The inevitability of global climate change has led to speculation regarding its effects on the incidence and distribution of infectious disease risk. This important topic has received well-deserved attention in the form of hypothesis-driven research aimed at untangling the relationships between climate and infectious disease, usually focusing on one disease in a specific population or geographic region. However, no study has systematically examined the impact of climate change on the global burden of infectious diseases. Though a comprehensive approach is ambitious, informatics tools, statistical methods and computing capacity now exist to begin to address this challenge quickly and efficiently. We propose to model global relationships between climate and disease risk and to use these models to project future effects of climate change on infectious disease risk. By coupling new technologies for automated, global disease outbreak detection with existing climate data we will comprehensively assess climate-disease relationships on a global scale. Leveraging our previous experience in climate-based disease modeling and our development of HealthMap.org, a leading global infectious disease surveillance system, we will explore an informatics approach to investigating the predictive relationships between climate and a number of infectious diseases. The goals of our proposed research are to broadly characterize the global effects of climate on infectious disease risk and burden and to evaluate the resulting models under future climate change scenarios to project changes in global disease risk due to climate change. First, we plan to validate the use of event-based infectious disease surveillance data sources for tracking spatiotemporal trends in global infectious disease risk and burden. Building on our previous efforts in identifying informal sources for outbreak surveillance, we will assess the reliability of these sources for analyses of large-scale, long-term epidemiological patterns. Second, using this validated data, we will identify the diseases most sensitive to climate and build disease-specific predictive spatiotemporal models of relationships between climate and infectious disease risk and burden. Finally, we will leverage existing climate change forecasts to evaluate our models under various climate change scenarios. Coupled with global population growth projections, these models can be used to predict changes in populations at risk as a consequence of climate change. Guided by our advisory group including partners at the WHO, Fogarty International, Red Cross/Red Crescent Climate Center, and NASA, we plan to frame our results in a policy- relevant manner that will inform ongoing international surveillance and impact assessment efforts.

Public Health Relevance

While the inevitability of global climate change has led to speculation regarding its effects on the incidence and distribution of infectious disease risk, no study has systematically examined the impact of climate change on the global burden of infectious diseases. We propose to couple new disease surveillance technologies and advanced statistical methodologies with global climate data in order to broadly characterize and analyze the global effects of climate on infectious disease risk and burden. Our goal is to project the likely changes in global disease risk due to climate change and to inform ongoing surveillance and impact assessments efforts of international organizations, such as the World Health Organization and the Red Cross.

Agency
National Institute of Health (NIH)
Institute
National Library of Medicine (NLM)
Type
Research Project (R01)
Project #
5R01LM010812-03
Application #
8318255
Study Section
Special Emphasis Panel (ZLM1-ZH-C (M3))
Program Officer
Sim, Hua-Chuan
Project Start
2010-07-15
Project End
2016-07-14
Budget Start
2012-07-15
Budget End
2013-07-14
Support Year
3
Fiscal Year
2012
Total Cost
$409,248
Indirect Cost
$174,048
Name
Children's Hospital Boston
Department
Type
DUNS #
076593722
City
Boston
State
MA
Country
United States
Zip Code
02115
Hswen, Yulin; Naslund, John A; Brownstein, John S et al. (2018) Online Communication about Depression and Anxiety among Twitter Users with Schizophrenia: Preliminary Findings to Inform a Digital Phenotype Using Social Media. Psychiatr Q 89:569-580
Thézé, Julien; Li, Tony; du Plessis, Louis et al. (2018) Genomic Epidemiology Reconstructs the Introduction and Spread of Zika Virus in Central America and Mexico. Cell Host Microbe 23:855-864.e7
Faria, N R; Kraemer, M U G; Hill, S C et al. (2018) Genomic and epidemiological monitoring of yellow fever virus transmission potential. Science 361:894-899
Shearer, Freya M; Longbottom, Joshua; Browne, Annie J et al. (2018) Existing and potential infection risk zones of yellow fever worldwide: a modelling analysis. Lancet Glob Health 6:e270-e278
O'Reilly, Kathleen M; Lowe, Rachel; Edmunds, W John et al. (2018) Projecting the end of the Zika virus epidemic in Latin America: a modelling analysis. BMC Med 16:180
Majumder, Maimuna S; Brownstein, John S; Finkelstein, Stan N et al. (2017) Nosocomial amplification of MERS-coronavirus in South Korea, 2015. Trans R Soc Trop Med Hyg 111:261-269
Kraemer, Moritz U G; Brady, Oliver J; Watts, Alexander et al. (2017) Zika virus transmission in Angola and the potential for further spread to other African settings. Trans R Soc Trop Med Hyg 111:527-529
Hswen, Yulin; Naslund, John A; Chandrashekar, Pooja et al. (2017) Exploring online communication about cigarette smoking among Twitter users who self-identify as having schizophrenia. Psychiatry Res 257:479-484
Zinszer, Kate; Morrison, Kathryn; Brownstein, John S et al. (2017) Reconstruction of Zika Virus Introduction in Brazil. Emerg Infect Dis 23:91-94
Shearer, Freya M; Moyes, Catherine L; Pigott, David M et al. (2017) Global yellow fever vaccination coverage from 1970 to 2016: an adjusted retrospective analysis. Lancet Infect Dis 17:1209-1217

Showing the most recent 10 out of 81 publications