key: cord-0821582-5mv15o9t authors: Coleman, Brenda L; Fadel, Shaza A; Drews, Steven J; Hatchette, Todd F; McGeer, Allison J title: Zanamivir versus trivalent split virus influenza vaccine: a pilot randomized trial date: 2015-01-04 journal: Influenza Other Respir Viruses DOI: 10.1111/irv.12301 sha: ca13097c0bc4ca9abed010fa69c56531749da4dd doc_id: 821582 cord_uid: 5mv15o9t BACKGROUND: Healthcare workers may be exposed to people with respiratory viral infections more often than other working adults. Understanding the risk and the effectiveness of different preventive measures is of great importance. OBJECTIVES: To estimate adherence to prophylactic antiviral medication for a full influenza season, to the compare efficacy of antiviral prophylaxis to that of the seasonal influenza vaccine and to identify exposures that increase risk of acute respiratory illnesses (ARI) in healthy adults. METHODS: Participants were randomized 1:2 to receive the 2008–2009 influenza vaccine or daily prophylaxis with 10 mg of zanamivir during the season. Web-based questionnaires collected information on demographics, symptoms, exposures, medication use and side effects. RESULTS: Sixty-four healthy adults were recruited in November 2008. Three of 40 active participants discontinued zanamivir due to side effects; the remaining 37 took >85% of scheduled doses for a median of 121 days. Symptomatic, laboratory-confirmed influenza was detected in one person randomized to zanamivir (2·5%) and 2/20 (10%) who received the vaccine (P = 0·25). Forty-seven participants reported 109 episodes of ARI. Factors associated with an ARI were exposure to a spouse (OR 7·2), child (OR 2·4) or patient (OR 2·0) with symptoms of an ARI in the previous 7 days. CONCLUSIONS: Breakthrough influenza infection occurred in both vaccinated participants and those receiving antiviral prophylaxis. Most adults were willing and able to comply with season-long prophylaxis. Report of recent exposure to family members and patients with an ARI increased the risk of developing an ARI in healthy adults. Respiratory tract infections are one of the most common causes of disease and in humans and for absenteeism in healthcare workers. 1, 2 In Canada, influenza-like illness consultation rates ranged from 15 to 20 per 1000 patients in the 2005-2006 and 2006-2007 influenza seasons, with 7-15% of illness caused by influenza. 3, 4 The primary tool for preventing influenza is annual vaccination. Osterholm et al. 5 report that the efficacy of the trivalent inactivated influenza vaccines in eight randomized controlled trials of adults 18-65 years of age was 59%. Neuraminidase inhibitors may also be effective in preventing influenza, with estimated efficacy of 31-83% in placebo-controlled trials. [6] [7] [8] Healthcare workers providing direct patient care may be at increased risk of developing influenza compared to other healthy adults 9,10 and may transmit the disease to vulnerable patients making them a priority group for influenza vaccines and, in the event of a pandemic, for antiviral medication. 11, 12 During the 2008-2009 influenza season, this pilot study determined the adherence to antiviral medication for an influenza season, the relative efficacy of antiviral prophylaxis with zanamivir and seasonal influenza vaccine against laboratory-confirmed influenza infection, and determined risk factors for acute respiratory illnesses (ARI) among healthy adults. bed academic health centre in Toronto, Canada. Participants were eligible if they were 18-69 years old, were available for follow-up during the study period and provided written informed consent. Individuals were excluded when they had any health or medical conditions that contraindicated influenza vaccine or zanamivir administration, had received the 2008-2009 influenza vaccine prior to the study start date, were pregnant or planning to be pregnant or were breastfeeding, had received immunoglobulin therapy within 6 months of study entry, were participating a study of any investigational drug during the study period or had an immunocompromising condition or therapy. Women of childbearing potential in the prophylaxis arm were required to have negative pregnancy tests prior to receiving each prescription for zanamivir. A non-blinded randomized controlled pilot study with participants randomized in a two to one ratio of antiviral prophylaxis to influenza vaccine. A random number table was used to generate assignments, in blocks of 4 or 6. A staff member not affiliated with the study generated the list and provided the assignment to study nurses following consent. Participants in the vaccine group received one intramuscular injection of Fluviral â (GlaxoSmithKline, Mississauga, ON, Canada) 2008-2009 trivalent inactivated split virion influenza vaccine containing influenza A/Brisbane/59/2007 (H1N1), A/Uruguay/716/2007 (H3N2) and B/Florida/4/ 2006. Participants in the antiviral prophylaxis arm were prescribed one 10 mg dose of zanamivir (Relenza â ; Glaxo-SmithKline) per day for the influenza season. Participants who experienced side effects and discontinued antiviral prophylaxis were given either Fluviral â or Vaxigrip â (Sanofi Pasteur, Toronto, ON, Canada) but remained in the antiviral arm of the study for analysis. The influenza season was defined, a priori, as starting when the proportion of all specimens tested for influenza in the province was >3% positive for 1 week or >2Á5% for two consecutive weeks and ending when the proportion was less than 2% positive for two consecutive weeks. These definitions were established to keep the risk of exposure to influenza low for participants on prophylactic antiviral medication. This study was approved by Health Canada and Mount Sinai Hospital's Research Ethics Board, was registered with ClinicalTrials.gov (NCT00784784) and was conducted according to Good Clinical Practice guidelines. Data collection started on the day of enrolment and continued until the end of the seasonal influenza season. Demographic, risk factor and health status information was collected by questionnaire at enrolment, 4 or 5 face-to-face interviews, weekly web-based diaries and daily illness ques-tionnaires for all ARI. As shown in Figure 1 , blood samples were collected four times: at baseline (prior to vaccination for the vaccine group), on day 14 (+7) after vaccination (vaccine group) or at the start of influenza season (antiviral prophylaxis group), on day 24-38 of the influenza season (mid-season) and 2-3 weeks after the end of the influenza season. Sera were extracted and stored, frozen at À70°C for later testing. Active surveillance for acute respiratory illness occurred using web-based weekly diaries of symptoms throughout the influenza season. Participants with any acute respiratory symptom (runny or stuffy nose, sneezing, sore or scratchy throat, hoarseness, cough) or an unexplained fever were asked to have a nasopharyngeal (NP) swab collected by study nurses and to self-collected a mid-turbinate nasal swab. 13 Adherence to prophylaxis was assessed using weekly diaries and medication counts at each of four study visits. Laboratory-confirmed influenza infection was defined as symptomatic infection, confirmed by NAAT testing of either NP or mid-turbinate nasal swabs. Seroconversion after vaccination was defined as post-vaccination titre ≥1:40 if the pre-vaccination titre was <1:10 or a fourfold or greater increase in HAI titres 15 . Acute respiratory illness was defined as a recent onset of at least two symptoms of which at least one was respiratory, among rhinorrhea/nasal congestion, sore throat, cough, headache or feverishness. 16 All participants remained in the arm to which they were randomized for modified intention-to-treat analyses, with people who withdrew prior to the influenza season excluded. 17 Conditional logistic regression, matched on week of illness onset, was used to account for time-varying risk factors such as exposure to ill family or patients. Robust variance estimates were used to adjust for correlation due to several ARI reports from the same participants. All weekly reports for people without signs or symptoms of a respiratory illness were used as controls. Weeks without a reported illness were not eligible for inclusion in the analyses. Assumptions of logistic regression modelling were checked using scatter plots of residuals against each predictor. All statistical analyses were performed using STATA â v11 (Stata-Corp, College Station, TX, USA). 18 A P value <0Á05 was considered statistically significant and all tests were twosided. A sensitivity analysis of the conditional logistic regression model was conducted in which people who discontinued antiviral prophylaxis were re-classified as being in the vaccine arm at 14-days postvaccination. As negligible differences in other covariate regression co-efficient estimates were detected (≤0Á01), these results are not presented. Of the 64 participants recruited into the study, 42 were randomized to the antiviral arm and 22 to the vaccine arm. As shown in Table 1 , baseline characteristics were similar between the two groups. The median age of the participants was 41 years, 69% were female and 21% had a chronic disease. All but three individuals (95%) worked at a health care facility and 41% provided direct patient care. Two individuals from the vaccine group and two from the prophylaxis group withdrew from the study prior to the start of the influenza season and are excluded from further analyses. The with 35/40 starting during the first week and the other 5 starting during the second week of January. Three individuals discontinued prophylaxis due to side effects: one in week 1 with nausea, vomiting and headache and two people in week 4, one with joint pain and one with increased nasal congestion. All three were vaccinated upon discontinuation. After 13 weeks (April 6th), the expected duration of the season and study, participants in the antiviral group were given the options of discontinuing prophylaxis and being vaccinated (n = 1, who was vaccinated April 7th but restarted prophylaxis April 29th due to the increased local pandemic influenza activity), discontinuing prophylaxis without vaccination (n = 4), continuing prophylaxis for an additional 4 weeks/the next planned study visit (n = 3) or continuing for an additional 5Á5 weeks/end of study (n = 29). Medication was taken for a median of 121 days (range 6-130) with very good adherence. According to selfreports on weekly diaries, 35/40 participants took >90% of prescribed doses while using prophylaxis. Adherence was higher at the start of prophylaxis with an average of 94% of doses taken per week until March 16th but dropped to 91% from March 17th to May 11th (see Figure 2 ). Baseline levels of seroprotection to the strains included in the 2008-2009 seasonal influenza vaccine were similar in the two groups. As shown in Table 2 Four cases (6Á2 per 100 person-seasons) of influenza infection were detected. Three cases were symptomatic and detected by NAAT while the fourth was detected by serology alone. Two cases occurred in participants from the vaccine arm: both tested positive to influenza A (H1N1, seasonal strain) but neither had a significant increase in HAI titres to tested strains. One participant randomized to antiviral prophylaxis, who reported taking 93% of prescribed doses, tested positive for influenza B by NAAT on 18 February 2009, but had no change in HAI titres. A second person taking antiviral prophylaxis did not report symptoms of an acute respiratory illness on questionnaires nor when questioned during the final study visit, but had a 16-fold increase in antibody titres to A/California/07/2009 (H1N1). This individual reported 100% compliance with the prophylaxis, stopped taking medication May 25th and had their final study visit (and blood draw) on July 15th. The period between discontinuing medication and the blood draw was during the peak of the first wave of the pandemic in Ontario 19 making it possible that the participant was exposed after discontinuing zanamivir prophylaxis. This case was not used in the analyses for effectiveness. As shown in Table 3 , 109 episodes of acute respiratory illness were by reported by 47 participants, with 0-9 episodes per participant. There was no difference in the number of episodes for people receiving prophylactic antiviral medication compared to those receiving seasonal influenza vaccine before (RR 0Á78 [CI 95% 0Á51, 1Á18] P = 0Á25) or following adjustment for week of illness (as shown in Table 4 ). Results of unadjusted conditional logistic regression analysis matched on week of illness (Table 4 ), determined that odds of reporting an illness were higher for older participants and those who provided direct patient care. The odds of reporting an acute respiratory illness also increased with recent exposure (past 7 days) to a patient, co-worker, spouse or child who had symptoms of a respiratory illness. Using a multivariable model to adjust for the impact of other factors, the odds of reporting an acute respiratory illness doubled following recent exposure to a patient or child who had symptoms but were 7 times higher following exposure to a spouse with symptoms of an acute respiratory illness. Participants in this randomized controlled study were largely able and willing to use antiviral prophylaxis against influenza for an entire influenza season with 90% of participants taking at least 90% of scheduled doses for up to 18Á5 weeks of prophylaxis. In this study, 7Á5% of people discontinued the antiviral medication due to side effects. This is similar to an unblinded randomized controlled trial of adults taking oseltamivir or given influenza vaccine for the prevention of influenza infection. In that study, 10% of participants discontinued prophylaxis due to side effects over a full influenza season. 21 In comparison, in three blinded, randomized, placebo-controlled trials only 1-2% of participants in each study arm discontinued zanamivir, oseltamivir or placebo prophylaxis due to side effects experienced during treatment. [6] [7] [8] In adults, seasonal influenza vaccines prevent about 59% of laboratory-confirmed influenza illnesses compared with no vaccine. 5 In randomized, placebo-controlled studies of antiviral prophylaxis, the protective efficacy of zanamivir and oseltamivir against laboratory-confirmed influenza ranged from 31 to 83% in adults and adolescents in studies that ranged in duration from 28 days to 6 weeks. [6] [7] [8] Studies that directly compare vaccination and antiviral prophylaxis, including the current study and another pilot study Seroprotection defined as HAI titres ≥1:40. Three participants in the antiviral arm were vaccinated between medication start and end-of-season (included); see Figure 1 for participants per blood draw. conducted in our facility in the 2007-2008 season, 21 highlight the fact that neither option is perfect, but that both provide greater protection than no intervention. Antiviral prophylaxis may provide protection for those at higher risk of contracting, transmitting, and/or suffering severe consequences of infection caused by influenza strains not included in the seasonal vaccines (e.g. during a pandemic or a year with significant mismatch between the vaccine and circulating strains). In this study, the direct provision of patient care and exposure to a patient with symptoms of an acute respiratory infection in the previous week were both associated with higher odds of illness. This is consistent with other studies reporting that people working in healthcare institutions are at higher risk of acute respiratory illness than people working in other professions. 9,10, 22 Williams et al. 10 report that people working in acute care hospitals in Germany had higher odds of reporting ARI during the 2006-2007 influenza season than people working for other employers after adjusting for age, sex and smoking status. In the current study, the risk of an acute respiratory illness was also higher for participants who were exposed to their spouse or child who was ill during the previous week. Exposure to an ill family member was reported as a risk factor for influenza for healthcare workers during the 2009 pandemic 23 , while living with 10, 22, 23 or being otherwise exposed to children 9 was a risk for respiratory illnesses in several other studies. A limitation of this pilot study was the inability to blind participants to their treatment which may have biased both the reporting of respiratory symptoms and side effects of the antiviral medication. Secondly, participants provided exposure information after they reported ARI, which likely biased their recall of exposure to people who had symptoms of an acute respiratory illness. Also, since the 2009 pandemic strain of influenza A started to circulate towards the end of the planned study period, it likely increased long-term adherence to the prophylactic antiviral medication. In a previous study, it was found that adherence started to wane towards the end of the influenza season. 21 As most of the study participants worked in an acute care facility and had regular internet access, it is likely that our study population was of a higher socioeconomic status than the general population which may limit the generalizability of the findings. Strengths of the study are that it was randomized and an overwhelming majority of participants consistently completed weekly diaries reducing recall bias of symptoms and exposures. Neuraminidase inhibitors are effective in preventing influenza infections and adults can comply with a schedule of once daily doses for a full season, with a low percentage having to discontinue because of side effects. Exposure to a spouse, child or patient with symptoms of an acute respiratory illness within the past week are risk factors for respiratory illness in healthy adults exemplifying the need to follow guidelines to prevent the spread of respiratory infections, both at home and in the workplace. 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Immunization of health-care personnel Public Health Agency of Canada. The Canadian pandemic influenza plan for the health sector Self-collected mid-turbinate swabs for the detection of respiratory viruses in adults with acute respiratory illnesses World Health Organization, Global Influenza Surveillance Network. Manual for the laboratory diagnosis and virological surveillance of influenza Guidance for industry: clinical data needed to support the licensure of seasonal inactivated influenza vaccines Rockville, MD: US Department of Health and Human Services Longitudinal study of influenza molecular viral shedding in Hutterite communities Intention-to-treat concept: a review StataCorp. Stata/SE for Windows. 11.2 ed. College Public Health Agency of Canada. FluWatch, 2008-09. season National Advisory Committee on Immunization. Statement on influenza vaccination for the 2008-2009 season Respiratory illnesses in Canadian health care workers: a pilot study of influenza vaccine and oseltamivir prophylaxis during the 2007/ 2008 influenza season Pandemic (H1N1) 2009 risk for frontline health care workers Risk factors for influenza among health care workers during 2009 pandemic This work was funded, in part, by an investigator-initiated research to AJM with GlaxoSmithKline Inc. (http:// www.gsk.ca). The funders had no role in study design, data collection and analysis, decision to publish or preparation of the manuscript.