The objective of this proposal is to develop new mathematical models of infectious disease transmission that effectively, capture the impact of stochasticity on dynamics and lead to more effective control. The group will study the dynamics of disease spread in fluctuating environments modeled at various population scales. First, the group will develop a new class of stochastic metapopulation models for disease spread, noting the importance of stochastic effects in the dynamics. These models capture new types of solutions that cannot be realized in deterministic models, such as disease extinction. The group proposes to develop new mathematical and computational methods for designing and analyzing this class of models. The group will also model various delivery schedules of vaccines into populations. By assuming limited resources, such as constrained vaccine supply or quarantine-type contact control, the results from these models will lead to practical solutions for experimentalists and poUcy makers. The project will lead to greater insight into the mechanisms that allow a disease to successfully propagate in a population, as well as new mathematical tools to analyze stochastic systems. In our long term vision for this project, the group will contribute new mathematical tools to the field of epidemiology. These tools will be motivated by improved models of real world problems, which lead to better ways to design optimization methods. Our work is driven by real epidemiological threats, is derived from data collected from around the world, and is focused on answering questions that could save lives. There is an excitement about the impact of interdisciplinary research efforts combining mathematical fields, such as nonlinear analysis, stochastic d3Tiamics, and network theory, with systems biology approaches such as population dynamics, epidemiology, and immunology. This proposal describes ways in which modeling can open new research directions in all of these fields.

Public Health Relevance

Noting the collaborative nature of this research proposal, we expect that this project will produce findings that could improve health standards across the world. It may lead to improved methods of disease control and health monitoring.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
1R01GM090204-01
Application #
7787317
Study Section
Special Emphasis Panel (ZGM1-CBCB-5 (BM))
Program Officer
Anderson, James J
Project Start
2009-09-01
Project End
2012-08-31
Budget Start
2009-09-01
Budget End
2010-08-31
Support Year
1
Fiscal Year
2009
Total Cost
$264,569
Indirect Cost
Name
Montclair State University
Department
Biostatistics & Other Math Sci
Type
Schools of Arts and Sciences
DUNS #
053506184
City
Montclair
State
NJ
Country
United States
Zip Code
07043
Forgoston, Eric; Shaw, Leah B; Schwartz, Ira B (2015) A Framework for Inferring Unobserved Multistrain Epidemic Subpopulations Using Synchronization Dynamics. Bull Math Biol 77:1437-55
Rodriguez-Barraquer, Isabel; Mier-y-Teran-Romero, Luis; Schwartz, Ira B et al. (2014) Potential opportunities and perils of imperfect dengue vaccines. Vaccine 32:514-20
Shkarayev, Maxim S; Tunc, Ilker; Shaw, Leah B (2014) Epidemics with temporary link deactivation in scale-free networks. J Phys A Math Theor 47:
Tunc, Ilker; Shaw, Leah B (2014) Effects of community structure on epidemic spread in an adaptive network. Phys Rev E Stat Nonlin Soft Matter Phys 90:022801
Rodriguez-Barraquer, Isabel; Mier-y-Teran-Romero, Luis; Burke, Donald S et al. (2013) Challenges in the interpretation of dengue vaccine trial results. PLoS Negl Trop Dis 7:e2126
Shkarayev, Maxim S; Shaw, Leah B (2013) Asymptotically inspired moment-closure approximation for adaptive networks. Phys Rev E Stat Nonlin Soft Matter Phys 88:052804
Shkarayev, Maxim S; Schwartz, Ira B; Shaw, Leah B (2013) Recruitment dynamics in adaptive social networks. J Phys A Math Theor 46:245003
Lindley, Brandon; Mier-Y-Teran-Romero, Luis; Schwartz, Ira B (2013) Noise Induced Pattern Switching in Randomly Distributed Delayed Swarms. Proc Am Control Conf 2013:4587-4591
Forgoston, Eric; Schwartz, Ira B (2013) Predicting unobserved exposures from seasonal epidemic data. Bull Math Biol 75:1450-71
Mier-y-Teran-Romero, Luis; Schwartz, Ira B; Cummings, Derek A T (2013) Breaking the symmetry: immune enhancement increases persistence of dengue viruses in the presence of asymmetric transmission rates. J Theor Biol 332:203-10

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