Background
Respiratory syncytial virus (RSV) is the most common etiologic agent for acute respiratory infections overall and for lower respiratory tract infections (LRTI) - bronchiolitis and pneumonia in infants. RSV causes between 50,000 and 125,000 annual hospitalizations of US children younger than 5 years [
1,
2]. In 2015, RSV was responsible for 33.1 million LRT infections worldwide, approximately 3.2 million hospital admissions, and 59,600 in-hospital deaths in children younger than 5 years [
3]. RSV is a leading cause of hospitalization for infants less than 2 years of age [
4‐
6]. Risk factors for severe illness and mortality are preterm birth, chronic lung disease (CLD), hemodynamically significant congenital heart disease (CHD), age less than 3 months, neuromuscular disorders, and immunodeficiency [
4,
7]. Healthy full-term or near-term infants of 34–37 gestational weeks (GW), can be affected too [
8]. RSV is mainly transmitted by aerosols or direct contact with contaminated surfaces where the virus can remain virulent for hours. The incubation period is between 4 and 5 days with initial viral replication in the nasopharynx; thereafter the virus can cause LRTI [
9]. As a highly contagious pathogen, RSV carries a high risk of nosocomial spreads in Neonatal Intensive Care Units (NICU) and RSV outbreaks are more frequent than suspected [
10].
There is currently no licensed vaccine to prevent RSV infection, but in the past two decades, passive immunoprophylaxis for high-risk infants was increasingly implemented using a monoclonal antibody, palivizumab [
11,
12]. This reduced the risk of RSV-LRTI hospitalizations for these infants [
13,
14].
In Bulgaria, RSV was the most frequently detected etiologic agent of LRTI in children under the age of 5 for the seasons 2014/15, 2015/16, 2016/17, 2017/18 [
15,
16]. The palivizumab prophylaxis started in 2010 for the most vulnerable groups with a gradual extension of the indications in the subsequent years. To date, there are no national guidelines for the use of palivizumab in NICUs, or control of in-hospital RSV outbreaks.
Methods
This study reports retrospectively data on case series, and analyses the nosocomial outbreak of RSV infections among inborn infants in the Neonatology clinic of the University Hospital of Obstetrics and Gynaecology “Maichin dom”, Sofia, for the period February–March 2019. The hospital is a tertiary care center for high-risk pregnancies and neonates with 3500–4200 deliveries per year. Healthy babies are cared for in two neonatal wards, with 35 baby beds each. One of the wards uses a rooming-in system. In the other one, the neonates are cared for in the well-baby nursery and stay with their mothers only during breastfeeding. The newborns are admitted to a particular ward, according to the preferences of the parents. Feedback on all problems in the first month after discharge is obtained from the outpatient pediatric practices. The NICU contains 45 beds: 15 intensive and 30 special care beds, separated into 7 boxes. Periods of overcrowding are not excluded. The NICU patients are usually cared for by 8 nurses in each shift. The physicians who work at the NICU are not the same who work at the healthy baby wards. During their daily visits, the parents are encouraged to take part in caring for and feeding the baby if the condition is stable. The practice in our NICU is to stimulate breastfeeding or bottle/ gastric tube feeding with expressed milk using breast-milk fortifiers for the most immature babies.
The epidemic RSV-outbreak, we report here, affected two groups of newborns without contact with each other. Group 1 included 14 healthy term infants, who were cared for in the well-baby nursery, and became symptomatic for LRTI 3 to 5 days after discharge from the hospital. Group 2 included 7 preterm infants with direct (one room), or indirect (caregivers, parents) contact with each other who were treated in the NICU (NICU-patients), and became RSV-positive during the hospital stay. The diagnosis of LRTI was based on standard clinical criteria [
17]. Clinical information, including demographic characteristics, symptoms, diagnosis, comorbid illnesses, and the outcome was documented in the hospital case reports. All parents were informed in detail about the disease. Written informed consent for the diagnostics, testing, manipulations, and treatment was obtained. The detection of RSV was performed using Real-Time Polymerase Chain Reaction (PCR). Nasal and pharyngeal specimens were collected and were transported immediately to the National Laboratory “Influenza and Acute Respiratory Diseases”, and were analyzed for viral respiratory pathogens. The results were available the next day. The primers/probes and protocol used in the study were identical to those described by Kodani et al. [
18]. Subgroup-specific primers and probes targeting F and N genes of the RSV were applied to determine the RSV-A and RSV-B respectively, using Multiplex Real-Time PCR.
The following measures have been taken to control the epidemic outbreaks:
At the healthy baby ward, strict administration of the standard infection control procedures was carried out: intensification of the disinfection regime; use of gowns, gloves, and masks; regular hand washing and disinfection; restricted visits for relatives other than the mother; denied access for medical staff/parents with respiratory symptoms.
At the NICU
All infection control procedures mentioned above were applied. As the RSV season was combined with a peak of other seasonal respiratory tract infections, the visits of parents or relatives in the NICU were limited until this outbreak was overcome. Only mothers without respiratory symptoms, who were not discharged from the hospital, were allowed to visit their NICU babies for this period. The RSV-positive infants were separated from the other NICU patients; cohort nursing for these groups was applied. RSV-PCR testing was performed on all 26 patients treated in the special care ward. Regardless of the PCR results immunoprophylaxis with 15 mg/kg palivizumab was administered to all these infants.
Discussion
Here, we describe the first nosocomial RSV-epidemic outbreak in a neonatology clinic since the routine RSV-diagnostics by PCR in Bulgaria was introduced (2013/2014). In the years before this outbreak only isolated cases of RSV infections during the RSV seasons were observed in the NICUs.
RSV is the most common viral pathogen in LRTI infections for infants aged less than 5 years. According to various authors, RSV causes 50–90% of hospitalizations due to bronchiolitis, 5–40% of hospitalizations due to pneumonia, and 10–30% of hospitalizations due to tracheobronchitis [
19‐
21]. In Bulgaria, for the seasons 2015/16, 2016/17, and 2017/18, RSV was identified in 44.5% of the infants with bronchiolitis and 25.1% of those with pneumonia [
16]. During the season 2014–2015, serotype A dominated, while over the next three seasons RSV-B was dominant [
15,
16]. In our NICU samples, where typing was possible, RSV-B was proven. In Bulgaria, there is a pronounced seasonality of RSV infections during December–March with a peak of diseases in February [
15,
16], i.e., the epidemic outbreak described here occurred in the second half of the RSV season.
For the affected full-term infants (Group 1) the symptoms of LRTI appear a few days after discharge from the well-baby nursery. So, they must have acquired the infection during the hospital stay from RSV-positive visitors or healthcare personal with or without respiratory symptoms. Although the mode of transmission of RSV facilitates its spread among the babies [
9], the role of the medical staff and gaps in the anti-epidemic regime should be discussed. Unfortunately, in the outbreak, described here, the source of the infection (medical staff or visitors) was not identified. It is important to mention that, there was not a single case of RSV infection among babies cared for in the roaming-in ward. This is likely related to the limited contact with health care personnel, other mothers, or visitors and demonstrates the advantages of the rooming-in system in preventing nosocomial respiratory tract infections in neonatal wards for healthy babies. Furthermore, in such wards, the mothers are actively involved in caring for their infants.
Preterm infants with or without BPD are at increased risk of severe RSV-LRTI during the first 2 years of life. Palivizumab, a monoclonal antibody to the RSV F-protein, was developed for immunoprophylaxis against RSV-disease. Following its license in 1998 palivizumab has been implemented in more and more countries with differing reimbursement criteria, which vary over the years [
9,
11,
12,
22,
23]. According to the guidelines of the American Academy of Paediatrics (AAP) until 2014 RSV immunoprophylaxis was administered to preterm infants of gestational age (GA) < 35 GW [
22,
24]. Prospective clinical trials have demonstrated palivizumab efficacy of 45–82% against RSV-related hospitalizations [
9,
13,
14]. Because of its high price cost-effectiveness studies for different subgroups of high-risk infants were conducted, but they did not provide uniform recommendations for prophylaxis according to gestational age [
25,
26]. So, in the following years, in the United States and some EU countries, the reimbursement criteria were limited to the most vulnerable groups: infants born preterm at ≤29 weeks of gestation, infants with BPD, or hemodynamically significant CHD [
23,
24,
27]. After the implementation of the RSV-immunoprophylaxis in Bulgaria, 2010, initially covering only the infants with severe BPD, the reimbursement criteria were gradually extended to all infants with GA < 30 GW up to 1 year of age; those < 2 years of age and requiring treatment for BPD within the previous 6 months, or with hemodynamically significant CHD. From season 2019/2020 onwards palivizumab is also reimbursed for preterm infants of gestational age 30 to < 32 GW and < 6 months at the start of the RSV season.
In preterm infants, especially those with BPD, RSV-disease is significantly more severe, with lower respiratory tract involvement or pneumonia. A bacterial infection is often superimposed [
21,
27‐
29]. For our two most critically affected infants, the severe RSV disease was complicated by ventilator-associated infection (P1 and P2).
If the RSV-disease in such high-risk newborns occurs in the NICU, discharge home is delayed. In our population of preterm babies, this period was between 1 week for milder cases and over 2 months for the infant with severe underlying BPD and critical deterioration. To date, there are no uniform recommendations to start palivizumab during the NICU-stay of high-risk infants [
10]. So, extremely preterm NICU patients born just before or during the RSV season in Bulgaria (December–March) generally do not receive palivizumab before discharge home. Since the hospital costs would increase significantly the practice in our NICU is to administer off-guideline palivizumab only for extremely preterm infants with the highest risk of severe BPD (need for MV and/or high oxygen requirements during the entire first month of life). Thus, the RSV-prophylaxis for such infants starts about a month after birth with 15 mg/kg of palivizumab monthly. Of our 7 RSV-positive NICU patients, palivizumab has been previously been initiated only for P1, the extremely preterm infant with severe BPD. The other 6 patients were without or low oxygen requirements at 1 month of life. So, they received their first palivizumab injection once the index case was detected.
Among our NICU patients, the RSV infection was most critical in the infant with severe BPD, despite ongoing prophylaxis with palivizumab. The morphological immaturity of the lung and the BPD-related changes might have contributed to the severe course of the disease. Fortunately, despite their low gestational age and co-morbidities, none of the infants in our RSV cohort died. It should be noted that three of the extremely preterm NICU patients with severe BPD had already received one or two injections of palivizumab before the beginning of the RSV outbreak, and they did not get infected. Thus, palivizumab might prevent RSV disease, or help such infants to survive and decrease the number of severe cases.
In the last two decades, several studies on RSV outbreaks in NICUs /Special care baby units with a series of 7–15 preterm infants have been published in the literature [
30‐
34]. Once the first RSV case is identified screening all infants in the NICU, isolating the symptomatic and infected infants, and strict infection control procedures are essential to stop the spread. Dizdar, et al. 2004 reported an RSV outbreak with 15 RSV-positive symptomatic preterm infants, 5 of them (~ 30%) died [
30]. During the outbreak reported by Kilani RA (2002) 8 very low gestational age infants were diagnosed with RSV-disease, 4 of them required mechanical ventilation, and one died. At the same time, the 12 term and late preterm infants remained RSV-negative and asymptomatic, probably due to the anti-RSV IgG antibodies that cross the placenta mainly in the last months of pregnancy [
35]. In their study, Halasa, et al. summarized the significant negative effects that the RSV outbreak in the NICU had on healthcare delivery, hospital costs, and patient outcome [
36]. Analyzing RSV-outbreaks in NICUs most authors conclude that standard infection control measures such as isolation and cohorting, strict hand washing, gowns, and gloves are the main tools to prevent or overcome RSV spread. Palivizumab may help to limit RSV-outbreaks in NICUs [
30‐
32,
34,
37‐
39], but its use in such situations remains controversial and continues to be discussed. However, the application of palivizumab in the NICU’s praxis as an additional tool to the routine infection control measures is not uncommon [
10,
37‐
39]. Therefore, the need for, and efficacy of palivizumab prophylaxis during RSV outbreaks in NICUs should further be studied.
Another aspect that should be mentioned in the discussion of the reported outbreak is the prolonged shedding of the RSV by the preterm patients: in most of them, the second PCRs tested RSV-positive one to 3 weeks after the first probes, regardless of the clinical recovery. Such a prolonged RSV shedding by high-risk neonates may last for up to 4 weeks [
10,
30,
32]. This further complicates the control of the NICU outbreaks and requires isolation of the affected infants until discharge, or until negative PCRs are obtained.
Although full-term infants may also be affected by nosocomial RSV infection, the disease is usually mild. Our full-term symptomatic patients required short-term hospitalization or treatment at home, followed by recovery without complications. In healthy term or near-term (34–37 GW) newborn infants, passive immunity provided by transplacental anti-RSV antibodies would help reduce RSV-related hospitalizations in the first months of life. Active immunization of women during pregnancy, for prevention of severe RSV disease in the neonatal period and early infancy, remains a challenge. The suitable vaccination timing – in the second or third trimester, is also under discussion. It should be sufficient to ensure that the mothers develop immunity, transfer transplacental antibodies, and protect the newborn, including those born preterms [
40]. RSV vaccine research and development activities have increased significantly in recent years [
21,
41,
42]. Several RSV vaccine clinical trials from Phase I to Phase III with a variety of vaccine strategies, summarized by Rezaee, et al., are currently underway or were recently completed but to date, there is no licensed RSV vaccine for pregnant women [
43].
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