Your search keyword '"Viboud, C"' showing total 16 results

1. Synergistic interventions to control COVID-19:Mass testing and isolation mitigates reliance on distancing

Author

Howerton, E., Ferrari, M.J., Bjørnstad, O.N., Bogich, T.L., Borchering, R.K., Jewell, C.P., Nichols, J.D., Probert, W.J.M., Runge, M.C., Tildesley, M.J., Viboud, C., Shea, K., Howerton, E., Ferrari, M.J., Bjørnstad, O.N., Bogich, T.L., Borchering, R.K., Jewell, C.P., Nichols, J.D., Probert, W.J.M., Runge, M.C., Tildesley, M.J., Viboud, C., and Shea, K.

Abstract

Stay-at-home orders and shutdowns of non-essential businesses are powerful, but socially costly, tools to control the pandemic spread of SARS-CoV-2. Mass testing strategies, which rely on widely administered frequent and rapid diagnostics to identify and isolate infected individuals, could be a potentially less disruptive management strategy, particularly where vaccine access is limited. In this paper, we assess the extent to which mass testing and isolation strategies can reduce reliance on socially costly non-pharmaceutical interventions, such as distancing and shutdowns. We develop a multi-compartmental model of SARS-CoV-2 transmission incorporating both preventative non-pharmaceutical interventions (NPIs) and testing and isolation to evaluate their combined effect on public health outcomes. Our model is designed to be a policy-guiding tool that captures important realities of the testing system, including constraints on test administration and non-random testing allocation. We show how strategic changes in the characteristics of the testing system, including test administration, test delays, and test sensitivity, can reduce reliance on preventative NPIs without compromising public health outcomes in the future. The lowest NPI levels are possible only when many tests are administered and test delays are short, given limited immunity in the population. Reducing reliance on NPIs is highly dependent on the ability of a testing program to identify and isolate unreported, asymptomatic infections. Changes in NPIs, including the intensity of lockdowns and stay at home orders, should be coordinated with increases in testing to ensure epidemic control; otherwise small additional lifting of these NPIs can lead to dramatic increases in infections, hospitalizations and deaths. Importantly, our results can be used to guide ramp-up of testing capacity in outbreak settings, allow for the flexible design of combined interventions based on social context, and inform future cost-b

Published

2021

2. Strategic testing approaches for targeted disease monitoring can be used to inform pandemic decision-making

Author

Nichols, J.D., Bogich, T.L., Howerton, E., Bjørnstad, O.N., Borchering, R.K., Ferrari, M., Haran, M., Jewell, C., Pepin, K.M., Probert, W.J.M., Pulliam, J.R.C., Runge, M.C., Tildesley, M., Viboud, C., Shea, K., Nichols, J.D., Bogich, T.L., Howerton, E., Bjørnstad, O.N., Borchering, R.K., Ferrari, M., Haran, M., Jewell, C., Pepin, K.M., Probert, W.J.M., Pulliam, J.R.C., Runge, M.C., Tildesley, M., Viboud, C., and Shea, K.

Abstract

More than 1.6 million Servere Acute Respiratory Syndrome Cronovirus 2(SARS-COV-2)tests were administered daily in the United States at the peak of the epidemic, with a significant focus on individual treatment. Here, we show that objective-driven, strategic sampling designs and analyses can maximize information gain at the population level, which is necessary to increase situational awareness and predict, prepare for, and respond to a pandemic, while also continuing to inform individual treatment. By focusing on specific objectives such as individual treatment or disease prediction and control (e.g., via the collection of population- level statistics to inform lockdown measures or vaccine rollout) and drawing from the literature on capture-recapture methods to deal with nonrandom sampling and testing errors, we illustrate how public health objectives can be achieved even with limited test availability when testing programs are designed a priori to meet those objectives. © 2021 Public Library of Science. All rights reserved.

Published

2021

3. Using Phenomenological Models to Characterize Transmissibility and Forecast Patterns and Final Burden of Zika Epidemics.

Author

Universidad EAFIT. Departamento de Ciencias, Lógica y Computación, Chowell G, Hincapie-Palacio D, Ospina J, Pell B, Tariq A, Dahal S, Moghadas S, Smirnova A, Simonsen L, Viboud C, Universidad EAFIT. Departamento de Ciencias, Lógica y Computación, Chowell G, Hincapie-Palacio D, Ospina J, Pell B, Tariq A, Dahal S, Moghadas S, Smirnova A, Simonsen L, and Viboud C

Abstract

BACKGROUND: The World Health Organization declared the ongoing Zika virus (ZIKV) epidemic in the Americas a Public Health Emergency of International Concern on February 1, 2016. ZIKV disease in humans is characterized by a "dengue-like" syndrome including febrile illness and rash. However, ZIKV infection in early pregnancy has been associated with severe birth defects, including microcephaly and other developmental issues. Mechanistic models of disease transmission can be used to forecast trajectories and likely disease burden but are currently hampered by substantial uncertainty on the epidemiology of the disease (e.g., the role of asymptomatic transmission, generation interval, incubation period, and key drivers). When insight is limited, phenomenological models provide a starting point for estimation of key transmission parameters, such as the reproduction number, and forecasts of epidemic impact. METHODS: We obtained daily counts of suspected Zika cases by date of symptoms onset from the Secretary of Health of Antioquia, Colombia during January-April 2016. We calibrated the generalized Richards model, a phenomenological model that accommodates a variety of early exponential and sub-exponential growth kinetics, against the early epidemic trajectory and generated predictions of epidemic size. The reproduction number was estimated by applying the renewal equation to incident cases simulated from the fitted generalized-growth model and assuming gamma or exponentially-distributed generation intervals derived from the literature. We estimated the reproduction number for an increasing duration of the epidemic growth phase. RESULTS: The reproduction number rapidly declined from 10.3 (95% CI: 8.3, 12.4) in the first disease generation to 2.2 (95% CI: 1.9, 2.8) in the second disease generation, assuming a gamma-distributed generation interval with the mean of 14 days and standard deviation of 2 days. The generalized-Richards model outperformed the logistic growth model an

Published

2021

4. Synergistic interventions to control COVID-19:Mass testing and isolation mitigates reliance on distancing

Author

Howerton, E., Ferrari, M.J., Bjørnstad, O.N., Bogich, T.L., Borchering, R.K., Jewell, C.P., Nichols, J.D., Probert, W.J.M., Runge, M.C., Tildesley, M.J., Viboud, C., Shea, K., Howerton, E., Ferrari, M.J., Bjørnstad, O.N., Bogich, T.L., Borchering, R.K., Jewell, C.P., Nichols, J.D., Probert, W.J.M., Runge, M.C., Tildesley, M.J., Viboud, C., and Shea, K.

Abstract

Stay-at-home orders and shutdowns of non-essential businesses are powerful, but socially costly, tools to control the pandemic spread of SARS-CoV-2. Mass testing strategies, which rely on widely administered frequent and rapid diagnostics to identify and isolate infected individuals, could be a potentially less disruptive management strategy, particularly where vaccine access is limited. In this paper, we assess the extent to which mass testing and isolation strategies can reduce reliance on socially costly non-pharmaceutical interventions, such as distancing and shutdowns. We develop a multi-compartmental model of SARS-CoV-2 transmission incorporating both preventative non-pharmaceutical interventions (NPIs) and testing and isolation to evaluate their combined effect on public health outcomes. Our model is designed to be a policy-guiding tool that captures important realities of the testing system, including constraints on test administration and non-random testing allocation. We show how strategic changes in the characteristics of the testing system, including test administration, test delays, and test sensitivity, can reduce reliance on preventative NPIs without compromising public health outcomes in the future. The lowest NPI levels are possible only when many tests are administered and test delays are short, given limited immunity in the population. Reducing reliance on NPIs is highly dependent on the ability of a testing program to identify and isolate unreported, asymptomatic infections. Changes in NPIs, including the intensity of lockdowns and stay at home orders, should be coordinated with increases in testing to ensure epidemic control; otherwise small additional lifting of these NPIs can lead to dramatic increases in infections, hospitalizations and deaths. Importantly, our results can be used to guide ramp-up of testing capacity in outbreak settings, allow for the flexible design of combined interventions based on social context, and inform future cost-b

Published

2021

5. Coordinating the real-time use of global influenza activity data for better public health planning

Author

Biggerstaff, M, Dahlgren, FS, Fitzner, J, George, D, Hammond, A, Hall, I, Haw, D, Imai, N, Johansson, MA, Kramer, S, McCaw, JM, Moss, R, Pebody, R, Read, JM, Reed, C, Reich, NG, Riley, S, Vandemaele, K, Viboud, C, Wu, JT, Biggerstaff, M, Dahlgren, FS, Fitzner, J, George, D, Hammond, A, Hall, I, Haw, D, Imai, N, Johansson, MA, Kramer, S, McCaw, JM, Moss, R, Pebody, R, Read, JM, Reed, C, Reich, NG, Riley, S, Vandemaele, K, Viboud, C, and Wu, JT

Abstract

Health planners from global to local levels must anticipate year-to-year and week-to-week variation in seasonal influenza activity when planning for and responding to epidemics to mitigate their impact. To help with this, countries routinely collect incidence of mild and severe respiratory illness and virologic data on circulating subtypes and use these data for situational awareness, burden of disease estimates and severity assessments. Advanced analytics and modelling are increasingly used to aid planning and response activities by describing key features of influenza activity for a given location and generating forecasts that can be translated to useful actions such as enhanced risk communications, and informing clinical supply chains. Here, we describe the formation of the Influenza Incidence Analytics Group (IIAG), a coordinated global effort to apply advanced analytics and modelling to public influenza data, both epidemiological and virologic, in real-time and thus provide additional insights to countries who provide routine surveillance data to WHO. Our objectives are to systematically increase the value of data to health planners by applying advanced analytics and forecasting and for results to be immediately reproducible and deployable using an open repository of data and code. We expect the resources we develop and the associated community to provide an attractive option for the open analysis of key epidemiological data during seasonal epidemics and the early stages of an influenza pandemic.

Published

2020

6. Influenza activity in Kenya, 2007-2013: timing, association with climatic factors, and implications for vaccination campaigns

Author

Emukule, G.O., Mott, J.A., Spreeuwenberg, P., Viboud, C., Commanday, A., Muthoka, P., Munywoki, P.K., Nokes, D.J., Velden, K. van der, Paget, J.W., Emukule, G.O., Mott, J.A., Spreeuwenberg, P., Viboud, C., Commanday, A., Muthoka, P., Munywoki, P.K., Nokes, D.J., Velden, K. van der, and Paget, J.W.

Abstract

Contains fulltext : 172815.pdf (publisher's version ) (Open Access), BACKGROUND: Information on the timing of influenza circulation remains scarce in Tropical regions of Africa. OBJECTIVES: We assessed the relationship between influenza activity and several meteorological factors (temperature, specific humidity, precipitation) and characterized the timing of influenza circulation and its implications to vaccination strategies in Kenya. METHODS: We analyzed virologically confirmed influenza data for outpatient influenza-like illness (ILI), hospitalized for severe acute respiratory infections (SARI), and cases of severe pneumonia over the period 2007-2013. Using logistic and negative binomial regression methods, we assessed the independent association between climatic variables (lagged up to 4 weeks) and influenza activity. RESULTS: There were multiple influenza epidemics occurring each year and lasting a median duration of 2-4 months. On average, there were two epidemics occurring each year in most of the regions in Kenya, with the first epidemic occurring between the months of February and March and the second one between July and November. Specific humidity was independently and negatively associated with influenza activity. Combinations of low temperature (<18 degrees C) and low specific humidity (<11 g/kg) were significantly associated with increased influenza activity. CONCLUSIONS: Our study broadens understanding of the relationships between seasonal influenza activity and meteorological factors in the Kenyan context. While rainfall is frequently thought to be associated with influenza circulation in the tropics, the present findings suggest low humidity is more important in Kenya. If annual vaccination were a component of a vaccination strategy in Kenya, the months of April to June are proposed as optimal for associated campaigns.

Published

2016

7. Influenza activity in Kenya, 2007-2013: timing, association with climatic factors, and implications for vaccination campaigns

Author

Emukule, G.O., Mott, J.A., Spreeuwenberg, P., Viboud, C., Commanday, A., Muthoka, P., Munywoki, P.K., Nokes, D.J., Velden, K. van der, Paget, J.W., Emukule, G.O., Mott, J.A., Spreeuwenberg, P., Viboud, C., Commanday, A., Muthoka, P., Munywoki, P.K., Nokes, D.J., Velden, K. van der, and Paget, J.W.

Abstract

Contains fulltext : 172815.pdf (publisher's version ) (Open Access), BACKGROUND: Information on the timing of influenza circulation remains scarce in Tropical regions of Africa. OBJECTIVES: We assessed the relationship between influenza activity and several meteorological factors (temperature, specific humidity, precipitation) and characterized the timing of influenza circulation and its implications to vaccination strategies in Kenya. METHODS: We analyzed virologically confirmed influenza data for outpatient influenza-like illness (ILI), hospitalized for severe acute respiratory infections (SARI), and cases of severe pneumonia over the period 2007-2013. Using logistic and negative binomial regression methods, we assessed the independent association between climatic variables (lagged up to 4 weeks) and influenza activity. RESULTS: There were multiple influenza epidemics occurring each year and lasting a median duration of 2-4 months. On average, there were two epidemics occurring each year in most of the regions in Kenya, with the first epidemic occurring between the months of February and March and the second one between July and November. Specific humidity was independently and negatively associated with influenza activity. Combinations of low temperature (<18 degrees C) and low specific humidity (<11 g/kg) were significantly associated with increased influenza activity. CONCLUSIONS: Our study broadens understanding of the relationships between seasonal influenza activity and meteorological factors in the Kenyan context. While rainfall is frequently thought to be associated with influenza circulation in the tropics, the present findings suggest low humidity is more important in Kenya. If annual vaccination were a component of a vaccination strategy in Kenya, the months of April to June are proposed as optimal for associated campaigns.

Published

2016

8. Transmission of the First Influenza A(H1N1) pdm09 Pandemic Wave in Australia Was Driven by Undetected Infections: Pandemic Response Implications

Author

Viboud, C, Fielding, JE, Kelly, HA, Glass, K, Viboud, C, Fielding, JE, Kelly, HA, and Glass, K

Abstract

BACKGROUND: During the first wave of influenza A(H1N1)pdm09 in Victoria, Australia the rapid increase in notified cases and the high proportion with relatively mild symptoms suggested that community transmission was established before cases were identified. This lead to the hypothesis that those with low-level infections were the main drivers of the pandemic. METHODS: A deterministic susceptible-infected-recovered model was constructed to describe the first pandemic wave in a population structured by disease severity levels of asymptomatic, low-level symptoms, moderate symptoms and severe symptoms requiring hospitalisation. The model incorporated mixing, infectivity and duration of infectiousness parameters to calculate subgroup-specific reproduction numbers for each severity level. RESULTS: With stratum-specific effective reproduction numbers of 1.82 and 1.32 respectively, those with low-level symptoms, and those with asymptomatic infections were responsible for most of the transmission. The effective reproduction numbers for infections resulting in moderate symptoms and hospitalisation were less than one. Sensitivity analyses confirmed the importance of parameters relating to asymptomatic individuals and those with low-level symptoms. CONCLUSIONS: Transmission of influenza A(H1N1)pdm09 was largely driven by those invisible to the health system. This has implications for control measures--such as distribution of antivirals to cases and contacts and quarantine/isolation--that rely on detection of infected cases. Pandemic plans need to incorporate milder scenarios, with a graded approach to implementation of control measures.

Published

2015

9. Global Mortality Estimates for the 2009 Influenza Pandemic from the GLaMOR Project: A Modeling Study

Author

Simonsen, L, Spreeuwenberg, P, Lustig, R, Taylor, RJ, Fleming, DM, Kroneman, M, Van Kerkhove, MD, Mounts, AW, Paget, WJ, Echenique, H, Savy, V, Muscatello, D, MacIntyre, CR, Dwyer, DE, Azziz-Baumgartner, E, Homaira, N, Moura, FEA, Schuck, C, Akwar, H, Schanzer, D, Fuentes, R, Olea, A, Sotomayor, V, Feng, L, Yu, H, Mazick, A, Mølbak, K, Nielsen, J, Carrat, F, Lemaitre, M, Buchholz, U, Schweiger, B, Höhle, M, Vesenbeckh, S, Cowling, B, Leung, G, Tsang, T, Chuang, SK, Bromberg, M, Kaufman, Z, Sugaya, N, Oka Ezoe, K, Hayashi, S, Matsuda, M, Lopez-Gatell, H, Alpuche-Aranda, C, Noyola, D, Chowell, G, van Asten, L, Meijer, A, van den Wijngaard, K, van der Sande, M, Baker, M, Zhang, J, Benavides, JG, Munayco, C, Laguna-Torres, A, Rabczenko, D, Wojtyniak, B, Park, SH, Lee, YK, Zolotusca, L, Popovici, O, Popescu, R, Ang, LW, Cutter, J, Lin, R, Ma, S, Chen, M, Lee, VJ, Prosenc, K, Socan, M, Cohen, C, Larrauri, A, de Mateo, S, Méndez, LS, Sanz, CD, Andrews, N, Green, HK, Pebody, R, Saei, A, Shay, D, Viboud, C, Simonsen, L, Spreeuwenberg, P, Lustig, R, Taylor, RJ, Fleming, DM, Kroneman, M, Van Kerkhove, MD, Mounts, AW, Paget, WJ, Echenique, H, Savy, V, Muscatello, D, MacIntyre, CR, Dwyer, DE, Azziz-Baumgartner, E, Homaira, N, Moura, FEA, Schuck, C, Akwar, H, Schanzer, D, Fuentes, R, Olea, A, Sotomayor, V, Feng, L, Yu, H, Mazick, A, Mølbak, K, Nielsen, J, Carrat, F, Lemaitre, M, Buchholz, U, Schweiger, B, Höhle, M, Vesenbeckh, S, Cowling, B, Leung, G, Tsang, T, Chuang, SK, Bromberg, M, Kaufman, Z, Sugaya, N, Oka Ezoe, K, Hayashi, S, Matsuda, M, Lopez-Gatell, H, Alpuche-Aranda, C, Noyola, D, Chowell, G, van Asten, L, Meijer, A, van den Wijngaard, K, van der Sande, M, Baker, M, Zhang, J, Benavides, JG, Munayco, C, Laguna-Torres, A, Rabczenko, D, Wojtyniak, B, Park, SH, Lee, YK, Zolotusca, L, Popovici, O, Popescu, R, Ang, LW, Cutter, J, Lin, R, Ma, S, Chen, M, Lee, VJ, Prosenc, K, Socan, M, Cohen, C, Larrauri, A, de Mateo, S, Méndez, LS, Sanz, CD, Andrews, N, Green, HK, Pebody, R, Saei, A, Shay, D, and Viboud, C

Abstract

Background:Assessing the mortality impact of the 2009 influenza A H1N1 virus (H1N1pdm09) is essential for optimizing public health responses to future pandemics. The World Health Organization reported 18,631 laboratory-confirmed pandemic deaths, but the total pandemic mortality burden was substantially higher. We estimated the 2009 pandemic mortality burden through statistical modeling of mortality data from multiple countries.Methods and Findings:We obtained weekly virology and underlying cause-of-death mortality time series for 2005-2009 for 20 countries covering ∼35% of the world population. We applied a multivariate linear regression model to estimate pandemic respiratory mortality in each collaborating country. We then used these results plus ten country indicators in a multiple imputation model to project the mortality burden in all world countries. Between 123,000 and 203,000 pandemic respiratory deaths were estimated globally for the last 9 mo of 2009. The majority (62%-85%) were attributed to persons under 65 y of age. We observed a striking regional heterogeneity, with almost 20-fold higher mortality in some countries in the Americas than in Europe. The model attributed 148,000-249,000 respiratory deaths to influenza in an average pre-pandemic season, with only 19% in persons <65 y. Limitations include lack of representation of low-income countries among single-country estimates and an inability to study subsequent pandemic waves (2010-2012).Conclusions:We estimate that 2009 global pandemic respiratory mortality was ∼10-fold higher than the World Health Organization's laboratory-confirmed mortality count. Although the pandemic mortality estimate was similar in magnitude to that of seasonal influenza, a marked shift toward mortality among persons <65 y of age occurred, so that many more life-years were lost. The burden varied greatly among countries, corroborating early reports of far greater pandemic severity in the Americas than in Australia, New Zealand

Published

2013

10. Influenza Vaccine Effectiveness against Hospitalisation with Confirmed Influenza in the 2010-11 Seasons: A Test-negative Observational Study

Author

Viboud, C, Cheng, AC, Holmes, M, Irving, LB, Brown, SGA, Waterer, GW, Korman, TM, Friedman, ND, Senanayake, S, Dwyer, DE, Brady, S, Simpson, G, Wood-Baker, R, Upham, J, Paterson, D, Jenkins, C, Wark, P, Kelly, PM, Kotsimbos, T, Viboud, C, Cheng, AC, Holmes, M, Irving, LB, Brown, SGA, Waterer, GW, Korman, TM, Friedman, ND, Senanayake, S, Dwyer, DE, Brady, S, Simpson, G, Wood-Baker, R, Upham, J, Paterson, D, Jenkins, C, Wark, P, Kelly, PM, and Kotsimbos, T

Abstract

Immunisation programs are designed to reduce serious morbidity and mortality from influenza, but most evidence supporting the effectiveness of this intervention has focused on disease in the community or in primary care settings. We aimed to examine the effectiveness of influenza vaccination against hospitalisation with confirmed influenza. We compared influenza vaccination status in patients hospitalised with PCR-confirmed influenza with patients hospitalised with influenza-negative respiratory infections in an Australian sentinel surveillance system. Vaccine effectiveness was estimated from the odds ratio of vaccination in cases and controls. We performed both simple multivariate regression and a stratified analysis based on propensity score of vaccination. Vaccination status was ascertained in 333 of 598 patients with confirmed influenza and 785 of 1384 test-negative patients. Overall estimated crude vaccine effectiveness was 57% (41%, 68%). After adjusting for age, chronic comorbidities and pregnancy status, the estimated vaccine effectiveness was 37% (95% CI: 12%, 55%). In an analysis accounting for a propensity score for vaccination, the estimated vaccine effectiveness was 48.3% (95% CI: 30.0, 61.8%). Influenza vaccination was moderately protective against hospitalisation with influenza in the 2010 and 2011 seasons.

Published

2013

11. Direct and indirect effects of rotavirus vaccination: Comparing predictions from transmission dynamic models

Author

Pitzer, VE, Atkins, KE, de Blasio, BF, van Effelterre, T, Atchison, CJ, Harris, JP, Shim, E, Galvani, AP, Edmunds, WJ, Viboud, C, Patel, MM, Grenfell, BT, Parashar, UD, Lopman, BA, Pitzer, VE, Atkins, KE, de Blasio, BF, van Effelterre, T, Atchison, CJ, Harris, JP, Shim, E, Galvani, AP, Edmunds, WJ, Viboud, C, Patel, MM, Grenfell, BT, Parashar, UD, and Lopman, BA

Abstract

Early observations from countries that have introduced rotavirus vaccination suggest that there may be indirect protection for unvaccinated individuals, but it is unclear whether these benefits will extend to the long term. Transmission dynamic models have attempted to quantify the indirect protection that might be expected from rotavirus vaccination in developed countries, but results have varied. To better understand the magnitude and sources of variability in model projections, we undertook a comparative analysis of transmission dynamic models for rotavirus. We fit five models to reported rotavirus gastroenteritis (RVGE) data from England and Wales, and evaluated outcomes for short- and long-term vaccination effects. All of our models reproduced the important features of rotavirus epidemics in England and Wales. Models predicted that during the initial year after vaccine introduction, incidence of severe RVGE would be reduced 1.8-2.9 times more than expected from the direct effects of the vaccine alone (28-50% at 90% coverage), but over a 5-year period following vaccine introduction severe RVGE would be reduced only by 1.1-1.7 times more than expected from the direct effects (54-90% at 90% coverage). Projections for the long-term reduction of severe RVGE ranged from a 55% reduction at full coverage to elimination with at least 80% coverage. Our models predicted short-term reductions in the incidence of RVGE that exceeded estimates of the direct effects, consistent with observations from the United States and other countries. Some of the models predicted that the short-term indirect benefits may be offset by a partial shifting of the burden of RVGE to older unvaccinated individuals. Nonetheless, even when such a shift occurs, the overall reduction in severe RVGE is considerable. Discrepancies among model predictions reflect uncertainties about age variation in the risk and reporting of RVGE, and the duration of natural and vaccine-induced immunity, highlighting im

Published

2012

12. Direct and indirect effects of rotavirus vaccination: Comparing predictions from transmission dynamic models

Author

Pitzer, VE, Atkins, KE, de Blasio, BF, van Effelterre, T, Atchison, CJ, Harris, JP, Shim, E, Galvani, AP, Edmunds, WJ, Viboud, C, Patel, MM, Grenfell, BT, Parashar, UD, Lopman, BA, Pitzer, VE, Atkins, KE, de Blasio, BF, van Effelterre, T, Atchison, CJ, Harris, JP, Shim, E, Galvani, AP, Edmunds, WJ, Viboud, C, Patel, MM, Grenfell, BT, Parashar, UD, and Lopman, BA

Abstract

Early observations from countries that have introduced rotavirus vaccination suggest that there may be indirect protection for unvaccinated individuals, but it is unclear whether these benefits will extend to the long term. Transmission dynamic models have attempted to quantify the indirect protection that might be expected from rotavirus vaccination in developed countries, but results have varied. To better understand the magnitude and sources of variability in model projections, we undertook a comparative analysis of transmission dynamic models for rotavirus. We fit five models to reported rotavirus gastroenteritis (RVGE) data from England and Wales, and evaluated outcomes for short- and long-term vaccination effects. All of our models reproduced the important features of rotavirus epidemics in England and Wales. Models predicted that during the initial year after vaccine introduction, incidence of severe RVGE would be reduced 1.8-2.9 times more than expected from the direct effects of the vaccine alone (28-50% at 90% coverage), but over a 5-year period following vaccine introduction severe RVGE would be reduced only by 1.1-1.7 times more than expected from the direct effects (54-90% at 90% coverage). Projections for the long-term reduction of severe RVGE ranged from a 55% reduction at full coverage to elimination with at least 80% coverage. Our models predicted short-term reductions in the incidence of RVGE that exceeded estimates of the direct effects, consistent with observations from the United States and other countries. Some of the models predicted that the short-term indirect benefits may be offset by a partial shifting of the burden of RVGE to older unvaccinated individuals. Nonetheless, even when such a shift occurs, the overall reduction in severe RVGE is considerable. Discrepancies among model predictions reflect uncertainties about age variation in the risk and reporting of RVGE, and the duration of natural and vaccine-induced immunity, highlighting im

Published

2012

13. Molecular epidemiology of A/H3N2 and A/H1N1 influenza virus during a single epidemic season in the United States

Author

Nelson, MI, Edelman, L, Spiro, DJ, Boyne, AR, Bera, J, Halpin, R, Ghedin, E, Miller, MA, Simonsen, L, Viboud, C, Holmes, EC, Nelson, MI, Edelman, L, Spiro, DJ, Boyne, AR, Bera, J, Halpin, R, Ghedin, E, Miller, MA, Simonsen, L, Viboud, C, and Holmes, EC

Abstract

To determine the spatial and temporal dynamics of influenza A virus during a single epidemic, we examined whole-genome sequences of 284 A/H1N1 and 69 A/H3N2 viruses collected across the continental United States during the 2006-2007 influenza season, representing the largest study of its kind undertaken to date. A phylogenetic analysis revealed that multiple clades of both A/H1N1 and A/H3N2 entered and co-circulated in the United States during this season, even in localities that are distant from major metropolitan areas, and with no clear pattern of spatial spread. In addition, co-circulating clades of the same subtype exchanged genome segments through reassortment, producing both a minor clade of A/H3N2 viruses that appears to have re-acquired sensitivity to the adamantane class of antiviral drugs, as well as a likely antigenically distinct A/H1N1 clade that became globally dominant following this season. Overall, the co-circulation of multiple viral clades during the 2006-2007 epidemic season revealed patterns of spatial spread that are far more complex than observed previously, and suggests a major role for both migration and reassortment in shaping the epidemiological dynamics of human influenza A virus.

Published

2008

14. Multiple reassortment events in the evolutionary history of H1N1 influenza A virus since 1918

Author

Nelson, MI, Viboud, C, Simonsen, L, Bennett, RT, Griesemer, SB, St. George, K, Taylor, J, Spiro, DJ, Sengamalay, NA, Ghedin, E, Taubenberger, JK, Holmes, EC, Nelson, MI, Viboud, C, Simonsen, L, Bennett, RT, Griesemer, SB, St. George, K, Taylor, J, Spiro, DJ, Sengamalay, NA, Ghedin, E, Taubenberger, JK, and Holmes, EC

Abstract

The H1N1 subtype of influenza A virus has caused substantial morbidity and mortality in humans, first documented in the global pandemic of 1918 and continuing to the present day. Despite this disease burden, the evolutionary history of the A/H1N1 virus is not well understood, particularly whether there is a virological basis for several notable epidemics of unusual severity in the 1940s and 1950s. Using a data set of 71 representative complete genome sequences sampled between 1918 and 2006, we show that segmental reassortment has played an important role in the genomic evolution of A/H1N1 since 1918. Specifically, we demonstrate that an A/H1N1 isolate from the 1947 epidemic acquired novel PB2 and HA genes through intra-subtype reassortment, which may explain the abrupt antigenic evolution of this virus. Similarly, the 1951 influenza epidemic may also have been associated with reassortant A/H1N1 viruses. Intra-subtype reassortment therefore appears to be a more important process in the evolution and epidemiology of H1N1 influenza A virus than previously realized.

Published

2008

15. Molecular epidemiology of A/H3N2 and A/H1N1 influenza virus during a single epidemic season in the United States

Author

Nelson, MI, Edelman, L, Spiro, DJ, Boyne, AR, Bera, J, Halpin, R, Ghedin, E, Miller, MA, Simonsen, L, Viboud, C, Holmes, EC, Nelson, MI, Edelman, L, Spiro, DJ, Boyne, AR, Bera, J, Halpin, R, Ghedin, E, Miller, MA, Simonsen, L, Viboud, C, and Holmes, EC

Abstract

To determine the spatial and temporal dynamics of influenza A virus during a single epidemic, we examined whole-genome sequences of 284 A/H1N1 and 69 A/H3N2 viruses collected across the continental United States during the 2006-2007 influenza season, representing the largest study of its kind undertaken to date. A phylogenetic analysis revealed that multiple clades of both A/H1N1 and A/H3N2 entered and co-circulated in the United States during this season, even in localities that are distant from major metropolitan areas, and with no clear pattern of spatial spread. In addition, co-circulating clades of the same subtype exchanged genome segments through reassortment, producing both a minor clade of A/H3N2 viruses that appears to have re-acquired sensitivity to the adamantane class of antiviral drugs, as well as a likely antigenically distinct A/H1N1 clade that became globally dominant following this season. Overall, the co-circulation of multiple viral clades during the 2006-2007 epidemic season revealed patterns of spatial spread that are far more complex than observed previously, and suggests a major role for both migration and reassortment in shaping the epidemiological dynamics of human influenza A virus.

Published

2008

16. Multiple reassortment events in the evolutionary history of H1N1 influenza A virus since 1918

Author

Nelson, MI, Viboud, C, Simonsen, L, Bennett, RT, Griesemer, SB, St. George, K, Taylor, J, Spiro, DJ, Sengamalay, NA, Ghedin, E, Taubenberger, JK, Holmes, EC, Nelson, MI, Viboud, C, Simonsen, L, Bennett, RT, Griesemer, SB, St. George, K, Taylor, J, Spiro, DJ, Sengamalay, NA, Ghedin, E, Taubenberger, JK, and Holmes, EC

Abstract

The H1N1 subtype of influenza A virus has caused substantial morbidity and mortality in humans, first documented in the global pandemic of 1918 and continuing to the present day. Despite this disease burden, the evolutionary history of the A/H1N1 virus is not well understood, particularly whether there is a virological basis for several notable epidemics of unusual severity in the 1940s and 1950s. Using a data set of 71 representative complete genome sequences sampled between 1918 and 2006, we show that segmental reassortment has played an important role in the genomic evolution of A/H1N1 since 1918. Specifically, we demonstrate that an A/H1N1 isolate from the 1947 epidemic acquired novel PB2 and HA genes through intra-subtype reassortment, which may explain the abrupt antigenic evolution of this virus. Similarly, the 1951 influenza epidemic may also have been associated with reassortant A/H1N1 viruses. Intra-subtype reassortment therefore appears to be a more important process in the evolution and epidemiology of H1N1 influenza A virus than previously realized.

Published

2008