Anti-influenza hyperimmune intravenous immunoglobulin for adults with influenza A or B infection (FLU-IVIG): a double-blind, randomised, placebo-controlled trial

Richard T Davey Jr, Eduardo Fernández-Cruz, Norman Markowitz, Sarah Pett, Abdel G Babiker, Deborah Wentworth, Surender Khurana, Nicole Engen, Fred Gordin, Mamta K Jain, Virginia Kan, Mark N Polizzotto, Paul Riska, Kiat Ruxrungtham, Zelalem Temesgen, Jens Lundgren, John H Beigel, H Clifford Lane, James D Neaton, INSIGHT FLU-IVIG Study Group, Richard T Davey, Eduardo Fernández-Cruz, Norman Markowitz, Sarah Pett, Abdel G Babiker, Deborah Wentworth, Surender Khurana, Nicole Engen, Fred Gordin, Mamta K Jain, Virginia Kan, Mark N Polizzotto, Paul Riska, Kiat Ruxrungtham, Zelalem Temesgen, Jens Lundgren, John H Beigel, H Clifford Lane, James D Neaton, Jessica Butts, Eileen Denning, Alain DuChene, Eric Krum, Merrie Harrison, Sue Meger, Ross Peterson, Kien Quan, Megan Shaughnessy, Greg Thompson, David Vock, Julia Metcalf, Robin Dewar, Tauseef Rehman, Ven Natarajan, Rose McConnell, Emily Flowers, Kenny Smith, Marie Hoover, Elizabeth M Coyle, David Munroe, Bitten Aagaard, Mary Pearson, Adam Cursley, Helen Webb, Fleur Hudson, Charlotte Russell, Aminata Sy, Cara Purvis, Brooke Jackson, Yolanda Collaco-Moraes, Dianne Carey, Rosemary Robson, Adriana Sánchez, Elizabeth Finley, Donna Conwell, Marcelo H Losso, Luciana Gambardella, Cecilia Abela, Paco Lopez, Helena Alonso, Giota Touloumi, Vicky Gioukari, Olga Anagnostou, Anchalee Avihingsanon, Kanitta Pussadee, Sasiwimol Ubolyam, Bola Omotosho, Clemencia Solórzano, Tianna Petersen, Kranthi Vysyaraju, Stacey A Rizza, Jennifer A Whitaker, Raquel Nahra, John Baxter, Patricia Coburn, Edward M Gardner, James A Scott, Leslie Faber, Erica Pastor, Linda Makohon, Rodger A MacArthur, L Monique Hillman, Marti J Farrough, Hari M Polenakovik, Linda A Clark, Roberto J Colon, Ken M Kunisaki, Miranda DeConcini, Susan A Johnson, Cameron R Wolfe, Laura Mkumba, June Y Carbonneau, Alison Morris, Meghan E Fitzpatrick, Cathy J Kessinger, Robert A Salata, Karen A Arters, Catherine M Tasi, Ralph J Panos, Laura A Lach, Marshall J Glesby, Kirsis A Ham, Valery G Hughes, Robert T Schooley, Daniel Crouch, Leticia Muttera, Richard M Novak, Susan C Bleasdale, Ariel E Zuckerman, Weerawat Manosuthi, Supeda Thaonyen, Thaniya Chiewcharn, Gompol Suwanpimolkul, Sivaporn Gatechumpol, Sirikunya Bunpasang, Brian J Angus, Monique Anderson, Marcus Morgan, Jane Minton, Maria N Gkamaletsou, Joe Hambleton, David A Price, Martin J Llewelyn, Jonathan Sweetman, Javier Carbone, Jose R Arribas, Rocio Montejano, Jose L Lobo Beristain, Iñaki Z Martinez, Jose Barberan, Paola Hernandez, Dominic E Dwyer, Jen Kok, Alvaro Borges, Christian T Brandt, Lene S Knudsen, Nikolaos Sypsas, Costas Constantinou, Antonios Markogiannakis, Spyros Zakynthinos, Paraskevi Katsaounou, Ioannis Kalomenidis, Analia Mykietiuk, Maria F Alzogaray, Mora Obed, Laura M Macias, Juan Ebensrtejin, Patricia Burgoa, Esteban Nannini, Matias Lahitte, Santiago Perez-Patrigeon, José Arturo Martínez-Orozco, Juan Pablo Ramírez-Hinojosa, Richard T Davey Jr, Eduardo Fernández-Cruz, Norman Markowitz, Sarah Pett, Abdel G Babiker, Deborah Wentworth, Surender Khurana, Nicole Engen, Fred Gordin, Mamta K Jain, Virginia Kan, Mark N Polizzotto, Paul Riska, Kiat Ruxrungtham, Zelalem Temesgen, Jens Lundgren, John H Beigel, H Clifford Lane, James D Neaton, INSIGHT FLU-IVIG Study Group, Richard T Davey, Eduardo Fernández-Cruz, Norman Markowitz, Sarah Pett, Abdel G Babiker, Deborah Wentworth, Surender Khurana, Nicole Engen, Fred Gordin, Mamta K Jain, Virginia Kan, Mark N Polizzotto, Paul Riska, Kiat Ruxrungtham, Zelalem Temesgen, Jens Lundgren, John H Beigel, H Clifford Lane, James D Neaton, Jessica Butts, Eileen Denning, Alain DuChene, Eric Krum, Merrie Harrison, Sue Meger, Ross Peterson, Kien Quan, Megan Shaughnessy, Greg Thompson, David Vock, Julia Metcalf, Robin Dewar, Tauseef Rehman, Ven Natarajan, Rose McConnell, Emily Flowers, Kenny Smith, Marie Hoover, Elizabeth M Coyle, David Munroe, Bitten Aagaard, Mary Pearson, Adam Cursley, Helen Webb, Fleur Hudson, Charlotte Russell, Aminata Sy, Cara Purvis, Brooke Jackson, Yolanda Collaco-Moraes, Dianne Carey, Rosemary Robson, Adriana Sánchez, Elizabeth Finley, Donna Conwell, Marcelo H Losso, Luciana Gambardella, Cecilia Abela, Paco Lopez, Helena Alonso, Giota Touloumi, Vicky Gioukari, Olga Anagnostou, Anchalee Avihingsanon, Kanitta Pussadee, Sasiwimol Ubolyam, Bola Omotosho, Clemencia Solórzano, Tianna Petersen, Kranthi Vysyaraju, Stacey A Rizza, Jennifer A Whitaker, Raquel Nahra, John Baxter, Patricia Coburn, Edward M Gardner, James A Scott, Leslie Faber, Erica Pastor, Linda Makohon, Rodger A MacArthur, L Monique Hillman, Marti J Farrough, Hari M Polenakovik, Linda A Clark, Roberto J Colon, Ken M Kunisaki, Miranda DeConcini, Susan A Johnson, Cameron R Wolfe, Laura Mkumba, June Y Carbonneau, Alison Morris, Meghan E Fitzpatrick, Cathy J Kessinger, Robert A Salata, Karen A Arters, Catherine M Tasi, Ralph J Panos, Laura A Lach, Marshall J Glesby, Kirsis A Ham, Valery G Hughes, Robert T Schooley, Daniel Crouch, Leticia Muttera, Richard M Novak, Susan C Bleasdale, Ariel E Zuckerman, Weerawat Manosuthi, Supeda Thaonyen, Thaniya Chiewcharn, Gompol Suwanpimolkul, Sivaporn Gatechumpol, Sirikunya Bunpasang, Brian J Angus, Monique Anderson, Marcus Morgan, Jane Minton, Maria N Gkamaletsou, Joe Hambleton, David A Price, Martin J Llewelyn, Jonathan Sweetman, Javier Carbone, Jose R Arribas, Rocio Montejano, Jose L Lobo Beristain, Iñaki Z Martinez, Jose Barberan, Paola Hernandez, Dominic E Dwyer, Jen Kok, Alvaro Borges, Christian T Brandt, Lene S Knudsen, Nikolaos Sypsas, Costas Constantinou, Antonios Markogiannakis, Spyros Zakynthinos, Paraskevi Katsaounou, Ioannis Kalomenidis, Analia Mykietiuk, Maria F Alzogaray, Mora Obed, Laura M Macias, Juan Ebensrtejin, Patricia Burgoa, Esteban Nannini, Matias Lahitte, Santiago Perez-Patrigeon, José Arturo Martínez-Orozco, Juan Pablo Ramírez-Hinojosa

Abstract

Background: Since the 1918 influenza pandemic, non-randomised studies and small clinical trials have suggested that convalescent plasma or anti-influenza hyperimmune intravenous immunoglobulin (hIVIG) might have clinical benefit for patients with influenza infection, but definitive data do not exist. We aimed to evaluate the safety and efficacy of hIVIG in a randomised controlled trial.

Methods: This randomised, double-blind, placebo-controlled trial was planned for 45 hospitals in Argentina, Australia, Denmark, Greece, Mexico, Spain, Thailand, UK, and the USA over five influenza seasons from 2013-14 to 2017-18. Adults (≥18 years of age) were admitted for hospital treatment with laboratory-confirmed influenza A or B infection and were randomly assigned (1:1) to receive standard care plus either a single 500-mL infusion of high-titre hIVIG (0·25 g/kg bodyweight, 24·75 g maximum; hIVIG group) or saline placebo (placebo group). Eligible patients had a National Early Warning score of 2 points or greater at the time of screening and their symptoms began no more than 7 days before randomisation. Pregnant and breastfeeding women were excluded, as well as any patients for whom the treatment would present a health risk. Separate randomisation schedules were generated for each participating clinical site using permuted block randomisation. Treatment assignments were obtained using a web-based application by the site pharmacist who then masked the solution for infusion. Patients and investigators were masked to study treatment. The primary endpoint was a six-category ordinal outcome of clinical status at day 7, ranging in severity from death to resumption of normal activities after discharge. The choice of day 7 was based on haemagglutination inhibition titres from a pilot study. It was analysed with a proportional odds model, using all six categories to estimate a common odds ratio (OR). An OR greater than 1 indicated that, for a given category, patients in the hIVIG group were more likely to be in a better category than those in the placebo group. Prespecified primary analyses for safety and efficacy were based on patients who received an infusion and for whom eligibility could be confirmed. This trial is registered with ClinicalTrials.gov, NCT02287467.

Findings: 313 patients were enrolled in 34 sites between Dec 11, 2014, and May 28, 2018. We also used data from 16 patients enrolled at seven of the 34 sites during the pilot study between Jan 15, 2014, and April 10, 2014. 168 patients were randomly assigned to the hIVIG group and 161 to the placebo group. 21 patients were excluded (12 from the hIVIG group and 9 from the placebo group) because they did not receive an infusion or their eligibility could not be confirmed. Thus, 308 were included in the primary analysis. hIVIG treatment produced a robust rise in haemagglutination inhibition titres against influenza A and smaller rises in influenza B titres. Based on the proportional odds model, the OR on day 7 was 1·25 (95% CI 0·79-1·97; p=0·33). In subgroup analyses for the primary outcome, the OR in patients with influenza A was 0·94 (0·55-1·59) and was 3·19 (1·21-8·42) for those with influenza B (interaction p=0·023). Through 28 days of follow-up, 47 (30%) of 156 patients in the hIVIG group and in 45 (30%) of 152 patients in the placebo group had the composite safety outcome of death, a serious adverse event, or a grade 3 or 4 adverse event (hazard ratio [HR] 1·06, 95% CI 0·70-1·60; p=0·79). Six (4%) patients in the hIVIG group and five (3%) in the placebo group died, but these deaths were not necessarily related to treatment.

Interpretation: When administered alongside standard care (most commonly oseltamivir), hIVIG was not superior to placebo for adults hospitalised with influenza infection. By contrast with our prespecified subgroup hypothesis that hIVIG would result in more favourable responses in patients with influenza A than B, we found the opposite effect. The clinical benefit of hIVIG for patients with influenza B is supported by antibody affinity analyses, but confirmation is warranted.

Funding: NIAID and NIH. Partial support was provided by the Medical Research Council (MRC_UU_12023/23) and the Danish National Research Foundation.

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
Figure 1
FLU-IVIG trial profile hIVIG=hyperimmune intravenous immunoglobulin.
Figure 2
Figure 2
Proportional distribution of primary endpoint categories at day 7 of follow-up for patients infected with influenza A and B (A) Proportions have been calculated from day-7 data for 111 patients in the hIVIG group and 110 in the placebo group. The OR estimate includes imputed data for three additional patients in the hIVIG group (n=114); these patients were discharged before day 7 and the imputation was on whether normal activities had been resumed. (B) Proportions have been calculated from day-7 data for 41 patients in the hIVIG and in the 42 placebo group. The OR estimate includes imputed data for one additional patient in the hIVIG group (n=42); this patient was discharged before day 7 and the imputation was on whether normal activities had been resumed. hIVIG=hyperimmune intravenous immunoglobulin. ICU=intensive care unit. OR=odds ratio.
Figure 3
Figure 3
Haemagglutination inhibition titres by reference virus and treatment group Patients infected with influenza A(H1N1) with (A) A/California/07/2009 or (B) A/Michigan/45/2015 used as the reference virus for analysis. Patients infected with influenza A(H3N2) with (C) A/Hong Kong/4801/2014 or (D) A/Switzerland/2013/50/2012 used as the reference virus for analysis. Patients infected with influenza B with (E) B/Brisbane/60/2008 or (F) B/Phuket/3073/2013 used as the reference virus for analysis. hIVIG=hyperimmune intravenous immunoglobulin.
Figure 4
Figure 4
Antibody affinity of hIVIG to properly folded haemagglutinin of seasonal influenza vaccine strains in SPR analysis Sequential SPR analysis of human hIVIG was done against properly folded homologous haemagglutinin from the H1N1pdm09, H3N2, and B influenza vaccine strains for each lot of hIVIG used. 50-fold, 100-fold, and 200-fold dilutions of individual hIVIG lots were evaluated. Antibody off-rate constants that describe the fraction of antibody-antigen complexes decaying per second were determined directly from the hIVIG interaction with each of the three haemagglutinin proteins using SPR in the dissociation phase (appendix p 7). Slower dissociation kinetics (off-rate) of antigen-antibody complex means higher antibody affinity. hIVIG=hyperimmune intravenous immunoglobulin. SPR=surface plasmon resonance.
Figure 5
Figure 5
Change in overall and serotype-specific nasopharyngeal viral load Analyses only include participants with detectable viral load at baseline and are adjusted for baseline viral load and geographical region. The overall analysis was also adjusted for influenza subtype. *Excludes five participants with unknown serotype. †Excludes three participants with unknown lineage.

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