37.0%; median, 5.9%; n = 7) for children with CHD (AMSTAR rating poor)^{Footnote 66}.

III.1.5 Down syndrome

There is evidence that children with Down syndrome have a higher risk of RSVH than healthy children. This increase is partially explained by co-morbidities such as CHD, CLD or prematurity. Excluding children with these comorbidities, risk remains increased. Possible explanations for this include anatomic abnormalities of the upper respiratory tract, airway malacia, swallowing dysfunction, hypotonia and immune dysfunction^{Footnote 83}.

The BODsr did not identify any studies of children with Down syndrome that were limited to those < 2 years of age. A single observational study of moderate COE comparing RSV outcomes in children with Down syndrome and healthy children < 3 years of age was identified. For children with Down sndrome and no other risk factors for severe RSV, RSVH rate was reported to be 2%, vs 1.1% in healthy controls, but the RSVH data had some inconsistencies and could not be further assessed. The median LOS was 5 days versus 2 days for healthy controls (mean difference 3.00 days, 95% CI 1.95, 4.05) (low COE)^{Footnote 84}.

A meta-analysis published in 2018 of studies to May 2017, rated by AMSTAR as average, reported a pooled odds ratio (OR) for RSVH in comparison with healthy controls of 8.69 (95% CI 7.33, 10.30) for all cases of Down syndrome and a pooled OR of 16.66 (95% CI 7.22, 38.46) when only studies that excluded children with other known risk factors for severe RSV were included (2 studies). Actual RSVH rates in this subgroup were 7.6 and 9.7%. Children with Down syndrome, including those with known risk factors for severe RSV, had increased LOS (pooled mean difference 4.73 days; 95% CI 2.12, 7.33), oxygen requirement (pooled OR 6.53; 95% CI 2.22, 19.19); ICU admission (pooled OR: 2.56 95% CI 1.17, 5.59) and need for mechanical ventilation (pooled OR 4.56; 95% CI 2.17, 9.58) and RSV associated mortality rate (pooled OR 9.4; 95% CI 2.26, 39.15) vs control infants without Down syndrome^{Footnote 83}. The authors report that in the single study that included only infants with no other risk factors, there was no mortality and LOS, oxygen need, ICU admission and mechanical ventilation did not differ from those reported for the whole group. An earlier systematic review (1995-2015), rated by AMSTAR as average, reported RSVH rates of 3.6 – 13.5% in infants with Down syndrome and no other known risk factors for severe RSV. Risk ratio vs healthy infants was 3.5-10.5 and average LOS was 4-5 days^{Footnote 22}.

III.1.6. Immunocompromised children

RSV can cause significant morbidity and mortality in immunocompromised children. Serum and secretory antibodies are important in preventing RSV infection and T cells are required to efficiently clear the virus. There is very little population based data on the burden of RSV disease in this group. Although most infections occur in young children, immunocompromised older children and adults are also at risk of severe RSV disease and death. Morbidity varies by severity of immunocompromised^{Footnote 22}.

The BODsr identified two studies of immunocompromised children. A USA multicenter study in 2004-2012 reported on RSV hospitalization in liver transplant recipients <18 years of age^{Footnote 85}. Multivariate analyses identified age <2 years at transplant as a predictor of RSVH (p<0.001). RSVH rate in the first 2 years post- transplant (for all aged <18 years) was 5.3% (95% CI 4.4, 6.2) (ROB moderate). Between-study comparisons (all at very low COE) showed a RR for RSVH of 4.4 (95% CI 4.0, 4.9, p<0.000) versus healthy term infants. Actual risk difference was 4.1% (95% CI 3.2, 5.04, p=0.000). The proportion of hospitalized patients that were admitted to ICU was 22.2% (95% CI 15.2, 29.2) (ROB low). RR for ICU admission among those hospitalized for RSV was 1.4 (95% CI 0.8, 2.5, p=0.242, very low COE) versus healthy term infants. Actual risk difference was 6.4% (95% CI -7.8, 20.6, p=0.375; very low COE). Of those admitted to hospital, 10.4 % (95% CI 5.2, 15.5), received MV (ROB low). RR for MV amongst those admitted to hospital was 0.7 (95% CI 0.5, 1.1, p=0.156) versus healthy term infants, with actual risk difference of -3.6% (95% CI -11.5, 4.3, p=0.372, all at very low COE)^{Footnote 85}.

The second study was of RSV infections in children less than 18 years of age with sickle cell disease. This single center retrospective study reported a RSVH rate of 63 per 1000 person-years (95% CI 44, 87) for children < 2 years of age (ROB moderate). Other outcomes (LOS, ICU admission, mechanical ventilation), were reported only for all children aged less than 18 years and did not differ significantly from those of healthy term infants age < 2 years^{Footnote 86}.

An earlier systematic review, rated as average by AMSTAR, reported that most RSV infections in haematopoietic stem cell and solid organ transplant recipients occur in the first 2 years after transplant. Immunocompromised children < 2 years of age with RSVH had a median LOS of 7 and 10 days, with ICU admission occurring in 13% and 19.1% and intubation and/or mechanical ventilation in 3% and 14.3%. Overall, case fatality rates were 0% and 4.8%^{Footnote 22}. In a Danish study of children less than 2 years old, carried out in 1997-2003, rates of first hospitalization for RSV were 21.3% in children with congenital immunodeficiencies and 8.4% in children with cancer, while the overall rate in the population of this age was 2.8%. Duration of hospitalization was not increased (ROB moderate)^{Footnote 21}.

El Saleeby et al. reported on RSV infections in 58 individuals aged < 21 years with cancer in Tennessee between 1997 and 2005. In multivariate analysis, age ≤ 2 years and absolute lymphocyte counts of < 100/mm3 at the time of RSV infection were found to be independent predictors of the development of LRTI, with OR of 9.84 (95% CI 1.95, 49.8) and 7.17 (95% CI 1.17, 44.03) respectively. These factors were also significantly associated with death^{Footnote 87}. In a Seattle study of HSCT recipients, the majority of whom were adults, absolute lymphocyte count of ≤100 / mm3 at the time of symptom onset was a risk factor for RSV disease progression^{Footnote 88}.

III.1.7 Children residing in remote communities

The BODsr identified two studies of infants in remote communities. Data from the two studies were not pooled due to differences in study design and patient populations.

One study of infants living in Canadian northern Inuit communities, carried out in 2009, (about 20% of the birth cohort, with or without prematurity or co-morbidities) reported an overall RSVH rate of 66.9 admissions per 1000 live births per year among children <1 year of age (ROB high), with regional RSVH rates of 2.0% in the Northwest Territories, 7.5% in Nunavut, and 17.6% in Nunavik. In different areas of Nunavut rates were 19.5%, 9.1% and 3.7%^{Footnote 23}.

The second was a study of healthy term Native American infants living on reservations in southwestern USA^{Footnote 89}. The RSVH rate was 12.8% (95% CI 10.1, 15.5) (ROB high). In between-study comparisons (very low COE), RR for RSVH was 10.7 (95% CI 9.4, 12.1, p<0.000). Actual risk difference was 11.6% (95% CI 8.9, 14.3, p=0.000). Mean LOS was 4.7 days (95% CI 4.2, 5.2) (ROB moderate). Mean difference in LOS versus healthy term infants was 1.2 days (95% CI -0.10, 2.5), p<0.802, very low COE). The proportion of hospitalized patients that were admitted to the ICU (ROB moderate) was 6.3% (95% CI 1.0, 11.6). RR for ICU admission was 0.4 (95% CI 0.04, 1.2, p=0.091). The actual risk difference was -9.5% (95% CI -22.9, 3.9, p=0.164). Mean ICU LOS 5.2 days (95% CI 2.1, 8.3) (ROB moderate). Mechanical ventilation was required for 2.5% of hospitalized patients (95% CI 0.9, 5.9) (ROB moderate) for a mean duration of 6.5 days (95% CI 3.6, 9.4) (ROB moderate).

The 2020 literature search update did not identify any studies of populations living in remote communities. Subsequent to that search, results of a recent observational study from Nunavik, Quebec became available (ROB high)^{Footnote 90}. RSVH rates for 2013-2019 was 5.0% for all infants < 1 year of age (7.3% after adjustment for possible under detection by rapid antigen test compared to PCR), a much lower rate than that reported in 2009^{Footnote 91}.

Previous studies indicate that children living in remote northern Inuit communities have high rates of RSV infection. In 2002, 16.6% of Baffin Island infants less than 1 year of age were admitted to Baffin Regional Hospital for RSV (ROB moderate). Rates ranged from 6.3% for infants from Iqaluit to 34.9% for infants from high risk rural communities. For infants of less than 6 months of age, overall RSVH rate was 25% and was 51% in high risk communities^{Footnote 91}. Singleton et al. reported the YK district of Alaska as having the highest rate of RSVH in the world, with 43.9% of premature infants and 14.8% of term infants < 1 year of age hospitalized annually in the pre-PVZ era (ROB high)^{Footnote 92}. These rates are many fold higher than the overall rates of 1-2% for term infants reported in developed countries and the infected infants frequently require air transfer to community hospitals or to tertiary care institutions.

Data on the burden of RSV illness in children living in other aboriginal communities in North America is very limited^{Footnote 93} and there is no information for other remote communities.

III.1.8 Other high risk infants

The BODsr and the 2020 literature search update did not identify any additional groups at risk for severe RSV disease.

III.2 RSV infection and long term sequelae: recurrent wheezing, asthma and pulmonary function

Several studies have shown RSV LRTI in early life to be associated with recurrent wheezing in childhood. Some studies suggest that post RSV recurrent wheezing is transient, with wheezing decreasing to background levels over the first decade^{Footnote 94}. Whether RSV in infancy predisposes to the development of asthma, or if infants genetically predisposed to develop asthma are at increased risk of severe RSV disease in infancy, is not known^{Footnote 95} but there is some indirect evidence for the latter. In a prospective cohort of healthy term newborns, infants who later developed severe RSV infection and post-RSV wheezing had lower results on pulmonary function tests in the neonatal period than those that did not^{Footnote 36}, and another study showed bronchial hyper-responsiveness in otherwise healthy term neonates who later developed severe bronchiolitis^{Footnote 96}. Genetic factors predisposing to severe RSV have been described^{Footnote 94} ^{Footnote 95}. An association between early rhinovirus infection and asthma has been reported^{Footnote 95}, as well as an association between asthma and the frequency of respiratory viral infections in early life rather than any specific etiology^{Footnote 97}. A recent World Health Organization review determined that the evidence is inconclusive in establishing a causal association between RSV lower respiratory tract infection and recurrent wheezing in childhood or asthma and that the evidence does not establish that RSV monoclonal antibody will have a substantial effect on these outcomes^{Footnote 98}.

The BODsr identified 6 studies that assessed long term respiratory sequelae of RSV infection in infancy.

A study of children born at 32-35 wGA with or without RSVH at < 12 months of age found small increases in the proportions with parent or physician reported simple wheeze (< 3 episodes within 12 months) (RR 1.4, 95% CI 1.15, 1.60, absolute increase 18%), parent or physician reported recurrent wheezing (≥3 episodes in 12 months) (RR 1.70, 95% CI 1.27, 2.29, absolute increase 19%), or physician reported severe wheeze (≥ 1 hospitalizations or ≥3 medically-attended episodes or on medication for wheeze for 3 consecutive months or 5 cumulative months) (RR 1.59, 95% CI 1.13, 2.24, absolute increase 14%) from 2 to 6 years of age. There was little to no difference in wheezing during the sixth year, with RR 1.16 (95% CI 0.70, 1.93), RR 1.28 (95% CI 0.71, 2.32) and RR 0.91(95% CI 0.44, 1.88) for simple, recurrent and severe wheezing respectively. There was a small increase in bronchodilator use (RR 1.48, 95% CI 1.23, 1.77, absolute increase 8%), inhaled corticosteroid use (RR 1.65, 95% CI 1.13, 2.40, absolute increase 10%) and oral corticosteroid use (RR 1.71, 95% CI 1.06., 2.74, absolute increase of 8%, and a larger increase in leukotriene antagonist use (RR 2.52, 95% CI 1.43, 4.42, absolute increase 10% from 2 to 6 years of age (COE low for all outcomes)^{Footnote 32}.

A study compared infants born at < 33 wGA versus at term for wheezing in the year following RSVH. There was no significant difference in simple, recurrent or severe wheeze between the two groups (RR 0.54, 95% CI 0.18-1.55; RR 0.80, 95% CI 0.04, 16.14; RR 0.00, 95% CI -0.34, 0.34 respectively but numbers with RSV were small) (very low COE)^{Footnote 29}.

A study of wheezing in the first year of life in healthy term infants with RSV infection who did or did not require hospitalization found little or no difference in parent-reported days with wheeze per month between the two groups (mean difference 0.70; 95% CI -0.94, 2.34) (very low COE)^{Footnote 36}.

Relative risk for physician diagnosed asthma at age 7 years among healthy term infants born to mothers with asthma who had RSV versus another respiratory infection in the first year of life was RR 2.33 (95% CI 1.35, 4.05, absolute increase 15%, OR 2.82, 95% CI 1.38, 5.77, p=0.005). After adjustment for the total number of respiratory infections the OR was 1.26, (95% CI 0.54, 2.91, p=0.59 (COE very low)^{Footnote 97}.

There was no difference in physician diagnosed asthma at age 28-31 years in individuals who were born at term and did or did not have RSVH at age < 24 months (RR 1.82, 95% CI 0.84, 3.94) (COE very low). There was an increase in self-reported bronchodilator use (RR 2.17, 95% CI 1.08, 4.34) and no difference in self-reported inhaled corticosteroid use (RR 1.56 95% CI 0.62, 3.89) (COE very low)^{Footnote 99}.

Some studies also addressed pulmonary function. There was little to no difference in the proportion of children born at 32-35 wGA with Force Expiratory Volume in one minute (FEV1) Z score ranking of -2 or -1 in the sixth year of life among those who did or did not have RSVH at age < 12 months (RR 0.83, 95% CI 0.45, 1.53) (COE low).^{Footnote 32}

Infants with or without RSVH at age < 24 months were evaluated at age 17-20 or 28-31 years. Pre-bronchodilator, there was a small decrease in mean percent of predicted FEV1 (mean difference -7.63, 95% CI -11.35, -3.91) and in the mean percent of predicted Forced Vital Capacity (FVC) (mean difference -4.74, 95% CI -7.80, -1.67) (COE low). There was little or no difference in the mean percent of predicted FEV1/FVC (mean difference -3.20, 95% CI -9.07, 2.67) or the mean percent of predicted Maximum Expiratory Flow after 50% of expired FVC (MEF50) (mean difference -4.00 95% CI -14.95, 6.95) (COE very low)^{Footnote 99} ^{Footnote 100}. There was little to no difference in the change in mean percent predicted FEV1 (mean difference 0.81, 95% CI -0.67, 2.30) (COE low) after administration of bronchodilator. There was very uncertain evidence on the change in mean percent predicted FVC (mean difference 0.60, 95% CI -0.67, 1.87) (COE very low), FEV1/FVC (mean difference -0.20 95% CI -2.71, 2.31) and the change in mean percent of predicted MEF50 (mean difference 3.70, 95% CI -5.42, 12.82) after administration of bronchodilator (COE very low).There was little or no difference for fractional exhaled nitrous oxide between those with or without RSVH at age < 24 month (mean difference -1.00 95% CI -14.49, 12.49) (COE low)^{Footnote 99} ^{Footnote 100}.

Single arm data showed rates of recurrent wheezing after RSVH in infancy of 12.4% (95% CI 6.3, 18.5; ROB moderate) for parent-reported or physician-diagnosed recurrent wheezing and 8.0% (95% CI 3.0, 13.0) for physician diagnosed severe wheezing at age 6 yr^{Footnote 32}. In other studies rates of physician-diagnosed asthma after RSVH in the first year of life were 26.9% (95% CI 14.9, 39.0; ROB low) at age 7 yr^{Footnote 97}, and 23.3% (95% CI 10.6, 35.9; ROB moderate) at age 28-31 yr^{Footnote 99}.

The 2020 literature review update identified two studies that looked at long term recurrent wheezing or asthma. In a prospective birth cohort study, premature infants of 32-25 wGA were followed up at 6 years of age for parent-reported wheeze within the previous 12 months. Wheeze was reported for 27.7% of children with RSVH in infancy versus 17.6% for those without RSVH (OR 1.80, 95% CI 1.11, 2.85). After adjustment for confounding factors, OR was 1.89 (95% CI 1.06, 3.32). When stratified by atopic predisposition (defined as atopic disease in at least one parent), the difference was significant only for the group without atopic predisposition (ROB high)^{Footnote 101}.

A retrospective matched cohort study of term infants without hsCHD, congenital lung disease or respiratory tract anomalies who did or did not have RSV infection in the first year of life assessed asthma or reactive airway disorder, identified from administrative claims databases, in the first 5 years of life. Cumulative incidence of asthma or reactive airway disorder for children with or without a history of RSV infection was 25.2% vs 11.4%, aOR (95% CI) 2.6 (2.5, 2.9), p<0.0001; 35.4% vs 16.7%, aOR 2.8 (2.6, 2.9), p<0.0001; and 24.4% vs 12.7%, aOR 2.2 (2.0, 2.4), p<0.0001 in three administrative databases (ROB high)^{Footnote 102}.

III.3 RSV Reinfection

Reinfections with RSV occur throughout life. Naturally acquired immunity does not protect against subsequent infection, although it may modify disease severity with the initial infection usually being the most severe infection during childhood ^{Footnote 103} ^{Footnote 104} ^{Footnote 105}. In addition, two antigenically distinct RSV subgroups, A and B, may circulate during the same season ^{Footnote 105} ^{Footnote 106}. In a study of 30 infants under 2 years of age with bronchopulmonary dysplasia (BPD), one child had two RSVH in the same season (3.3%)^{Footnote 107}. Two prospective studies from Spain of children born at ≤ 32 weeks gestation reported recurrent RSVH in the same season in 6/584 (1.0%) and 9/999 (0.9%) of patients^{Footnote 108} ^{Footnote 109}. For these reasons, previous statements from NACI^{Footnote 4} and AAP^{Footnote 5} recommended continuation of PVZ if an infant had a breakthrough RSV infection while receiving prophylaxis.

However, more recent data suggest that repeat RSV infections in the same season are rare. A study of 240 premature infants of <28 wGA or birth weight <1000 g in Denmark identified only 1 child with two RSVH in the same season (0.4%)^{Footnote 110}. In a placebo-controlled trial of PVZ in children with CHD, only 0.39% of children (3 of 648 in the placebo group and 2 of 639 who received PVZ) had more than 1 RSVH in the same season^{Footnote 80}. In another study of 429 premature infants followed for 1 year, there were no RSV reinfections^{Footnote 111}. A study in an outpatient setting identified 726 RSV lower respiratory tract infections among children younger than 5 years over 8 successive RSV seasons. There were 56 reinfections but only one occurred during the same season^{Footnote 112}. In another outpatient study of children less than 5 years of age, of 1802 children with RSV respiratory tract infections over 2 seasons only 1 had two infections in the same season, one of RSV-A and one of RSV-B^{Footnote 113}. Because of the rarity of repeat infections in the same season, the AAP (2014)^{Footnote 6} and CPS (2015)^{Footnote 8} now recommend that if a child experiences a breakthrough RSVH while receiving PVZ, monthly prophylaxis should be discontinued.

III.4 RSV infection risk and siblings of multiple births

In a case-control study of preterm infants with BPD, fourteen sets of twins and two sets of triplets were matched with 34 singleton infants for date of birth and gestational age. The risk of developing RSV illness was significantly higher in multiple-birth infants than in singletons (53% vs 24%; p=0.01), as were the rate of RSVH (32% vs 18%; p=0.05) and the rate of RSV pneumonia (24% vs. 6%, p=0.05). After controlling for confounders in a matched logistic multiple regression analysis, multiple birth was still significantly associated only with the development of pneumonia (p=0.048)^{Footnote 114}. In another study, Resch and colleagues retrospectively evaluated rates of hospitalization due to respiratory illness in 435 premature infants of 29–36 weeks gestation without chronic lung disease. They found that multiple birth was associated with RSVH (55% vs. 15%, p=0.013). Multivariate analysis to consider confounding factors was not done^{Footnote 115}.

In contrast, two larger prospective studies of risk factors linked to RSVH, involving a total of 2326 premature infants, found similar proportions of infants of multiple births in the groups with RSVH and in the control groups^{Footnote 71} ^{Footnote 116}.

In a retrospective study of infants hospitalized with RSV bronchiolitis, twins represented 7.6 % (66/875) of hospitalizations. Of the 53 pairs of twins with at least one twin with RSVH, if one twin was hospitalized the other had a 34% chance of also being hospitalized with bronchiolitis (24% chance of being hospitalized with RSV positive bronchiolitis) during the same period. However, infants in the twin group were younger and had lower gestational age than singletons. In multivariate analysis, being born a twin was not a significant risk factor for RSV disease severity^{Footnote 117}.

III.5 Healthcare associated RSV infections

RSV is frequently transmitted in hospitals, including in neonatal intensive care units^{Footnote 118}. The available data indicates that RSV infection rates during the birth hospitalization do not differ among infants who receive PVZ prophylaxis while in the neonatal unit compared with those who receive PVZ starting at hospital discharge ^{Footnote 119} ^{Footnote 120} ^{Footnote 121}. These studies were rated as fair (Harris criteria)^{Footnote 122}. The 2003 NACI statement on PVZ did not address the issue of administration of PVZ to in-patients^{Footnote 4}. The 2014 AAP Statement states that infants in a neonatal unit who qualify for prophylaxis may receive a dose 48-72 hours before discharge home or promptly after discharge^{Footnote 6}. The CPS states that for eligible infants being discharged home for the first time during RSV season, PVZ should be started just before discharge^{Footnote 8}. The United Kingdom's Green Book states that infants in neonatal units who are in the appropriate risk groups should begin PVZ 24 to 48 hours before being discharged.^{Footnote 123} To avoid wastage when vials are being opened daily for single infants about to be discharged, coordinating administrations to three times weekly has been suggested^{Footnote 121}.

PVZ has frequently been used to control RSV outbreaks in neonatal units. In some instances PVZ was administered to all exposed infants ^{Footnote 118} ^{Footnote 124} ^{Footnote 125} ^{Footnote 126} ^{Footnote 127}, in others only to those would have qualified for PVZ as outpatients ^{Footnote 118} ^{Footnote 127} ^{Footnote 128}. PVZ was started after other infection control measures had failed in some outbreaks^{Footnote 118} ^{Footnote 124}, and at the time of recognition of the outbreak in others ^{Footnote 118} ^{Footnote 125} ^{Footnote 126} ^{Footnote 127} ^{Footnote 128}. The incremental role played by PVZ in control of these outbreaks could not be determined^{Footnote 118}. PVZ may be useful when other measures have failed to control an outbreak or when it is anticipated that adherence to infection control recommendations will be poor^{Footnote 118} ^{Footnote 126}.

Although not addressed in the AAP 2014 or the CPS statements, the 2009 AAP PVZ statement indicates that infants who have begun PVZ prophylaxis earlier in the season and are hospitalized on the date when a dose is due should receive that dose as scheduled^{Footnote 5}. Likewise the UK Green Book states that those infants that have begun a course of PVZ but are subsequently hospitalized should continue to receive it whilst they remain in hospital^{Footnote 123}.

Product

IV.1 Preparation authorized for use in Canada

The only product currently authorized for use in Canada for prevention of serious RSV disease is PVZ (Synagis^®, AbbVie AstraZeneca, Mississauga, Ontario). PVZ is a humanized monoclonal antibody (IgG1κ) produced by recombinant DNA technology, directed to an epitope in the A antigenic site of the F protein of RSV, a surface protein that is highly conserved among RSV isolates. It is a composite of 95% human and 5% murine amino acid sequences^{Footnote 129}. It was authorized for use in Canada in 2002.

PVZ solution for injection is available in 50 mg/0.5 ml and 100 mg/1 ml single use vials. Non-medicinal ingredients included are chloride, glycine, histidine and water for injection^{Footnote 129}.

IV.2 Efficacy and effectiveness

Studies of the efficacy and effectiveness of PVZ in preventing severe consequences of RSV infection in children at high risk of severe RSV disease are reported in the document "NACI Literature Review on the Effects of PVZ Prophylaxis on Reducing the Complications Associated with Respiratory Syncytial Virus in Infants" which will be forthcoming. Results are summarized below. In mixed populations of infants at risk of severe RSV infection, PVZ prophylaxis is associated with reductions of 38 - 86% in the risk of RSV-associated hospital admissions, with number needed to treat (NNT) to prevent one hospitalization of 2 to 24. Differences in the health conditions of the mixed populations preclude definitive conclusions about relative benefits for different patient groups. Studies of mixed populations will not be discussed further here, but are included in the Literature Review which will be forthcoming.

IV.2.1 Premature infants without infantile chronic lung disease

IV.2.1.1 RSV-associated hospitalizations

Twelve studies examined the effect of PVZ prophylaxis on RSVH in premature infants without CLD: a systematic review and meta-analysis of average quality^{Footnote 74}, four RCT reports of good^{Footnote 41} ^{Footnote 48} or average quality^{Footnote 111} ^{Footnote 130}, six observational cohort studies of either good^{Footnote 131}, average or fair ^{Footnote 27} ^{Footnote 44} ^{Footnote 49}, or poor^{Footnote 47} ^{Footnote 132} quality and one case-control study of fair quality^{Footnote 133}.

The systematic review and meta-analysis of studies from 1990 to 2007 found that compared to no prophylaxis, PVZ use was associated with 72% fewer RSVH in infants born at ≤32 wGA and 74% fewer in infants born at 32–35 wGA^{Footnote 74}. The IMPACT RCT, carried out in 1996, reported a 78% decrease in rate of hospitalization for RSV in premature infants aged ≤ 6 months without CLD who received PVZ, with a NNT of 16^{Footnote 48}. The decrease was 47% for infants ≤ 32 wGA and 72% for those 32-35 wGA^{Footnote 48}. Notario et al. further analyzed the data from the IMpact study by gestational age groups. PVZ resulted in significant reductions in hospitalization rates for infants of 28-31 wGA (73%), 29-32 wGA (80%), 32-34 wGA (82%), and 32-35 wGA (82%), but not for those <29 wGA or 33-35 wGA. The numbers in these two latter groups were small^{Footnote 41}. NNT ranged from 13 to 21 and decreased with increased gestational age. A similar significant protective effect of PVZ prophylaxis was found in a later RCT of infants 33–35 wGA enrolled in 2008-10 (82%. NNT 24)^{Footnote 111}and a small RCT of infants born at ≤32 wGA enrolled in 2009-11 (OR 0.26, NNT 5)^{Footnote 130}.

In the prospective case-control study rated as fair quality, conducted from 2002 to 2006, PVZ effectiveness for prevention of RSVH was 74% of 29-35 wGA infants. Effectiveness was not observed in those < 29 wGA but the numbers were small^{Footnote 133}.

Observational cohort studies had conflicting results about the impact of PVZ prophylaxis on RSVH in premature infants. A retrospective cohort study of fair quality of children born in 2012-2015 found a 38% lower RSVH rate in the first RSV season in infants 29–32 wGA who received PVZ compared to infants receiving no prophylaxis (NNT 53), but no statistically significant difference in RSVH in infants 33–36 wGA who did and did not receive PVZ prophylaxis. However, numbers of children prescribed PVZ and adherence to PVZ prophylaxis in the latter group were low^{Footnote 27}.

In an observational study rated fair quality, PVZ prophylaxis did not significantly reduce RSVH rate for infants of ≤ 28 wGA without CLD enrolled between 2011-2013 compared with a historic control group born in 2000-2008^{Footnote 44}. However, the sample sizes were small.

PVZ was not significantly effective in cohorts of children born at 32–35 wGA in 2002-3 in a study rated as good quality^{Footnote 131}. Another cohort study of infants born at 32-34 wGA from 1995-2004, rated as fair quality, found a significant reduction in RSVH in Texas (OR=0.45, 95% CI 0.26, 0.78, p=0.005) but not in Florida (OR=0.81, 95% CI 0.42, 1.58, p=.54)^{Footnote 49}.

In a study rated as poor quality, PVZ prophylaxis was found to significantly reduce RSVH in a cohort of children born at ≤30 wGA in 1999-2004 (1.1 % vs 13.6%, NNT 9)^{Footnote 47}.

In summary, there is good evidence, based on early RTC, of the efficacy of PVZ in premature infants of 28-35 wGA. The conflicting results of observational studies on infants of 32-36 wGA are difficult to explain, but may in part be due to differences in study design, adherence, location and era. Three studies, one of good and two of fair quality, suggested lack of effect in infants of < 29 wGA but this may be the result of small numbers of infants without CLD in this very premature group ^{Footnote 41} ^{Footnote 44} ^{Footnote 133}. One observational study of poor quality supported a protective effect in infants of ≤ 30 wGA. In general, it appears there is evidence in support of the effectiveness of PVZ in reducing RSVH in children born prematurely, although the level of prematurity at which PVZ is most effective is not clear from the data.

IV.2.1.2. Mortality

The only study that examined all-cause mortality was a systematic review and meta-analysis of average quality by Checchia et al.. In infants born at ≤32 wGA. PVZ recipients had a significantly reduced risk of all-cause mortality (OR=0.25, 95% CI 0.13, 0.49, p<0.001) compared to recipients of placebo or no intervention, while in infants born at 32–35 weeks' GA, the difference was not significant (OR=0.22, 95% CI 0.03, 1.89, p=0.085)^{Footnote 74}.

It is possible that there may be a differential impact of PVZ prophylaxis on all-cause mortality in this population, showing a protective effect in infants born at ≤32 weeks' GA, but not at lesser levels of prematurity (32–35 weeks' GA). However, these findings are based upon few studies which may have been underpowered to detect difference in mortality in the less premature infants.

IV.2.1.3 Long term sequelae

IV.2.1.3.1 Recurrent wheezing and atopic asthma

Six reports examined the effect of PVZ prophylaxis on the risk of wheezing in the first few years of life: Two reports of average or fair quality from a RCT^{Footnote 111} ^{Footnote 134} and four reports from two cohort studies of good^{Footnote 135}, average or fair^{Footnote 136} ^{Footnote 137} and poor^{Footnote 138} quality. One study^{Footnote 111} investigated parent-reported wheezing only, while the other five investigated physician-diagnosed or both parent-reported and physician-diagnosed wheezing. Three studies found that PVZ prophylaxis in otherwise healthy premature infants born at 33–35 wGA^{Footnote 111} ^{Footnote 138} or ≤35 wGA^{Footnote 136}, resulted in a significant reduction (46-66%) in the risk of wheezing in children in the first year of life^{Footnote 111}, up to age 3^{Footnote 138}, or up to 2 years after enrollment at age ≤36 months^{Footnote 136}.

In another report from the cohort study of Simoes et al., children who had received PVZ prophylaxis had a significantly decreased incidence of physician-diagnosed wheezing 24-months after study enrollment and a significantly longer time to a third physician-diagnosed wheezing episode compared to children receiving no intervention, but only in children without a family history of asthma or atopy. There was no significant difference in these outcomes in children with a family history of asthma or atopy^{Footnote 135}.

A follow-up of the cohort of children born at 33–35 wGA initially assessed for wheezing at age 3 years^{Footnote 138} found that children who had received PVZ prophylaxis had reduced rates of physician-diagnosed recurrent wheezing during the first 6 years of life compared to children who had not received prophylaxis. However, this association was found only in the subgroups of children with a family history of allergy. The authors distinguished atopic asthma (recurrent wheezing and elevated IgE) from recurrent wheezing and found rates of atopic asthma were similar in children who received PVZ and those who did not, regardless of family history of allergy^{Footnote 137}. On follow-up at age 6 years of the infants enrolled in the Blanken et al. RCT, the difference between PVZ and placebo recipients was significant only for those with parent reported infrequent wheeze (1-3 episodes per year). There was no significant difference in physician diagnosed asthma or the use of asthma medication in the previous 12 months and pulmonary function at 6 years of age did not differ between the groups^{Footnote 134}.

It appears PVZ may have a consistent impact in reducing the incidence of recurrent wheezing in young children in the first few years of life, but the findings are contradictory as to the relative impact of PVZ versus a family history of atopy on subsequent recurrent wheezing in older children. It also is not clear from these studies at what level of prematurity PVZ may be most effective in having a long term impact. The NNT to prevent one case of recurrent wheezing was 7-8 in infants of 32-35 or 33-35 wGA ^{Footnote 111} ^{Footnote 136} ^{Footnote 137} ^{Footnote 138}, 10 for 29-32 wGA^{Footnote 136} and 15 for < 29 wGA^{Footnote 136}.

IV.2.1.3.2 Growth parameters

One cohort study of fair quality assessed parameters of growth at 6 years of age in children born at 33–35 wGA^{Footnote 137}. The study found no significant differences in weight, height or body mass index between children who received PVZ and children did not.

IV.2.2 Premature infants with infantile chronic lung disease

IV.2.2.1 RSV-associated hospitalizations

Five studies examined this outcome. A good quality RCT of children born at ≤35 wGA and ≤24 months of age with BPD, carried out in 1996, found that PVZ recipients had a reduced risk of RSV-associated hospitalization compared to infants who received placebo (RR=0.61, 95% CI 0.40, 0.95; NNT 21)^{Footnote 48}. In an observational study rated as fair, PVZ prophylaxis reduced RSVH rate by 86% (NNT 13) in the first 6 months after initial hospital discharge for infants with CLD enrolled between 2011 and 2013 compared with a historic control group born in 2000-2008. By gestational age, reduction was significant for those of ≤28 wGA (89%, NNT 12) and not those 29-35 wGA, but numbers in the latter group were small^{Footnote 44}. An earlier prospective observational cohort study of poor quality of infants born at ≤32 wGA, carried out in 1999-2002, found PVZ prophylaxis to be associated with a reduced risk of RSVH (RR=0.15, 95% CI 0.05, 0.49, p<0.01; NNT 3) in the 1st RSV^{Footnote 139}. Another prospective observational study of poor quality that included children up to 24 months of age with CLD also reported reduced risk of RSVH (RR=0.28, 95% CI 0.14, 0.58, p<0.007; NNT 8)^{Footnote 46}. In a prospective case-control study, rated as fair quality, of infants ≤35 wGA and <12 months or 12-24 months of age, conducted from 2002 to 2006, there was no significant reduction in hospitalization rate^{Footnote 133}.

The results suggest that PVZ prophylaxis provides a reduction in the risk of RSV-associated hospital admissions in this population, but the influence of gestational age on this benefit is not clear.

IV.2.2.2 Mortality

A meta-analysis of average quality showed no observed effect of PVZ vs no intervention/placebo on all-cause mortality for preterm CLD (0.22% vs. 0.34%; Peto OR, 0.83; 95% CI 0.13, 5.25), but there were only 3 events in the prophylaxis group and 2 events in the placebo/no intervention group^{Footnote 74}.

IV.2.3 Children with cystic fibrosis

IV.2.3.1. RSV-associated Hospitalizations

Six studies examined this outcome. A systematic review rated of good quality identified one RCT carried out in 1998-2001. The study found no significant difference in RSVH in children with cystic fibrosis who received either PVZ prophylaxis or placebo (RR 1.02 (95% CI 0.06, 16.09). However only one child in each group was hospitalized due to RSV^{Footnote 140} ^{Footnote 141}. One small observational study of fair quality found that historical controls from 1997-2002 who did not receive PVZ were more likely to have RSVH compared to children who received PVZ from 2003-2007 (21.3% vs 4.4%, p=0.027; NNT 6)^{Footnote 78}. Three other observational studies found no significant difference in RSVH between PVZ recipients and controls. In the study by Bjornson et al, carried out from 2000-2017 and rated as fair, hospitalization rate was 2.7% for PVZ recipients and 6.0 % for controls (p=0.20). After adjustment for confounding factors, the hospitalization rate for RSV was still not significantly less in children who received PVZ than in those who did not. However there was a significantly reduced rate of hospitalization for respiratory illness in the PVZ recipients, and overall testing rate for RSV was low at 53%^{Footnote 77}. A large study from 1999-2006, of poor quality^{Footnote 142}, and a small study of PVZ recipients from 2001-05 with historical controls from 1997-2000, also of poor quality^{Footnote 143} did not find a significant benefit of PVZ prophylaxis compared to no intervention on subsequent RSVH. A case control study of fair quality, carried out in 2001-12, found no significant reduction in RSVH between the PVZ (5%) and control (2.9%) groups^{Footnote 144}.

No conclusions on the effectiveness of PVZ prophylaxis in reducing the risk of RSVH in children with cystic fibrosis can be drawn from the findings of these studies. Only the observational study of Groves et al. found a significant preventive effect of PVZ prophylaxis on RSVH^{Footnote 78}. The rate of RSVH in the control group in that study was very high and the number of participants was small. Most studies had small numbers and may have been underpowered to detect an effect. The exception was the large study of Winterstein et al, which used a health care provider administrative database^{Footnote 142}. It may be that some children with cystic fibrosis, e.g, those with significant chronic lung disease in the first 1 or 2 years of life, may benefit.

IV.2.3.2 Additional Hospital Outcomes due to RSV

IV.2.3.2.1 Length of hospital stay due to RSV

One observational cohort study of fair quality examined the effect of PVZ on the duration of hospitalization due to RSV in children with cystic fibrosis. The mean duration of hospitalization was significantly less in the PVZ recipients (5.7 ± 2.4 days) than in the controls (47 ± 39 days), p=0.048^{Footnote 77}. An earlier small historical cohort study of poor quality found no significant difference in the median number of days of RSVH in PVZ recipients (11, interquartile range: 3–14) compared to children receiving placebo (13, IQR: 2–14) (OR=0.46, 95% CI 0.16, 1.31)^{Footnote 143}.

At present, with the results of a single small study of poor assessed quality that may not have been sufficiently powered to detect a difference, no firm conclusions can be drawn on the effect of PVZ prophylaxis on the duration of RSVH in children with cystic fibrosis.

IV.2.3.2.2. Admission to intensive care unit due to RSV

One study assessed this outcome. None of 183 PVZ recipients and 2 of 84 controls were admitted to ICU because of RSV. Of patients hospitalized for RSV, 2 of 5 patients in the control group required ICU admission^{Footnote 77}.

IV.2.3.2.3 Use of respiratory support due to RSV

Robinson et al examined the effect of PVZ prophylaxis on the use of oxygen therapy due to RSV in children with cystic fibrosis. No significant difference between the groups was found in the need for oxygen therapy; however, the number of outcomes was small (PVZ prophylaxis group, n=1; placebo intervention group, n=0)^{Footnote 140}. In the study of Bjornson, increased respiratory support, either MV or oxygen therapy, was required by 2.2 % of PVZ recipients and 1.2% of the control group (p=0.58)^{Footnote 77}. In the study of Buchs, no patients required supplemental oxygen or MV^{Footnote 144}.

IV.2.3.3 All-cause Mortality

The RCT study examined the effectiveness of PVZ prophylaxis in reducing all-cause mortality in children with cystic fibrosis. However, as there were no deaths identified in either group during the 6 months of follow-up during the study, no conclusion can be drawn about the effect of PVZ prophylaxis on this outcome^{Footnote 140}. A larger cohort study by Fink et al. also reported no difference in all-cause mortality before age 2 years between those who did or did not receive PVZ^{Footnote 145}.

IV.2.3.4. Long-term Sequelae

IV.2.3.4.1 Lung function

A small historical cohort study of fair quality found no significant difference in lung function (as assessed by measurement of FEV1) between children with cystic fibrosis who had and had not received PVZ was found on follow-up assessments at 6 years of age^{Footnote 78}. The cohort study by Fink et al., rated as of poor quality, also found no difference in FEV1 at age 7 years between those who did or did not receive PVZ^{Footnote 145}.

IV.2.3.4.2 Growth parameters

The RCT found no significant differences between the PVZ and placebo groups at 12 month follow-up with respect to weight gain or weight to height ratio^{Footnote 140}. A small historical cohort study found no significant differences in growth parameters (weight, height, body mass index) at 6 years of age between children who did and did not receive PVZ prophylaxis^{Footnote 78}. The case control study of Buchs et al, also found no significant difference between PVZ recipients and controls in growth in the first 3 years of life^{Footnote 144}.

IV.2.3.4.3 P. aeruginosa and S aureus colonization

The RCT found no statistically significant differences in the numbers of children with P. aeruginosa airway colonization in children receiving PVZ compared to those receiving placebo at 12 months follow-up.^{Footnote 140} In the study by Groves et al, the median time to a first isolate of P. aeruginosa was significantly shorter in PVZ recipients than in non-recipients and the relative risk of a first isolate during the study period was also significantly increased in PVZ recipients. However, at follow-up at 6 years of age there was no significant difference in chronic P. aeruginosa colonization rates between the two groups^{Footnote 78}. Buchs et al, reported that PVZ prophylaxis had no significant effect on age at first colonization with P. aeruginosa or S. aureus or in the proportion of children colonized with P. aeruginosa by age 3 years. The proportion of infants colonized with S. aureus by age 3 years was significantly increased in the PVZ recipients (97%) in comparison to controls (85%)^{Footnote 144}. Fink et al. also reported no difference in time to first P. aeruginosa colonization between those with or without PVZ prophylaxis^{Footnote 145}.

The results from the these studies appear consistent with no significant differences in the longer term sequelae examined between children with cystic fibrosis who have and have not received PVZ prophylaxis. However, the number of children studied was small.

IV.2.4 Children with hemodynamically significant congenital heart disease

IV.2.4.1. RSV hospitalizations (RSVH)

Five studies examined the efficacy or effectiveness of PVZ prophylaxis in children with hsCHD. A good quality RCT carried out in 1998-2002^{Footnote 80} found that children with hsCHD and ≤24 months of age at the start of the RSV season who received PVZ prophylaxis had a significant relative decrease in RSVH compared to children receiving placebo (RD=45%, p=0.003; NNT 23). This was statistically significant in children with acyanotic CHD (RD=58%, p=0.003; NNT 15), but not in children with cyanotic CHD (RD=29%, p=0.285). An observational cohort study of fair quality of infants < 1 year of age, with PVZ recipients in 2013-2015 followed prospectively and controls from 2010-15 identified retrospectively found a significant reduction of 49% (NNT 45) for all cases and 65% (NNT 31) for the subgroup with cyanotic hsCHD but a non-significant reduction of 35% for those with acyanotic disease^{Footnote 146}. A significant relative risk of 0.28 (72% reduction, NNT 7) in hospitalization for all cases of hsCHD < 1 year of age was reported in a small observational study of fair quality with PVZ recipients enrolled between 2014-16 and historical controls born in 2007-09^{Footnote 147}. An earlier poor quality observational cohort study with PVZ recipients from 2003-07 and historical controls born 1998-03 did not find PVZ prophylaxis to result in a significant reduction in RSVH compared to no intervention in children with CHD who were born at ≤36 w GA and ≤24 months of age at the start of the RSV season (RR=0.58, 95% CI 0.21, 1.65), but the RSVH rate in the control population was very low (2.9%)^{Footnote 148}. In a prospective case-control study of fair quality, carried out from 2002-6, significant PVZ effectiveness was not observed, either in the first or the second year of life^{Footnote 133}.

These studies show conflicting results on the protective effect of PVZ on RSVH in infants with hsCHD. The two studies that did not show a significant effect^{Footnote 133} ^{Footnote 148} had smaller numbers of participants than two larger studies that showed 45-49% risk reduction^{Footnote 80} ^{Footnote 146}. One of these studies showed significant protection in children with cyanotic heart disease but not in those with acyanotic heart disease^{Footnote 146}, but the other showed the opposite^{Footnote 80}. The reasons for these discrepancies are not evident but may be due to inadequate sample size to detect a difference in the subgroups.

IV.2.4.2. Additional Hospital Outcomes Due To RSV

IV.2.4.2.1. Length of hospital stay due to RSV

The RCT involving children with hsCHD and ≤24 months of age found PVZ recipients to have a significant relative decrease in the total number of RSVH days/100 children compared to placebo recipients (RD=56%, p=0.003)^{Footnote 80}. For those admitted to hospital because of RSV, mean LOS was 10.8 days for PVZ recipients and 13.3 days for placebo, not significantly different. In the study of Chiu et al, the LOS was not significantly different in patients who did or did not receive PVZ, either for the total group or for those with cyanotic or acyanotic hsCHD^{Footnote 146}.

IV.2.4.2.2 Admission to and length of stay in intensive care unit due to RSV

The RCT of children with hsCHD aged ≤24 months reported that compared to placebo recipients, PVZ recipients had a relative decrease in the number of admissions to ICU but the reduction was not significant (RD=46%, p=0.094)^{Footnote 80}. In the observational cohort studies, Chiu et al, reported no significance differences in rates of admission to ICU in those who received PVZ and those who did not, either for the total group or for those with cyanotic or acyanotic hsCHD, and Harris et al also found no significant difference in rate of admission to ICU. In the three studies, the proportions of infants hospitalized for RSV who required ICU admission were also not significantly different in the groups that received PVZ and those that did not^{Footnote 80} ^{Footnote 146} ^{Footnote 148}.

In the RCT the total number of days/100 children in an ICU due to RSV did not differ significantly between PVZ and placebo recipients^{Footnote 80}. In the cohort study of Harris, mean ICU LOS decreased from 14.9 to 10 days but the difference was not significant^{Footnote 148}.

IV.2.4.2.3 Use of mechanical ventilation (MV) due to RSV

The RCT by Feltes et al. found no significant difference in the use of MV, reported as total days/100 children, between children with hsCHD and ≤24 months of age at the start of the RSV season who received PVZ compared to placebo recipients (RD=41%, p=0.282)^{Footnote 80}.

IV.2.4.2.4. Duration of oxygen therapy due to RSV

The RCT found that compared to placebo, children who received PVZ prophylaxis had significantly less total days/100 children on oxygen therapy (RD=73%, p=0.014)^{Footnote 80}.

These results suggest that for children with hsCHD who are hospitalized with RSV infection, having received PVZ does not affect the severity of illness, as manifested by hospital LOS, ICU admission, ICU LOS, or need for MV, although the number of studies is small.

IV.2.4.3 All-cause mortality

Both the RCT by Feltes et al. and the cohort study by Harris et al. examined all-cause mortality in this population^{Footnote 80} ^{Footnote 148}. In the RCT, there was no significant difference in all-cause mortality between children with hsCHD and ≤24 months of age at the start of the RSV season who received PVZ compared to placebo recipients. The Harris et al. study reported one death in the no intervention group and no deaths in PVZ prophylaxis group.

The RCT reported deaths from RSV in 2 of 639 PVZ recipients and 4 of 648 controls (p=0.46)^{Footnote 80}.

IV.2.5 Children with Down syndrome

IV.2.5.1 RSV-associated Hospitalizations

Three studies examined the effect of PVZ prophylaxis in reducing RSVH in infants with Down syndrome. A small observational cohort study of fair quality of children carried out in 2012-14 found that hospitalization rate for children with Down syndrome without other criteria for PVZ prophylaxis was not significantly different in those who received PVZ and those who did not (3% vs 15%, p=0.075)^{Footnote 149}. An earlier, larger cohort study, of poor quality, compared children in Canada with Down syndrome who received PVZ from 2005-2012 with children from a Dutch Down syndrome registry born from 2003-05 who did not receive PVZ^{Footnote 150}. After adjusting for hsCHD, insignificant CHD, gestational age, and birth weight, the analysis found that compared to no intervention receipt of PVZ was associated with a statistically significantly 72% reduction in RSVH (IRR=3.63 95% CI 1.52, 8.67, p=0.002; NNT 12). Significant reduction in hospitalization was also found when the analysis was restricted to children with at least one standard risk criteria for RSV prophylaxis (hsCHD, born at ≤35 wGA, CLD) (IRR 3.39 (1.02–11.25)). However, when the analysis was restricted to children with no standard RSV risk criteria, the difference in RSVH between children receiving PVZ prophylaxis and children receiving no intervention was not significant (IRR=6.57 95% CI 0.70, 62.16). The third study, rated as good, reported a decrease in overall RSVH after PVZ prophylaxis was approved in Japan for all children with Down syndrome. For all children, the adjusted odds ratio (aOR) for those receiving PVZ was 0.41 (95% CI 0.18, 0.92, p=0.03) but there were no differences in RSVH in the groups without hsCHD (aOR 0.43, 95% CI 0.04, 4.26, p=0.47) or without additional risk factors for RSVH (aOR 0.68, 95% CI 0.06–7.73, p=0.75)^{Footnote 151}.

IV.2.5.2 Additional Hospital Outcomes Due To RSV

IV.2.5.2.1 Duration of hospital stay due to RSV

The observational study of Yi et al. study found that there was no significant difference in average number of days of hospital stay due to RSV in PVZ recipients compared to children receiving no intervention (6.4 versus 12.4 days, p=0.48)^{Footnote 150}.

IV.2.5.2.2. Admission to and duration of stay in intensive care unit due to RSV

The observational study of Yi et al reported that none of the 532 children who received PVZ prophylaxis were admitted to an ICU, while in the 233 without PVZ there were 4 admissions to an ICU (p=0.0085). The average LOS in ICU was 10.3 days^{Footnote 150}.

IV.2.5.2.3 Use and duration of mechanical ventilation (MV) due to RSV

The Yi et al. study also had no children who received PVZ prophylaxis requiring MV, while in the group without PVZ there were 4 children who required MV (p=0.0085). The average duration of MV was 10.3 day^{Footnote 150}.

IV.2.5.2.4 Use and duration of oxygen therapy due to RSV

The Yi et al. study found that children who received PVZ prophylaxis had significantly less use of supplemental oxygen therapy (2/532, 0.004% versus 19/233, 0.08%, p<0.001) and fewer average number of days of use of oxygen therapy (4 versus 13.7 days, p=0.046) compared to children who did not receive PVZ^{Footnote 150}.

The significance of the results from these studies, one of poor quality^{Footnote 150} and the other involving very few children^{Footnote 149}, is unclear, but suggests that PVZ may not benefit children with Down syndrome who do not have other conditions that may warrant PVZ administration. Further studies would be required before conclusions can be drawn on the benefit of PVZ in this population.

IV.2.6 Infants residing in remote communities

IV.2.6.1 RSV-associated hospitalizations

There were two cohort studies of poor quality that examined this outcome^{Footnote 92} ^{Footnote 152}. The Banerji et al. study included Inuit children from Nunavut, Canada who were born at either <36 wGA and/or had significant cardiac or respiratory disease and were <6 months of age at the start of the 2009-10 RSV season. Children who received PVZ had significantly fewer RSVH (2/91, 2.2%) compared to PVZ eligible children receiving no intervention (5/10, 50%) (OR=0.04, 95% CI 0.008, 0.26, p=0.0005). The number needed to treat to prevent one RSVH was 2^{Footnote 152}. As not all PVZ eligible infants were identified, the actual reduction rate is likely to be less than that reported. In the study by Singleton et al., RSVH were assessed in Alaskan Aboriginal children before and after introduction of a PVZ program for high risk infants in 1998.There was a significant reduction in RSVH in infants born at ≤36 wGA (relative rate 0.34, 95% CI 0.17, 0.68, p<0.001). After the PVZ program introduction, among high risk infants the rate of first RSVH was 0.55 per 1000 PVZ protected days and 1.07 per 1000 unprotected days (relative rate 0.52; 95% CI 0.28, 0.93). The number needed to treat to prevent one RSVH was 4^{Footnote 92}.

Although Inuit infants residing in remote northern communities are known to be at high risk of RSVH^{Footnote 23}, data on PVZ effectiveness to prevent hospitalization in this group is very limited. After completion of the PVZ effectiveness literature review, the results of a program providing PVZ prophylaxis to healthy term infants less than 3 months of age during RSV season in Nunavik, Quebec became available^{Footnote 90}. The quality of the study was rated as fair. Between November 2016 and June 2019, 73% of 646 eligible healthy term infants received some PVZ but only 37% received all recommended doses on time. PVZ effectiveness was assessed by 1) comparing RSVH in infants who received all doses of PVZ on time and those who received no PVZ and 2) comparing RSVH during PVZ-protected and unprotected days. RSVH occurred in 10/237 infants (4.2%) who received PVZ and in 7/177 (4.0%) of those who did not. PVZ direct effectiveness was calculated to be -6.7% with wide 95% CI of -174.8, 85.5. RSVH rates were 37.6/100,000 PVZ-protected days and 39.1/100,000 unprotected days, for a direct protective effect of 3.8% with 95% CI -1167.6, 64.9. Limitations of the study included small numbers of RSVH, wide variation in RSVH in different years, and a high rate of co-infections with other respiratory viruses. For details, see the Data Table in Appendix C.

IV.2.7. Impact of changes in recommendations for PVZ prophylaxis.

Several studies were identified in the literature search on burden of RSV illness that described the impact of the 2014 AAP revised recommendations for PVZ use on RSVH by analyses of sequential time periods before and after implementation of the revised recommendations^{Footnote 6}. These studies did not meet the criteria for the literature review because children who did or did not receive PVZ were not identified, but are summarized here.

In a single tertiary center study from North Dakota, the rate of RSVH per 1,000 children <24 months old was 5.37 in the pre-2014 guideline period (2012-13 and 2013-14 seasons) and 5.78 in the post-2014 guideline period (2014-2015 season) (rate difference of +0.4, 95% CI −1.2, +2, p=0.622). The number of RSV admissions was 194. The number of doses of PVZ administered per 1000 children <24 months of age was 21.7 in the pre-2014 guideline period and 10.3 doses in the post-2014 guideline period, a reduction of 11.4 doses (95% CI 14.3, 8.4, p<0.001)^{Footnote 153}.

Another single center study from Milwaukee looked at numbers of RSVH in infants less than 1 year old born at ≥29-35 wGA and the proportions of all RSV admissions that were in this gestational age group 2 seasons before and two after implementation of the 2014 AAP guidelines (2012-2017). The number of RSVH was 91.There were no significant differences in the number of admissions or the proportion of admissions in this gestational age group before and after implementation of the new guidelines. Duration of hospitalization increased from a median of 5.86 days before to a median of 7.86 days (p=0.02) after implementation but there was no difference in need for ICU, supplemental oxygen, or MV^{Footnote 154}.

A single center study from Ohio looked at RSVH in infants <12 months old before and after implementation of the 2014 guidelines. Of 1063 RSVH, infants born at 29^0/7-34^6/7 wGA accounted for 7.1% (34/482) in the 2013-4 season and 9.8% (57/581) in 2014-5 season (not significantly different). Infants of 29-34 wGA who were <6 months old constituted 3.5% (17/482) of RSVH in 2013-14 versus 7.1% (41/581) in 2014-15 (p=0.01). Among 29^0/7-34^6/7 wGA otherwise healthy infants who were <3 months old, oxygen administration (40.0% vs 78.9%; p=0.05), pediatric ICU admission (30.0% vs 68.4%; p=0.04), MV (10.0% vs 52.6%; 0.04), duration of hospitalization (1.8 vs 8.8 days; p=0.04) were all higher in 2014-15. No differences in morbidity were observed between 2013-14 and 2014-15 in premature infants aged 3 to <6 or 6 to <12 months. PVZ eligibility decreased from 32.3% in 2013-14 to 1.8% in 2014-15 (p<0.001)^{Footnote 51}.

A large study used commercial and Medicaid databases to assess infants born between July 1, 2011 and June 30, 2016. Infants were categorized as preterm or term and hospitalizations for RSV for infants aged < 6 months identified. Rate ratios comparing hospitalization rates for preterm and term infants were calculated. Seasonal rate ratios prior to the guidance change for preterm versus term infants ranged from 1.6 to 3.4. After the guidance change, seasonal rate ratios ranged from 2.6 to 5.6. In 2014 to 2016, the risk associated with prematurity of 29-34 wGA versus term birth was significantly higher than in 2012 to 2014 (2.00, p<0.0001 for commercially insured infants and 1.46, p<0.0001 for Medicaid insured infants, p<0.0001). PVZ use decreased by 74-97% in different wGA and age groups^{Footnote 155}.

An earlier study using similar databases assessed PVZ use and RSVH rates among preterm infants of 29-36 wGA during the 2014–2015 season with rates in the 2013–2014 season. PVZ prophylaxis utilization in infants 29 to 34wGA decreased by 62 to 95% (p< 0.01) in the 2014–2015 season relative to the 2013–2014 season. Compared with the 2013–2014 season, RSVH rates increased in the 2014–2015 season by 2.7-fold (p=0.02) and 1.4-fold (p=0.03) for infants 29 to 34wGA aged <3 months with commercial and Medicaid insurance, respectively. No significant differences were observed for those aged 3-6 months^{Footnote 156}.

Another study investigated the effect of the change in recommendations for children with hsCHD. The 2014 AAP guidelines recommended PVZ prophylaxis for those in the first year of life whereas previous guidelines recommended prophylaxis for those < 2 years of age. A US national administrative healthcare database was reviewed to identify children age < 24 months with CHD admitted with RSV in the 2012-2014 and 2014-2016 RSV seasons. There were 644 RSV admissions in the 2012-13 and 2013-2014 seasons and 625 in the 2014-15 and 2015-2016 seasons. There was no change in LOS, ICU admission rate, or in-hospital mortality for children 13–24 months old with CHD after the change in recommendations. There were no deaths in 13–24 month olds, regardless of era. The population studied was not limited to those with hsCHD^{Footnote 157}.

Following publication of the revised recommendations from the AAP in 2014, Italy implemented similar limitations for PVZ use for otherwise healthy premature infants in the fall of 2016. In a population of 284,902 children aged <2 years in one region of Italy, the number of RSVH was 1729. Following the change in policy a reduction in the number of RSVH from 6.3/1000 (95% CI 6.0, 6.7) to 5.5/1000 (95% CI 5.0, 5.9) was observed. There was no significant difference in wGA or age on admission of children admitted with RSV in the 2 seasons before and the season after the change in policy. The number of prescriptions for PVZ decreased by 48% after the change in policy^{Footnote 158}.

A retrospective review of RSVH of children ≤ 1 years of age over three consecutive RSV seasons (2014-15, 2015-16, 2016–2017) was carried out in single tertiary center in Italy. Total RSV admissions for the 3 seasons was 366. The proportion that were preterm increased in the 3 seasons from 6.6%, to 7.3%, to 9.2%, respectively for the 29 - < 36 wGA group, and from 5.1% to 6.4% to 8.3%, respectively, for the 33 - < 36 wGA subgroup. These increases were not statistically significant but sample size was small^{Footnote 159}.

Another retrospective cohort study of RSVH among infants born at 29-35 wGA in the season before (2015–2016) or after (2016–2017) the introduction of more restricted recommendations for PVZ was conducted in three neonatal ICUs in Italy. There were 262 infants enrolled in 2015-16 and 274 in 2016-17. RSVH occurred in 1.9 and 5.1% in infants in 2015-16 and 2016-17 respectively (odds ratio 2.77; 95% CI 0.98, 7.8, p=0.045. The proportion of infants not receiving PVZ increased significantly from 63.7% in 2015-16 to 80.6% in 2016-17 (p< 0.0001)^{Footnote 160}.

In summary, there is little population-based data on the effect of the 2014 change in AAP recommendations on RSVH of premature infants of 29 to 35/36 wGA. One small single center study reported no difference in overall RSVH rates. A large administrative database study showed a 1.4 to 2.7 fold increase in RSVH rates in premature infants aged < 3 months. Other studies looked at the proportions of children admitted with RSV who were of 29-35 wGA. Two single center studies showed no difference in this proportion. One showed no difference in morbidity of those admitted, while the other reported a shift towards younger age, and higher morbidity in those admitted who were < 3 months old but not in older infants. Another large database study compared ratios of premature to term infants among those admitted with RSV and reported an increase of 1.5 to 2 fold. One study of children with CHD aged 13-24 months showed no increase in morbidity in those hospitalized with RSV. A similar policy change was made in Italy. Two studies there showed no significant impact while a third reported a 2.7 fold increase in RSVH rates in infants of 29 to <36 wGA. However there are important variations in RSVH rates from 1 season to another, and these studies covered only 1 or 2 seasons before and after policy change.

IV.3 Immunogenicity

IV.3.1 PVZ levels

PVZ is a passive immunizing agent. A PVZ serum concentration of ≥ 30 ug/mL was shown to reduce replication of RSV in the lungs of the cotton rat by 99%^{Footnote 161}. Based on this data, ≥40 ug/mL was chosen arbitrarily as the preferred target trough level in clinical trials in infants^{Footnote 48} ^{Footnote 80} ^{Footnote 162}. In these studies, 5 doses of 15 mg/kg were given at intervals of 30 days. A pharmacokinetic computer model based on data from 22 clinical trials suggested that this schedule would provide levels above the target trough for 6 months^{Footnote 163}.

The half-life of PVZ is 19-27 days^{Footnote 164}. Trough PVZ levels increase with sequential doses. Mean ± SD trough serum concentrations 30 days after 15 mg/kg doses one, two, three, and four were 37±21 ug/mL, 57± 41 ug/mL, 68±51 ug/mL, and 72±50 ug/mL, respectively^{Footnote 165}. In a study of PVZ in children with CHD, serum concentrations (mean ±SD) before the second and fifth doses were 55.5 ±19 ug/mL and 90.8 ±35 ug/mL. In 139 patients who underwent cardiac bypass, PVZ levels measured just before and the day after bypass were 98.0 ±52 ug/mL and 41.4 ±33 ug/mL, respectively, a decrease of 58% (p=0.0001)^{Footnote 80}. Previous NACI guidance and the AAP state that for children with CHD who will continue to require prophylaxis, a 15 mg/kg dose of PVZ should be given after cardiac bypass^{Footnote 4} ^{Footnote 6}. The AAP also suggests that if prophylaxis is still indicated, an extra 15 mg/kg dose be considered at the conclusion of extracorporeal membrane oxygenation^{Footnote 6}.

The possibility of giving fewer than 5 doses of PVZ has been explored. A recent modeling study predicted that levels of 30 to 40 ug/mL would be maintained for 181 days if doses 1 and 2 were given 29 days apart and the subsequent 3 doses 38 days apart. With only 4 doses these levels would be maintained for 143 days^{Footnote 166}. The CPS recommends that programs should administer a maximum of 3 to 5 doses, with 4 doses probably being sufficient in all risk groups if PVZ is started only when there is RSV activity in the community, especially if doses 2, 3, and 4 are given 38 days apart^{Footnote 8}.

However, administration at 38 day intervals is more complex to implement and may result in more wastage; an interval of 35 days may be more practical. A program in British Columbia gave 4 doses of PVZ with interval of 21-28 days between the first 2 doses and 28-35 days between subsequent doses. RSVH occurred in 10 of 666 infants (1.5 %). All were PVZ breakthrough cases with the exception of one set of twins who were hospitalized 65 days after the 4th dose. Eighteen others (2.7%) were hospitalized for bronchiolitis while receiving PVZ but not tested for RSV. A 3-dose schedule was provided for 514 lower risk children born at 29 to <35 wGA and without chronic lung or CHD. One child was admitted for RSV while receiving PVZ and another was admitted 58 days after the 3rd dose^{Footnote 167}.

A further cohort study of 391 children with CHD in British Columbia who received 4 doses of PVZ 2012 through 2016 showed an admission rate for proven or potential (not tested) RSV lower respiratory tract infection of 6.2 per 100 PVZ approvals^{Footnote 168}, a rate similar to the 5.3% observed in PVZ recipients in a clinical trial of 5 monthly doses in children with CHD (respiratory illnesses that were not tested for RSV were excluded)^{Footnote 80}. Only one child had RSVH more than 30 days following the last dose of PVZ. In another study, protective neutralizing antibody levels (defined as neutralization titre (NT95) of ≥ 1 in 12 dilution) were present at an average of 55 days (range 28-105 days) after the final dose of PVZ. Protective neutralizing antibody levels were also found in 54% of control infants aged 4-11 months who did not receive PVZ, suggesting that humoral response to subclinical RSV infections may contribute to neutralizing titers that persist after PVZ administration^{Footnote 169}.

Concern has been expressed about the substantial inter- and intra- individual variability in PVZ levels^{Footnote 163} ^{Footnote 165} and implications for protection if fewer PVZ doses or longer dose intervals are used. Low trough levels after the first dose has led to suggestions for a shorter interval between the first and second doses^{Footnote 170}. Troughs of <40 ug/ml after the first dose were reported in 33% of recipients^{Footnote 164}. In one report, 46% of breakthrough RSV infections occurred in the interval after the first dose^{Footnote 171} but this high rate has not been replicated in other studies. A retrospective review of 42 patients hospitalized with RSV despite PVZ showing a correlation between lower PVZ levels and admission to an ICU. Mean levels were 47.2 ug/mL in those who required ICU care and 98.7 ug/mL in those who did not (p< 0.0001). In multivariate analysis in the above study, including potential confounding factors, the only parameter associated with ICU admission was PVZ level^{Footnote 172}.

IV.3.2. Dose Schedules and RSV Seasonality

The annual "RSV season" is the period during which the risk of acquiring RSV is sufficiently high to warrant prophylaxis of high risk infants. The season usually starts in October or November in Canada and ends in April or May, with most cases occurring in December through March. The duration of the annual RSV season varies with year and location, and was reported as varying from 13 to 23 weeks in various locations in the USA^{Footnote 7} and from 90 to 181 days in Hamilton, Ontario^{Footnote 173}. Because 5 monthly doses should provide protective levels for > 6 months, a maximum of 5 doses is recommended by the AAP^{Footnote 6}. Use of PVZ can be optimized if local virology laboratory data are used to determine when to begin prophylaxis^{Footnote 173}. Where such data are unavailable, the start date may be determined by paediatric RSVH data, or based on previous seasons. In some areas, 4 monthly doses may be sufficient^{Footnote 174}. In Canada, some programs start routinely in November or December and others use local laboratory and hospitalization data to define the RSV season (see Appendix A). The latter may be more complicated to implement than using fixed dates but may make more efficient use of the product.

Occasional RSVH may be expected before or after the main season in some areas, but maximum benefit from prophylaxis will be achieved during the peak of the season.

IV.4 Safety

PVZ is generally considered to be a safe product. Since the description of adverse events (AEs) in the NACI 2003 PVZ statement^{Footnote 4} there have been no safety alerts, but the number of infants exposed to PVZ has risen considerably. NACI determined that this warranted a new assessment of PVZ safety data. A rapid literature search of publications from 2003 onwards and a review of data from the Canadian Vigilance Program were performed. The full report on PVZ Safety is attached to this document as Appendix B, below.

IV.4.1 Rapid literature review

Nine RCTs, two population based cohort studies, 26 descriptive reports from registries or cohorts, and 2 case reports were identified. The most commonly reported AE considered related to PVZ were injection site reactions, fever, nervousness or irritability, cough, rhinitis, and diarrhea. PVZ related serious adverse events (SAEs) were very rare, reported in 1% or less of recipients, with most studies reporting none. Most were hypersensitivity reactions. Three reports of anaphylaxis were identified. PVZ discontinuation because of AEs occurred in 0-2.3% of recipients. There were no deaths attributable to PVZ. Repeated injections of a humanized monoclonal antibody raised concern for the development of immune mediated disease. Studies showed no increased risk of autoimmune disease or atopy in children exposed to PVZ.

IV.4.2 Data from the Canada vigilance program

A review of AEs reported to the Canada Vigilance Program, Health Canada, identified 259 case reports of AE following PVZ, with 237 classified as serious. The most frequent events were respiratory at 137 (53%), of which 113 were infections, mainly reported because of PVZ product failure, followed by hypersensitivity reactions at 23 (9%). Other events reported are expected complications of the underlying conditions for which PVZ is recommended and are consistent with those reported in the product monograph. The role of PVZ in these AEs is unknown as causality was not assessed.

IV.5 Vaccine administration

PVZ is given at a dose of 15 mg/kg of body weight by intramuscular injection.

For dose intervals and numbers of doses see Immunogenicity, Section IV.3, above.

IV.6 Storage requirements

PVZ should be stored between +2 and +8°C in its original container. It should not be frozen. Vials are for single use and do not contain a preservative.

If an entire vial (50 mg or 100 mg) is not required for a patient's monthly injection, physicians should arrange for more than one patient to receive PVZ within 6 hours^{Footnote 4} or on that same clinic day^{Footnote 175} in order to minimize product wastage. Opened vials containing product not used within 6 hours should be discarded and not stored. Weekly clinics for eligible infants in a specific locality facilitate efficient use with minimal wastage.

IV.7 Simultaneous administration with other vaccines

PVZ is an antibody directed specifically against RSV and does not contain other antibodies or human serum. It is not expected to interfere with the immune response to live or inactivated vaccines ^{Footnote 7} ^{Footnote 129}. Children receiving PVZ should receive all routine childhood vaccines and any other vaccines that may be indicated because of underlying health conditions, following recommended schedules.

IV.8 Contraindications and precautions

Contraindications
Significant hypersensitivity to any component of PVZ is a contraindication to use of this product.

Precautions
Minor illnesses such as the common cold, with or without fever, are not contraindications to use of PVZ. Moderate to severe illness, with or without fever, is a reason to consider deferring PVZ, to avoid superimposing adverse effects from PVZ on the underlying illness, or mistakenly identifying a manifestation of the underlying illness as a complication of PVZ. The decision to delay PVZ depends on the severity and etiology of the underlying disease.

Economics

V.1 Systematic review

A systematic review of the cost-effectiveness of PVZ prophylaxis for RSV was conducted. Studies carried out in OECD countries and published from 2000 to 2018 were reviewed. The original review has been published^{Footnote 176}. For the purposes of NACI's decision-making, changes to the reporting and discussion were made to the original review, and can be found as a NACI Supplement entitled "Cost-Effectiveness of PVZ for Respiratory Syncytial Virus (RSV): A Systematic Review" which will be forthcoming. Changes include currency reported in Canadian dollars, a section on Canadian studies, alternate subgroups reported, and additional commentary. Results from the supplement are summarized here. Of 28 studies included in the final analysis, 20 were cost-utility analyses and 8 were cost-effectiveness analyses. Two economic evaluations were trial-based^{Footnote 177} ^{Footnote 178}, and the rest were considered model-based. Studies were conducted in the US (n=6), Canada (n=5), Netherlands (n=3), the United Kingdom (n=3), Spain (n=3), Austria (n=2), Germany (n=2), and Italy, Mexico, New Zealand, and Sweden (1 each). Base-case analyses were conducted from a health system payer perspective (n=15) or a societal perspective (n=13). Eight of the payer perspective studies performed additional analyses from a societal perspective. The majority of studies were industry sponsored (n=17, 61%). Cost-effectiveness outcomes were reported as ICERs, mostly represented as the incremental cost per additional QALY (n=20) and cost per hospitalization avoided (n=6). ICERs were adjusted to 2017 Canadian dollars (CAD).

PVZ prophylaxis ranged from being a dominant strategy (i.e. less costly and more effective) to having an ICER of $2,975,489/QALY. The wide variation in ICERs depended on the perspective, study setting, population, local RSV epidemiology, healthcare system, and key model input parameters such as rate of reduction in RSVH (39%-96%), estimated RSV-related mortality (1%-8.1%), PVZ costs ($1,099-$2,198 per 100-mg vial), dosage schedules, and vial usage.

V.1.1 Economic evaluations with outcomes expressed in cost per QALY

Data are summarized in Tables 1 and 2. For studies reporting cost-effectiveness in terms of cost per QALY from a health system payer perspective, there were 22 cost-effectiveness estimates for preterm infants, ranging between $6,216 per QALY and $938,623 per QALY ^{Footnote 82} ^{Footnote 179} ^{Footnote 180} ^{Footnote 181} ^{Footnote 182} ^{Footnote 183} ^{Footnote 184} ^{Footnote 185} ^{Footnote 186} ^{Footnote 187} ^{Footnote 188}. The subgroups with the next highest numbers of estimates were (i) preterm infants stratified by risk factor scores ^{Footnote 185} ^{Footnote 186} ^{Footnote 187}, (ii) infants with CHD ^{Footnote 82} ^{Footnote 179} ^{Footnote 181} ^{Footnote 182} ^{Footnote 190} ^{Footnote 191} ^{Footnote 192}, and (iii) infants with CLD ^{Footnote 82} ^{Footnote 181} ^{Footnote 182} ^{Footnote 187} ^{Footnote 191}. The proportion of reported cost-effectiveness estimates that fall below different thresholds is shown in Table 1. The largest agreement among reported estimates falling below the commonly used threshold of $50,000/QALY were infants with CLD (n =6 out of 6 studies), preterm infants (n=18/22), and infants with CHD (n=8/10). For premature infants no specific trend was detected between wGA and the ICER. From a societal perspective, PVZ prophylaxis was considered a dominant strategy (i.e. less costly and more effective) in some instances for preterm infants ^{Footnote 183} ^{Footnote 193} ^{Footnote 194} ^{Footnote 195}, term infants in the Canadian Arctic^{Footnote 196}, and infants with CHD^{Footnote 182}. However, there was high heterogeneity in the study design and model parameters among reviewed studies including those that reported PVZ prophylaxis to be a dominant strategy. There does not appear to be a common driver for dominance of PVZ prophylaxis. In other scenarios, ICERs <$200,000/QALY were observed. Generally, one would expect ICERs from a societal perspective to be lower than those from a payer perspective, but this trend was not observed. Payer and societal perspective estimates frequently came from different studies and there was heterogeneity in model designs and differences between setting-specific costs and RSV epidemiology that may account for larger ICERs under a societal perspective.

Twelve of these studies were industry sponsored. It was noted that 50% of all estimates of <$200,000/QALY and 19% of all estimates of >$200,000/QALY were from studies funded by industry (S. Mac personal communication Mar 2019).

Table 6 Summary of ICER estimates by health condition and perspective (N= 20 studies)
	Health Conditions
	CLD	CHD	Preterm	Preterm with CLD	Preterm with risk factors^{Footnote *}	CF	Canadian Artic^{Footnote **}
	CLD	CHD	Preterm	Preterm with CLD	Preterm with risk factors^{Footnote *}	CF	All infants	High risk areas
Payer perspective
Number of estimates	6	10	22	4	14	2	6	2
ICER (Minimum)	4,786	11,668	6,216	15,202	215	167,107	Dominant	Dominant
ICER (Maximum)	46,821	164,946	938,623	131,874	205,563	693,105	178,057	391
Proportion of estimates that are dominant	0.0	0.0	0.0	0.0	0.0	0.0	0.17	0.50
Proportion of estimates CE below $50,000/QALY	1.00	0.80	0.82	0.75	0.64	0.0	0.67	1.00
Proportion of estimates CE below $100,000/QALY	1.00	0.90	0.86	0.75	0.86	0.0	0.67	1.00
Proportion of estimates CE below $200,000/QALY	1.00	1.00	0.91	1.00	0.92	0.50	1.00	1.00
Societal perspective
Number of estimates	1	8	23	3	6	0	6	2
ICER (Minimum)	28,529	Dominant	Dominant	18,717	21,931	N/A	Dominant	Dominant
ICER (Maximum)	28,529	209,666	2,975,489	138,282	635,172	N/A	175,291	Dominant
Proportion of estimates that are dominant	0.0	0.13	0.13	0.0	0.0	N/A	0.17	1.00
Proportion of estimates CE below$50,000/QALY	1.00	0.63	0.39	0.67	0.17	N/A	0.67	1.00
Proportion of estimates CE below $100,000/QALY	1.00	0.63	0.48	0.67	0.50	N/A	0.67	1.00
Proportion of estimates CE below $200,000/QALY	1.00	0.88	0.52	1.00	0.67	N/A	1.00	1.00
Table 6 - Footnote * Major risk factors: chronological age < 10 weeks at beginning of the RSV season, being born during the first 10 weeks of the RSV season, school aged siblings, day-care attendance. Minor risk factors: mother smoking during pregnancy, male gender. Return to Table 6 Footnote * referrer Table 6 - Footnote Infants less than 1 year of age living in Baffin Island and infants less than 1 year of age living in high risk areas of Baffin Island (defined as having RSV hospitalization rates over 500 per 1,000 live births). Effectiveness estimate in the model is from a study of preterm infants. Return to Table 6 Footnote referrer All ICERs are reported in 2017 Canadian dollars (CAD) / QALY. Dominant = less costly and more effective CLD, chronic lung disease; CHD, CHD; CF cystic fibrosis N/A: Not available

Table 7. Summary of ICER estimates by gestational age and perspective (N= 14 studies)
	ICERS: Preterm by Gestational Age in weeks (wGA)
	26-28	< 29	29-30	29-32	< 32	< 33	32-35
Payer perspective
Number of estimates	N/A	3	N/A	3	2	3	6
ICER (Minimum)	N/A	6,216	N/A	9,989	12,710	16,434	26,170
ICER (Maximum)	N/A	24,009	N/A	58,872	25,065	42,730	919,073
Proportion of estimates that are dominant	N/A	0.00	N/A	0.00	0.00	0.00	0.00
Proportion of estimates CE below $50,000/QALY	N/A	1.00	N/A	0.67	1.00	1.00	0.67
Proportion of estimates CE below $100,000/QALY	N/A	1.00	N/A	1.00	1.00	1.00	0.67
Proportion of estimates CE below $200,000/QALY	N/A	1.00	N/A	1.00	1.00	1.00	0.83
Societal perspective
Number of estimates	4	5	2	N/A	3	N/A	4
ICER (Minimum)	165,301	22,765	449,264	N/A	Dominant	N/A	32,390
ICER (Maximum)	2,406,619	1,359,641	1,083,976	N/A	Dominant	N/A	338,823
Proportion of estimates that are dominant	0.00	0.00	0.00	N/A	1.00	N/A	0.00
Proportion of estimates CE below$50,000/QALY	0.00	0.40	0.00	N/A	1.00	N/A	0.75
Proportion of estimates CE below $100,000/QALY	0.00	0.80	0.00	N/A	1.00	N/A	0.75
Proportion of estimates CE below $200,000/QALY	0.25	0.80	0.00	N/A	1.00	N/A	0.75
All ICERs are reported in 2017 Canadian dollars (CAD) / QALY. Dominant = less costly and more effective N/A: Not available

V.1.2 Economic Evaluations with Outcomes Expressed in Costs per Hospitalizations Avoided

Six studies reported cost-effectiveness in terms of cost per hospitalizations avoided (HA) ^{Footnote 179} ^{Footnote 197} ^{Footnote 198} ^{Footnote 199} ^{Footnote 200} ^{Footnote 201}. A study of healthy term infants in different regions of the Canadian Arctic compared two scenarios of PVZ prophylaxis for infants who were less than 6 months of age, from a payer perspective. The ICER ranged from being dominant (i.e. less costly and more effective) in specific Arctic regions to $593,250/HA in the Northwest Territories^{Footnote 197}. Also from the payer perspective, a Florida study of preterm infants (<32 wGA), term infants with CHD, CLD, combinations of all three groups and infants with no indications for PVZ) reported ICERs between $413,127/HA (preterm infants) and $2,924,911/HA (infants with no indication)^{Footnote 201}.

From a societal perspective, a study from the Netherlands of preterm infants (< 28 wGA) with additional risk factors (BPD, male sex, birth weight < 2,500 grams) found ICERs ranging between $24,875/HA and $1,572,268/HA depending on the month of the prophylaxis^{Footnote 198}. In a study from Germany of preterm infants (<35 wGA) with additional risk factors, from a societal perspective ICERs ranged between $11,821/HA and $364,462/HA for preterm infants with CLD and risk factors and preterm male infants without CLD and with no siblings in school, respectively^{Footnote 199}. A New Zealand study analyzed cost-effectiveness of prophylaxis in preterm infants (<28, 29-31 wGA) with or without CLD from a societal perspective. The ICERs ranged from $33,376/HA for preterm infants discharged home on oxygen, to $37,213/HA for infants ≤ 28 wGA with no CLD, to $193,859/HA for preterm (29-31 wGA) infants with CLD^{Footnote 200}.

V.1.3 Economic Evaluations with Outcomes Expressed In Other Ratios

An economic evaluation on term infants with CHD in western Canada found that from a societal perspective, the base-case ICER was $18,155 per one day of hospitalization avoided^{Footnote 148}. A study of preterm infants (< 32 wGA) or with CLD or significant CHD in France found that from a societal perspective, the base-case ICER was $43,856/Life year (LY) gained and $33,450/LY gained for preterm infants with CLD and preterm infants with CHD, respectively. From a payer perspective, the ICER was $16,368/LY gained for infants with CLD^{Footnote 202}. In a study of preterm infants with CLD in the US, the model used a reduction in incidence of RSV infection, ranging from 50% ($66,494 per RSV infection episode avoided) to 83% reduction (PVZ prophylaxis a dominant strategy, i.e. less costly and more effective) from a payer perspective^{Footnote 178}.

V.1.4 Economic Evaluations in Canadian Settings

There were five economic evaluations conducted in Canadian settings ^{Footnote 148} ^{Footnote 186} ^{Footnote 189} ^{Footnote 196} ^{Footnote 197}. Populations studied were term infants from the Canadian Arctic^{Footnote 196} ^{Footnote 197}, preterm infants^{Footnote 186}, infants with CF^{Footnote 189}, and infants with CHD^{Footnote 148}. These studies assumed 4.5 to 6 doses of PVZ per RSV season at a cost of $1,599 - $1,718 (2017 CAD) per 100 mg of PVZ. In the above studies, the effectiveness of PVZ was measured in reduction in RSVH, which ranged between 42% and 96%. Mortality rates were incorporated into two models, at 1% and 8.1%^{Footnote 186} ^{Footnote 196}. Sequelae were incorporated into two models (in one sequelae of RSV infection, the other sequelae associated with CF)^{Footnote 186} ^{Footnote 189}. The most influential parameters on the cost-effectiveness outcomes in the five Canadian studies were: RSVH rates^{Footnote 196} ^{Footnote 197}, cost of PVZ^{Footnote 148} ^{Footnote 189}, and cost for hospitalization ^{Footnote 196} ^{Footnote 197}, which includes inpatient medical costs and transportation costs to the medical centre.

In the Canadian Arctic, PVZ prophylaxis was considered cost-effective for some subgroups of infants as PVZ can prevent the high costs of hospitalizations related to transportation costs. This was especially the case for settings where baseline RSVH rates were high. From a payer perspective, PVZ can be considered cost-effective under commonly used thresholds for all Baffin Island term infants < 1 year of age ($46,151/QALY) or < 6 months of age ($11,925/QALY), all term infants < 1 year of age in rural areas ($28,965/QALY), infants < 1 year of age in high-risk rural areas ($391/QALY), and infants < 6 months of age in rural areas or in high-risk rural areas (dominant). However, it was not cost-effective for infants < 1 year of age ($178,057/QALY) or < 6 months of age ($120,817/QALY) residing in Iqaluit^{Footnote 196}. ICERs were not cost-effective in the city because PVZ did not prevent transportation costs associated with an RSVH. From a societal perspective, ICERs were slightly lower but followed a similar trend. Banerji et al. included term infants from eight Arctic regions: the Northwest Territories, Nunavut, Nunavut without Iqaluit, the three sub-regions of Nunavut (Kitikmeot, Kivalliq and Qikiqtaaluk), the Qikiqtaaluk Region without Iqaluit, and Nunavik (northern Quebec); and reported costs per HA in two separate scenarios: prophylaxis until the end of the RSV season (scenario A) and prophylaxis until 5 months of age (scenario B). PVZ prophylaxis was a dominant strategy (i.e. less costly and more effective) in Kitikmeot (scenarios A and B) and Kivalliq (scenario B); $24,981/HA in Kivalliq (scenario A); $5,042/HA (scenario B) and $31,104/HA (scenario A) in Nunavut without Iqaluit; $15,829/HA (scenario B) and $45,060/HA (scenario A) in Nunavut; $16,979/HA (scenario B) $32,899/HA (scenario A) in Nunavik. In all other regions, ICERs were greater than $100,000/HA^{Footnote 197}. There was much variation in ICERs by region. PVZ tended to be cost-effective at a threshold of $50,000/QALY in regions with higher RSVH rates (range: 97.8 to 296.1 RSV admissions per 1,000 in Nunavik, Kivalliq region, Kitikmeot region, and Nunavut), whereas PVZ tended to be not cost-effective at a threshold of $100,000/QALY in regions with lower RSVH rates (range: 16.6 to 49.4 RSV admissions per 1,000 in the Northwest Territories and Qikiqtaaluk region)^{Footnote 197}.

From the payer perspective, PVZ was considered cost-effective under commonly used thresholds for preterm infants of 32-35 weeks GA ($20,814/QALY including asthma as a consequence of RSV infection and $35,119/QALY excluding asthma). Using two sets of risk factor scores, ICERs were $251/QALY and $5,906/QALY for infants with high scores (high risk), $29,901/QALY and $38,566/QALY with medium scores, and > $50,000/QALY ($92,649 - $919,073) for lower scores or no risk factors^{Footnote 186}. For infants less than 24 months of age with CF, PVZ was determined unlikely to be cost-effective from a payer perspective ($693,105/QALY for all and $167,107/QALY for high risk infants)^{Footnote 189}. In the study of PVZ cost-effectiveness in children < 24 months of age with CHD, from a societal perspective the ICER was $18,155/day of hospitalization avoided and considered unlikely to be cost-effective^{Footnote 148}.

These latter three studies may be generalizable to most Canadian provinces given they used PVZ costs ($1,468 - $1,505 per 100 mg vial, original costs) similar to those in other Canadian provinces, dosing schedules close to 5 injections per season (4.5 to 5.39 vials per season), healthcare costs from British Columbia and Ontario, and included model parameters of relevance to the Canadian healthcare system. Studies of cost-effectiveness of PVZ prophylaxis for infants from smaller Canadian provinces (e.g. Maritimes provinces) were lacking.

Table 8. Characteristics of Canadian Studies
Authors, Year	Population	Dosage (per season)	Cost per unit (Unadjusted)	Hospitalization			Mortality	RSV-Sequelae included?
Authors, Year	Population	Dosage (per season)	Cost per unit (Unadjusted)	PVZ	No PVZ	Reduction (%)	Mortality	RSV-Sequelae included?
Tamet al., 2009^{Footnote 196}	Baffin Island Term infants	5 doses	Vial unit cost: NR; $220/kg infant	1.4 - 11.4%	6.3 - 51.2%	78%^{Table 8 Footnote a}	1% (both groups)	No
Banerji et al., 2016^{Footnote 23}	Canadian Arctic Term infants	6 doses (maximum)	Vial unit cost: NR; $226/kg infant	NR	NR	96%	NR	No
Smartet al., 2010^{Footnote 186}	Premature 32-35 wGA	5.39 vials	50mg: $752 100mg: $1,505	1.8%	10.0%	NR (82% back calculation)	3.9% (both groups)^{Table 8 Footnote b}	Yes / No (asthma)
McGirr et al., 2017^{Footnote 189}	Cystic fibrosis age <24 months	5 doses	100mg: $1,505	1.7% (assuming 55% reduction)^{Table 8 Footnote c}	3.8%	55%	NR (Used CF-related death)	Yes (cystic fibrosis progression)
Harris et al., 2011^{Footnote 148}	CHD age <24 months	4.5 doses	100mg: $1,468	1.7%	2.9%	NR (42% back calculation)	NR 0.2% (1/41, no PVZ); 0% (0/292, PVZ)	No
Table 8 Footnote a Estimate = IMPACT data for premature infants Return to footnote a referrer Table 8 Footnote b Annual mortality rate based on a Canadian sample of premature infants (33-35 wGA) hospitalized with RSV Return to footnote b referrer Table 8 Footnote c Hospitalization rates x 3.6 RR (for high-risk CF infants) Return to footnote c referrer NR: not reported

V.1.5 Heterogeneity in Results: Key Parameters

The most frequently reported influential parameters affecting the ICER were the RSVH rates and cost of PVZ used. Reduction in RSVH varied drastically between 39% and 96% depending on the population of interest, and the source of the data. The cost of a 100mg vial of PVZ also ranged between $1,099 and $2,198 (2017 CAD). However, vial usage and dosage scheme only affected the ICERs in four^{Footnote 181} ^{Footnote 183} ^{Footnote 195} ^{Footnote 200}, and three studies^{Footnote 185} ^{Footnote 187} ^{Footnote 200}, respectively. In studies addressing drug wastage, ICERs fluctuated up to 50% depending on the assumed vial usage. In a New Zealand study, assuming no vial sharing (entire 100 mg vial is used per injection) increased cost per case averted by up to 50% (i.e. worse value for money)^{Footnote 200}, while another study in Spain concluded a lower ICER (i.e. better value for money) when 50-mg vials were used instead of 100mg^{Footnote 183}. It has been suggested in the literature that vial usage efficiency can be achieved for PVZ^{Footnote 203}. Discounting was also frequently reported as being influential on the ICER. Discount rates varied across studies (3-5%). Currently Canadian guidelines recommend a discount rate of 1.5% for costs and outcomes^{Footnote 204}.

V.1.6 Generalizability of Included Studies to Canadian Setting

Most study results may be broadly generalizable to the Canadian healthcare system since these were economic evaluations conducted in OECD countries with healthcare components similar to Canada^{Footnote 205}. The only exceptions were the six studies from the US. Choice of payer or societal perspective may influence the costs and the benefits included in the analysis. Among the studies that used a societal perspective, the following costs outside of the healthcare system were considered: time loss from work due to asthma; indirect costs of nosocomial infections; travel costs (i.e. hotel, transportation); productivity loss (i.e. caregiving, leisure, future productivity of children); and school absenteeism.

From three Canadian studies, the cost per 100-mg vial of PVZ used in models was between $1,599 and $1,718 (2017 CAD). Models from the UK used a lower PVZ cost of $1,099 to $1,240 per 100-mg vial, and costs in the remaining studies (with the exception of those from the US) were between $1,386 and $2,035 (2017 CAD). The number of doses per season ranged between 3.88 and 6 doses. In the subset of countries with similar healthcare structure to Canada, almost all models assumed five doses of PVZ per season, except for Resch et al. (Austria)^{Footnote 82}, Nuijten et al., Sanchez-Luna et al., and Schmidt et al. (all from Spain), where the average number of doses was 4 per season^{Footnote 183} ^{Footnote 185} ^{Footnote 195}.

Despite the similarities in PVZ prophylaxis cost and dosage schedule, estimated reduction rates of RSVH varied from 39% to 96% depending on the infant population, and literature referenced. Sixty-eight percent of the studies (S. Mac personal communication June 2019) used the IMPACT-RSV trial for some of their model parameters, a trial that included Canadian children and concluded that reduction in RSVH was 78% for preterm infants, 39% for children with CLD and 55% overall. While the subgroup of Canadian subjects in that study showed a 40% overall reduction in RSVH, the trend was similar to that seen in US (56%), and UK subjects (64%)^{Footnote 48}. It is noted that the IMPACT-RSV trial was carried out in 1996 and that with changes in the management of prematurity, CLD and CHD, as well as RSV infection, model parameters based on that study may not be appropriate today.

V.2 Cost-effectiveness study in Nunavik, Quebec

In addition to the studies in the systematic review, preliminary results of a cost-effectiveness study in the region of Nunavik, Northern Quebec were reported to NACI on March 13, 2019 (R. Gilca, Institut national de santé publique de Québec, personal communication, Nov. 18 2020)^{Footnote 206}. Starting in the 2016-17 season, healthy full-term infants <3 months of age at the start of the RSV season or born during the RSV season became eligible for up to 3 doses of PVZ. For the 2017-18 season, infants meeting these criteria were eligible for up to 5 doses. The objectives were to estimate the healthcare cost of RSVH in the targeted population and the cost of the PVZ program, and to estimate cost per hospitalization averted.

The analysis below is based on the first 2 years of the program. It is being updated to include 4 years of data and will be published. The conclusions remain unchanged.

Table 9: PVZ effectiveness
Date	Incidence of RSVH per 100 000 patient-days		Effectiveness^{Table 9 Footnote *}
Date	Unprotected	PVZ - Protected	Effectiveness^{Table 9 Footnote *}
2017
January 1 to April 30	58.1	37.5	35.5%
January 1 to May 31	45.5	33.8	25.7%
2018
January 1 to May 31	22.5	14.5	35.6%
January 1 to June 30	17.8	13.0	27.3%
Table 9 - Footnote * Effectiveness= 1- (incidence with PVZ /Incidence without PVZ) Return to Table 9 Footnote * referrer

Table 10: Scenarios of averted costs
Scenarios / hypotheses	Averted costs: (average cost in absence of program, 2014-2016 = $156,914)	2017			2018
Scenarios / hypotheses		total costs for program	ratio spent/averted	ROI	total costs for program	ratio spent /averted	ROI
1. PVZ effectiveness = 36%^{Footnote *}; cost reduction is proportional to effectiveness	$55,861	$291,533	5	0.19	$369,641	7	0.15
2. All observed reduction in 2017 is due to PVZ (reduction=89%)^{Footnote **}	$139,395	$291,533	2	0.48	$369,641	3	0.38
3. All observed reduction in 2018 is due to PVZ (reduction=71%)^{Footnote **}	$112,040	$291,533	3	0.38	$369,641	3	0.30
Table 10 - Footnote * The highest estimated effectiveness value, based on 2017 and 2018 seasons Return to Table 10 Footnote * referrer Table 10 - Footnote Extreme scenario Return to Table 10 Footnote referrer ROI: return on investment

The program costs far exceeded hospitalization and transportation costs. To be cost-neutral, the program would need to prevent 9 to 11 hospitalizations per year (total program costs / average 2014-2016 cost per hospitalization = $33,600). Such a high number of hospitalizations has not been observed in this population (average for 2014-2016 = 7 hospitalizations)

There are several limitations to this study, including the small population size, with approximately 220 healthy term infants born between October 1 and June 30 annually, and scattered across many very small communities. The number of hospitalizations of healthy full-term 0-2-month-old infants from Nunavik was low (lower than previously anticipated) and highly variable from year to year. The total costs for hospitalization and transportation are therefore also highly variable. The program cost is similar from year to year. The cost of PVZ is the main component but administration cost is not negligible (>$135/dose). Effectiveness of PVZ to prevent RSVH was low. Many hospitalized infants had co-infections with other viruses. There were also issues of social acceptability and compliance with the PVZ program.

Ethics, equity, feasibility and acceptability (EEFA) considerations

The peer-reviewed EEFA Framework^{Footnote 13} was applied to this guidance to ensure the systematic consideration of factors critical for comprehensive immunization program decision-making and successful implementation of recommendations. The use of this EEFA Framework empowers the committee to review and balance all of the available evidence and transparently summarize their rationale for appropriate, timely recommendations. The evidence-informed tools associated with the framework (Ethics Integrated Filters, Equity Matrix, Feasibility Matrix, Acceptability Matrix) ensure that issues related to EEFA of expert committee guidance are systematically and adequately integrated.

Ethics considerations

To support ethics deliberation and decision-making, NACI's Ethics Integrated Filters for core ethical dimensions (respect for persons and communities, beneficence and non-maleficence, justice, trust) and procedural ethical dimensions (accountability, inclusiveness, responsibility, responsiveness, transparency) were applied. NACI followed its established methodology, standard operating procedures (SOP), and conflict of interest guidelines to ensure a robust analysis of evidence, with transparency about knowns and unknowns, as well as certainty of evidence, and to maintain stakeholder trust. In order to respect the right to exercise informed choice, NACI reviewed the best, current evidence available for groups of infants and children at risk of RSV and summarized it for stakeholders throughout this guidance document, including recent data on burden of illness due to RSV disease, the efficacy and effectiveness of PVZ in infants at risk of more severe RSV disease and economic implications of PVZ use. NACI also considered evidence for minimizing the risk of harm and maximizing benefits for all potential key populations in their deliberations. These findings should be interpreted with caution given that some potential concerns were identified regarding availability of evidence; small numbers of articles were identified for some risk groups and situations and there was significant heterogeneity in methodology used and the outcomes studied. Furthermore, with no evidence of lowered mortality rates from RSV or of long term benefit from PVZ, the high cost of PVZ prophylaxis programs must also be balanced against costs of other health care interventions if these other interventions may be compromised by provision of PVZ programs. Therefore, NACI will continue to monitor the evidence related to use of PVZ in different groups, including the cost-effectiveness of PVZ programs and alternative dosage schedules and newer products which may be more cost-effective and will update the statement and its recommendations as needed.

Equity considerations

NACI reviewed the epidemiology of RSV and the results of the systematic review on the burden of RSV disease in young children in high-income countries comparable to Canada (summarized in Section III) to identify distinct inequities associated with COVID-19, potential reasons for these inequities, and suggested interventions to reduce inequities and improve access to vaccine when it becomes available.

The risk of severe RSV illness is influenced by gestational age at birth, underlying health conditions, and age. As it is not feasible to provide PVZ prophylaxis to all infants at some increased risk of RSV disease, in principle it should be provided to high risk groups at equivalent risk of severe disease. Specific recommendations are needed for selective PVZ prophylaxis for identifiable high-risk subgroups of infants and children who are more vulnerable than others to the adverse effects of RSV infection, and whose risk of severe outcome are within a similar range and for whom PVZ prophylaxis has been shown to be effective. However, the limited nature and heterogeneity of the data available makes assessment of degree of risk somewhat arbitrary. For certain very rare conditions, risk of severe RSV illness may be high but epidemiologic data are not available, and the number of children with certain rare diseases may not be sufficient for PVZ effectiveness to be studied. In these circumstances, extrapolation may be made from data on conditions of pathophysiological similarity with documented increased risk of RSV and where PVZ has been shown to be effective. In most provinces and territories, physicians may request PVZ by exception for children that do not meet specific criteria for PVZ. While this permits flexibility for use in children with rare conditions, it may also introduce inequity. Those making requests for exceptions and those assessing these requests must do so fairly, to avoid inequity.

Infants living in remote northern Inuit communities and other remote rural communities may also be at increased risk of severe outcomes resulting from RSV infection. Limited local access to medical care may necessitate medical evacuations requiring air transportation to hospital facilities. Therefore, additional resources may be needed for provision of PVZ prophylaxis and for monitoring and follow-up of infants living in remote locations. PVZ prophylaxis should also be provided as close to home as possible given that the number and frequency of visits over a short period of time and the strict injection intervals may be a barrier for families due to out-of-pocket expenses if the family has to travel some distance to receive PVZ and/or take time off work for these visits. In these cases, assistance may need to be given to some families so that they can benefit from the PVZ prophylaxis program. NACI will continue to monitor the evidence related to severity of RSV disease in infants with pre-existing conditions and in infants living in remote northern Inuit communities and other remote rural communities.

Feasibility considerations

Provision of PVZ prophylaxis is complex and integration into existing active vaccination programs is not feasible due to the dosing schedule and the seasonal nature of the disease. In particular, the need for multiple injections over a short time period may create scheduling challenges; up to 4 doses must be given at 28-35 day intervals during the period that the local annual RSV outbreak is underway. Unlike vaccines, PVZ dose depends on weight and precise timing of visits for PVZ administration is crucial for appropriate protection and it is not possible to combine all visits with visits for other vaccines or routine child care. Additionally, PVZ is provided in multi-dose vials which, once opened, must be used within 6 hours or discarded and wasted. Vial sharing may be difficult in smaller communities where very few children are candidates for PVZ, further increasing the cost. Therefore, important considerations for the implementation of a new PVZ prophylaxis program include limiting prophylaxis to those groups at highest risk of severe outcomes, scheduling specific PVZ clinics during the RSV season, recognizing the potential impact on existing local programs, and involving of local care givers in planning for program implementation.

Acceptability considerations

Very limited acceptability data are currently available specific to PVZ prophylaxis and the perception of RSV disease in parents or guardians of high risk infants. Likely barriers to acceptability and adherence include:

The number and frequency of visits, especially if families have to travel some distance to receive prophylaxis and it is not possible to combine visits for PVZ with visits for other vaccines or routine health care needs.
Out-of-pocket expenses if appointments require long-distance travel to the treatment center and time away from work.
Lack of knowledge about the risk of RSV infection in high risk children.

There is some evidence indicating that Indigenous populations in Canada are at higher risk of non-adherence than non-Indigenous populations and that acceptance is lower in remote northern populations^{Footnote 207} ^{Footnote 208}. Nurses and midwives working with a population in the Canadian North have also expressed concerns regarding lack of data about the efficacy and safety of PVZ in healthy term infants^{Footnote 207}. Low acceptability of PVZ prophylaxis by families may result in decreased adherence to PVZ schedules and diminish effectiveness^{Footnote 209}. Therefore, implementation of a new program should include ongoing education of local health care providers, families and guardians of infants for whom PVZ is indicated, and their active involvement in planning of the intervention. Provision of PVZ in local clinics as close to home as is feasible and sufficient resources to provide assistance for families who may need some additional support to be able to travel to the clinic are also important considerations.

Recommendations

Following the thorough review of available evidence summarized above, as well as the systematic assessment of ethics, equity, feasibility and acceptability considerations with the peer-reviewed EEFA Framework, NACI makes the following evidence-informed recommendations.

Recommendations for public health program level decision-making

(i.e. provinces/territories making decisions for publicly funded immunization programs)

In considering these recommendations and for the purposes of publicly funded program implementation, provinces and territories may take into account local programmatic factors (e.g. current programs, resources). Recognizing that there are differences in operational contexts across Canada, jurisdictions may wish to refer to the Management Options Table below for a summary of the relative merits of vaccinating different high risk groups, if prioritization of targeted immunization programs is required for implementation.

1. Preterm infants without CHD or CLD:

Recommendation 1.1: NACI recommends that PVZ should be offered to infants born at < 30 weeks, 0 days gestation and aged < 6 months at the onset of or during the RSV season. (Strong NACI Recommendation)

NACI concludes that there is fair evidence to recommend PVZ use in this population (Grade B evidence).

Recommendation 1.2: NACI recommends that PVZ may be considered for infants of 30 to 32 weeks, 6 days gestation aged < 3 months at the onset of or during the RSV season if they are at high risk of exposure to RSV from day care attendance or presence of another preschool child or children in the home. (Discretionary NACI Recommendation)

NACI concludes that there is insufficient evidence to recommend PVZ use in this population (Grade I evidence). Therefore, this recommendation is based on expert opinion.

Recommendation 1.3: NACI recommends that PVZ should not be offered to otherwise healthy infants born at or after 33 weeks, 0 days gestation (Strong NACI Recommendation)

NACI concludes that there is fair evidence to recommend against PVZ use in this population (Grade C evidence).