In response to the 2009 H1N1 pandemic, interventions were conducted in an effort to limit transmission, including school closure, vaccination and antiviral prophylaxis. By and large, these approaches were meant to reduce the population level transmission of disease, rather than to protect specific individuals from infection. Using current methods, it is difficult to measure how effective such interventions were. Conducting a randomized controlled trial is difficult due to the unknown timing and location of outbreaks, as well as being ethically problematic. However, quantifying intervention effects is important. Knowing the extent to which transmission is reduced by particular control measures can help us to determine how many cases can be prevented by a particular approach, and whether the approach is sufficient to interrupt (rather than simply reduce) disease spread. Also, interventions are not without both direct and indirect social and financial costs. Deciding whether the effect of an intervention justifies its cost depends on the size of the expected effect and the severity of the disease being prevented. Finally, modern approaches to disease control and public health planning rely extensively on models of disease transmission. These models are only as good as their inputs, one of the most important of which is the effectiveness of any planned intervention. While mechanistic approaches to quantifying intervention effects may be useful, they are assumption laden and could be much improved by measures of the real world reduction in population level transmission provided by these interventions. The objective of the proposed research is to quantify the effects of interventions on the transmission dynamics of influenza through the development and validation of statistical techniques and enhanced study designs. Specifically, we aim to (1) estimate the effect of prophylactic use of antivirals combined with reactive vaccination on influenza transmission in long term care facilities, (2) estimate the effectiveness of social distancing measures to control influenza transmission in Thailand, and (3) develop and validate enhanced study designs for the investigation of outbreaks of influenza and other pathogens. The methods and techniques used to answer these questions will be widely applicable to other diseases (particularly respiratory viruses), and will provide researchers with new tools to investigate transmission dynamics and identify new methods of disease control. The proposed research is part of a K22 award. Prior to receiving the award the PI candidate will continue to work in his post-doctoral position under the supervision of Dr. Derek Cummings on research into the understanding and modeling of infectious disease. This research will be conducted under two grants, """"""""Immune landscapes of human influenza in households, towns and cities in southern China"""""""" (NIH, 1 R01 TW 0008246-01) and the """"""""Vaccine Modeling Initiative"""""""" (Bill and Melinda Gates Foundation). In his role in the Immune Landscapes project, the applicant will be involved in the collection of serological data on influenza infection from Guang Dong province, China, and the analysis of this data. This work will further his understanding of both the science and practicalities of infectious disease research. In the Vaccine Modeling Initiative, the applicant will work closely with Dr. Cummings and Dr. Bryan Grenfell in an analysis of the effectiveness of reactive vaccination in cholera outbreaks, thereby increasing his abilities in the modeling of infectious disease and the assessment of intervention effects. In addition, the candidate will continue to consult with his mentors Dr. Ron Brookmeyer (on statistical matters), and Dr. Charlotte Gaydos (on laboratory topics and virology). The experience and guidance he receives from this postdoctoral work will leave the candidate well prepared to both succeed in the proposed research and as an independent investigator. PUBLIC HEALTH RELEVENCE: An understanding of the dynamics of influenza transmission and the effectiveness of interventions in mitigating it is important due to the threat of emerging pandemic strains as wells as the high burden of endemic disease. This project aims to study the transmission dynamics of influenza and the effect of interventions through the development and application of statistical techniques and novel study designs. This research will provide a direct benefit to public health by estimating the effect of commonly used interventions and fundamental characteristics of influenza transmission.

Public Health Relevance

Anunderstandin ofthedynamics ofinfluena transmissionandtheeffectivenessofinterventionsin mtgtngitisimportntduetothethetofemegngpndemcstansaswelsasthehghbud ndmicdisas.Thisprojc aims osudyttahn smssiondynamcs o nluenz ndtheefect o inervnions hroughth dvlopmn andapplicaionostifcsaltaeichniquesand novel study desins.Thsreserch wl povdeadrectbeneitto pubichelthby estimtngtheefectofcommo usedintreventionsandfundmentlchrcteistcsofinluenz tansmisson.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Career Transition Award (K22)
Project #
1K22AI092150-01
Application #
8035103
Study Section
Microbiology and Infectious Diseases B Subcommittee (MID)
Program Officer
Stemmy, Erik J
Project Start
2011-07-16
Project End
2013-06-30
Budget Start
2011-07-16
Budget End
2012-06-30
Support Year
1
Fiscal Year
2011
Total Cost
$162,000
Indirect Cost
Name
Johns Hopkins University
Department
Public Health & Prev Medicine
Type
Schools of Public Health
DUNS #
001910777
City
Baltimore
State
MD
Country
United States
Zip Code
21218
Lessler, J; Edmunds, W J; Halloran, M E et al. (2015) Seven challenges for model-driven data collection in experimental and observational studies. Epidemics 10:78-82
Azman, Andrew S; Luquero, Francisco J; Ciglenecki, Iza et al. (2015) The Impact of a One-Dose versus Two-Dose Oral Cholera Vaccine Regimen in Outbreak Settings: A Modeling Study. PLoS Med 12:e1001867
Kucharski, Adam J; Lessler, Justin; Read, Jonathan M et al. (2015) Estimating the life course of influenza A(H3N2) antibody responses from cross-sectional data. PLoS Biol 13:e1002082
Longosz, Andrew F; Mehta, Shruti H; Kirk, Gregory D et al. (2014) Incorrect identification of recent HIV infection in adults in the United States using a limiting-antigen avidity assay. AIDS 28:1227-32
Grabowski, Mary K; Lessler, Justin; Redd, Andrew D et al. (2014) The role of viral introductions in sustaining community-based HIV epidemics in rural Uganda: evidence from spatial clustering, phylogenetics, and egocentric transmission models. PLoS Med 11:e1001610
Read, Jonathan M; Lessler, Justin; Riley, Steven et al. (2014) Social mixing patterns in rural and urban areas of southern China. Proc Biol Sci 281:20140268
Longosz, Andrew F; Serwadda, David; Nalugoda, Fred et al. (2014) Impact of HIV subtype on performance of the limiting antigen-avidity enzyme immunoassay, the bio-rad avidity assay, and the BED capture immunoassay in Rakai, Uganda. AIDS Res Hum Retroviruses 30:339-44
Rainwater-Lovett, Kaitlin; Chun, Kevin; Lessler, Justin (2014) Influenza outbreak control practices and the effectiveness of interventions in long-term care facilities: a systematic review. Influenza Other Respir Viruses 8:74-82
Kaufman, James; Lessler, Justin; Harry, April et al. (2014) A likelihood-based approach to identifying contaminated food products using sales data: performance and challenges. PLoS Comput Biol 10:e1003692
Azman, Andrew S; Rudolph, Kara E; Cummings, Derek A T et al. (2013) The incubation period of cholera: a systematic review. J Infect 66:432-8

Showing the most recent 10 out of 17 publications