Literature DB >> 25802435

Meteorological conditions associated with increased incidence of West Nile virus disease in the United States, 2004-2012.

Micah B Hahn1, Andrew J Monaghan1, Mary H Hayden1, Rebecca J Eisen1, Mark J Delorey1, Nicole P Lindsey1, Roger S Nasci1, Marc Fischer2.   

Abstract

West Nile virus (WNV) is a leading cause of mosquito-borne disease in the United States. Annual seasonal outbreaks vary in size and location. Predicting where and when higher than normal WNV transmission will occur can help direct limited public health resources. We developed models for the contiguous United States to identify meteorological anomalies associated with above average incidence of WNV neuroinvasive disease from 2004 to 2012. We used county-level WNV data reported to ArboNET and meteorological data from the North American Land Data Assimilation System. As a result of geographic differences in WNV transmission, we divided the United States into East and West, and 10 climate regions. Above average annual temperature was associated with increased likelihood of higher than normal WNV disease incidence, nationally and in most regions. Lower than average annual total precipitation was associated with higher disease incidence in the eastern United States, but the opposite was true in most western regions. Although multiple factors influence WNV transmission, these findings show that anomalies in temperature and precipitation are associated with above average WNV disease incidence. Readily accessible meteorological data may be used to develop predictive models to forecast geographic areas with elevated WNV disease risk before the coming season. © The American Society of Tropical Medicine and Hygiene.

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Year:  2015        PMID: 25802435      PMCID: PMC4426558          DOI: 10.4269/ajtmh.14-0737

Source DB:  PubMed          Journal:  Am J Trop Med Hyg        ISSN: 0002-9637            Impact factor:   2.345


  45 in total

1.  Impact of climate variation on mosquito abundance in California.

Authors:  William K Reisen; Daniel Cayan; Mary Tyree; Christopher M Barker; Bruce Eldridge; Michael Dettinger
Journal:  J Vector Ecol       Date:  2008-06       Impact factor: 1.671

2.  Weather and land cover influences on mosquito populations in Sioux Falls, South Dakota.

Authors:  Ting-Wu Chuang; Michael B Hildreth; Denise L Vanroekel; Michael C Wimberly
Journal:  J Med Entomol       Date:  2011-05       Impact factor: 2.278

Review 3.  West Nile virus: review of the literature.

Authors:  Lyle R Petersen; Aaron C Brault; Roger S Nasci
Journal:  JAMA       Date:  2013-07-17       Impact factor: 56.272

4.  Urban land use predicts West Nile virus exposure in songbirds.

Authors:  Catherine A Bradley; Samantha E J Gibbs; Sonia Altizer
Journal:  Ecol Appl       Date:  2008-07       Impact factor: 4.657

5.  Culex restuans (Diptera: Culicidae) oviposition behavior determined by larval habitat quality and quantity in southeastern Michigan.

Authors:  Michael H Reiskind; Mark L Wilson
Journal:  J Med Entomol       Date:  2004-03       Impact factor: 2.278

6.  Land cover variation and West Nile virus prevalence: patterns, processes, and implications for disease control.

Authors:  Vanessa O Ezenwa; Lesley E Milheim; Michelle F Coffey; Marvin S Godsey; Raymond J King; Stephen C Guptill
Journal:  Vector Borne Zoonotic Dis       Date:  2007       Impact factor: 2.133

7.  West Nile virus in overwintering Culex mosquitoes, New York City, 2000.

Authors:  R S Nasci; H M Savage; D J White; J R Miller; B C Cropp; M S Godsey; A J Kerst; P Bennett; K Gottfried; R S Lanciotti
Journal:  Emerg Infect Dis       Date:  2001 Jul-Aug       Impact factor: 6.883

8.  Ecological factors associated with West Nile virus transmission, northeastern United States.

Authors:  Heidi E Brown; James E Childs; Maria A Diuk-Wasser; Durland Fish
Journal:  Emerg Infect Dis       Date:  2008-10       Impact factor: 6.883

9.  West Nile virus epidemics in North America are driven by shifts in mosquito feeding behavior.

Authors:  A Marm Kilpatrick; Laura D Kramer; Matthew J Jones; Peter P Marra; Peter Daszak
Journal:  PLoS Biol       Date:  2006-02-28       Impact factor: 8.029

10.  Heeding the message? Determinants of risk behaviours for West Nile virus.

Authors:  Susan J Elliott; Mark Loeb; Daniel Harrington; John Eyles
Journal:  Can J Public Health       Date:  2008 Mar-Apr
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  26 in total

1.  Integrating Environmental Monitoring and Mosquito Surveillance to Predict Vector-borne Disease: Prospective Forecasts of a West Nile Virus Outbreak.

Authors:  Justin K Davis; Geoffrey Vincent; Michael B Hildreth; Lon Kightlinger; Christopher Carlson; Michael C Wimberly
Journal:  PLoS Curr       Date:  2017-05-23

2.  Drought and immunity determine the intensity of West Nile virus epidemics and climate change impacts.

Authors:  Sara H Paull; Daniel E Horton; Moetasim Ashfaq; Deeksha Rastogi; Laura D Kramer; Noah S Diffenbaugh; A Marm Kilpatrick
Journal:  Proc Biol Sci       Date:  2017-02-08       Impact factor: 5.349

3.  Transmission of West Nile and five other temperate mosquito-borne viruses peaks at temperatures between 23°C and 26°C.

Authors:  Marta S Shocket; Anna B Verwillow; Mailo G Numazu; Hani Slamani; Jeremy M Cohen; Fadoua El Moustaid; Jason Rohr; Leah R Johnson; Erin A Mordecai
Journal:  Elife       Date:  2020-09-15       Impact factor: 8.140

Review 4.  Reducing West Nile Virus Risk Through Vector Management.

Authors:  Roger S Nasci; John-Paul Mutebi
Journal:  J Med Entomol       Date:  2019-10-28       Impact factor: 2.278

5.  Overlap in the Seasonal Infection Patterns of Avian Malaria Parasites and West Nile Virus in Vectors and Hosts.

Authors:  Matthew C I Medeiros; Robert E Ricklefs; Jeffrey D Brawn; Marilyn O Ruiz; Tony L Goldberg; Gabriel L Hamer
Journal:  Am J Trop Med Hyg       Date:  2016-09-12       Impact factor: 2.345

6.  Spatiotemporal Bayesian modeling of West Nile virus: Identifying risk of infection in mosquitoes with local-scale predictors.

Authors:  Mark H Myer; John M Johnston
Journal:  Sci Total Environ       Date:  2018-10-02       Impact factor: 7.963

7.  Vector Surveillance, Host Species Richness, and Demographic Factors as West Nile Disease Risk Indicators.

Authors:  John M Humphreys; Katherine I Young; Lee W Cohnstaedt; Kathryn A Hanley; Debra P C Peters
Journal:  Viruses       Date:  2021-05-18       Impact factor: 5.048

8.  Effects of Scale on Modeling West Nile Virus Disease Risk.

Authors:  Johnny A Uelmen; Patrick Irwin; Dan Bartlett; William Brown; Surendra Karki; Marilyn O'Hara Ruiz; Jennifer Fraterrigo; Bo Li; Rebecca L Smith
Journal:  Am J Trop Med Hyg       Date:  2021-01       Impact factor: 3.707

9.  Solar radiation and the incidence and mortality of leading invasive cancers in the United States.

Authors:  Alan B Fleischer; Sarah E Fleischer
Journal:  Dermatoendocrinol       Date:  2016-03-28

10.  On the Seasonal Occurrence and Abundance of the Zika Virus Vector Mosquito Aedes Aegypti in the Contiguous United States.

Authors:  Andrew J Monaghan; Cory W Morin; Daniel F Steinhoff; Olga Wilhelmi; Mary Hayden; Dale A Quattrochi; Michael Reiskind; Alun L Lloyd; Kirk Smith; Chris A Schmidt; Paige E Scalf; Kacey Ernst
Journal:  PLoS Curr       Date:  2016-03-16
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