Efficacy of inactivated trivalent influenza vaccine in rural India: a 3-year cluster-randomised controlled trial

Wayne M Sullender, Karen B Fowler, Vivek Gupta, Anand Krishnan, Debjani Ram Purakayastha, Raghuram Srungaram Vln, Kathryn E Lafond, Siddhartha Saha, Francisco S Palomeque, Paul Gargiullo, Seema Jain, Renu Lal, Marc-Alain Widdowson, Shobha Broor, Wayne M Sullender, Karen B Fowler, Vivek Gupta, Anand Krishnan, Debjani Ram Purakayastha, Raghuram Srungaram Vln, Kathryn E Lafond, Siddhartha Saha, Francisco S Palomeque, Paul Gargiullo, Seema Jain, Renu Lal, Marc-Alain Widdowson, Shobha Broor

Abstract

Background: Paediatric vaccination against influenza can result in indirect protection, by reducing transmission to their unvaccinated contacts. We investigated whether influenza vaccination of children would protect them and their household members in a resource-limited setting.

Methods: We did a cluster-randomised, blinded, controlled study in three villages in India. Clusters were defined as households (ie, dwellings that shared a courtyard), and children aged 6 months to 10 years were eligible for vaccination as and when they became age-eligible throughout the study. Households were randomly assigned (1:1) by a computer-based system to intramuscular trivalent inactivated influenza vaccine (IIV3) or a control of inactivated poliovirus vaccine (IPV) in the beginning of the study; vaccination occurred once a year for 3 years. The primary efficacy outcome was laboratory-confirmed influenza in a vaccinated child with febrile acute respiratory illness, analysed in the modified intention-to-treat population (ie, children who received at least one dose of vaccine, were under surveillance, and had not an influenza infection within 15 days of last vaccine dose). The secondary outcome for indirect effectiveness (surveillance study) was febrile acute respiratory illness in an unvaccinated household member of a vaccine study participant. Data from each year (year 1: November, 2009, to October, 2010; year 2: October, 2010, to October, 2011; and year 3: October, 2011, to May, 2012) were analysed separately. Safety was analysed among all participants who were vaccinated with at least one dose of the vaccine. This trial is registered with ClinicalTrials.gov, number NCT00934245.

Findings: Between Nov 1, 2009, to May 1, 2012, we enrolled 3208 households, of which 1959 had vaccine-eligible children. 1010 households were assigned to IIV3 and 949 households were assigned to IPV. In 3 years, we vaccinated 4345 children (2132 with IIV3 and 2213 with IPV) from 1868 households (968 with IIV3 and 900 with IPV) with 10 813 unvaccinated household contacts. In year 1, influenza virus was detected in 151 (10%) of 1572 IIV3 recipients and 206 (13%) of 1633 of IPV recipients (total IIV3 vaccine efficacy 25·6% [95% CI 6·8-40·6]; p=0·010). In year 2, 105 (6%) of 1705 IIV3 recipients and 182 (10%) of 1814 IPV recipients had influenza (vaccine efficacy 41·0% [24·1-54·1]; p<0·0001). In year 3, 20 (1%) of 1670 IIV3 recipients and 81 (5%) of 1786 IPV recipients had influenza (vaccine efficacy 74·2% [57·8-84·3]; p<0·0001). In year 1, total vaccine efficacy against influenza A(H1N1)pdm09 was 14·5% (-20·4 to 39·3). In year 2, total vaccine efficacy against influenza A(H3N2) was 64·5% (48·5-75·5). Total vaccine efficacy against influenza B was 32·5% (11·3-48·6) in year 1, 4·9% (-38·9 to 34·9) in year 2, and 76·5% (59·4-86·4) in year 3. Indirect vaccine effectiveness was statistically significant only in year 3 (38·1% [7·4-58·6], p=0·0197) when influenza was detected in 39 (1%) of 4323 IIV3-allocated and 60 (1%) of 4121 IPV-allocated household unvaccinated individuals. In the IIV3 group, 225 (12%) of 1632 children in year 1, 375 (22%) of 1718 in year 2, and 209 (12%) of 1673 in year 3 had an adverse reaction (compared with 216 [13%] of 1730, 380 [21%] of 1825, and 235 [13%] of 1796, respectively, in the IPV group). The most common reactions in both groups were fever and tenderness at site. No vaccine-related deaths occurred in either group.

Interpretation: IIV3 provided variable direct and indirect protection against influenza infection. Indirect protection was significant during the year of highest direct protection and should be considered when quantifying the effect of vaccination programmes.

Funding: US Centers for Disease Control and Prevention.

Conflict of interest statement

Declaration of interests

WMS, KBF, VG, AK, DRP, RSVLN, and SB report a grant from the US CDC during the conduct of the study. All other authors declare no competing interests.

Copyright © 2019 The Author(s). Published by Elsevier Ltd. This is an Open Access article under the CC BY-NC-ND 4.0 license. Published by Elsevier Ltd.. All rights reserved.

Figures

Figure 1:. Trial profile
Figure 1:. Trial profile
Randomised childhood vaccination study analysing total protection.
Figure 2:. Trial profile
Figure 2:. Trial profile
Unvaccinated individuals in indirect protection analysis. Number of eligible households enrolled and randomly assigned to each group are shown in figure 1.
Figure 3:. Number of laboratory-confirmed influenza cases…
Figure 3:. Number of laboratory-confirmed influenza cases by month and year, from November, 2009, to April, 2012, among vaccinated children and unvaccinated individuals
Viruses were typed and subtyped by real-time RT-PCR and haemagglutination inhibition. Vertical arrows indicate start dates of vaccination each year. This analysis includes 15 158 participants (4345 vaccinated and 10 813 unvaccinated).

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