Literature DB >> 19960707

Seasonal patterns for entomological measures of risk for exposure to Culex vectors and West Nile virus in relation to human disease cases in northeastern Colorado.

Bethany G Bolling1, Christopher M Barker, Chester G Moore, W John Pape, Lars Eisen.   

Abstract

We examined seasonal patterns for entomological measures of risk for exposure to Culex vectors and West Nile virus (family Flaviviridae, genus Flavivirus, WNV) in relation to human WNV disease cases in a five-county area of northeastern Colorado during 2006-2007. Studies along habitat/elevation gradients in 2006 showed that the seasonal activity period is shortened and peak numbers occur later in the summer for Culex tarsalis Coquillett females in foothills-montane areas >1600 m compared with plains areas <1600 m in Colorado's Front Range. Studies in the plains of northeastern Colorado in 2007 showed that seasonal patterns of abundance for Cx. tarsalis and Culex pipiens L. females differed in that Cx. tarsalis reached peak abundance in early July (mean of 328.9 females per trap night for 18 plains sites), whereas the peak for Cx. pipiens did not occur until late August (mean of 16.4 females per trap night). During June-September in 2007, which was a year of intense WNV activity in Colorado with 578 reported WNV disease cases, we recorded WNV-infected Cx. tarsalis females from 16 of 18 sites in the plains. WNV infection rates in Cx. tarsalis females increased gradually from late June to peak in mid-August (overall maximum likelihood estimate for WNV infection rate of 8.29 per 1000 females for the plains sites in mid-August). No WNV-infected Culex mosquitoes were recorded from sites >1600 m. The vector index for abundance of WNV-infected Cx. tarsalis females for the plains sites combined exceeded 0.50 from mid-July to mid-August, with at least one site exceeding 1.00 from early July to late August. Finally, we found that abundance of Cx. tarsalis females and the vector index for infected females were strongly associated with weekly numbers of WNV disease cases with onset 4-7 wk later (female abundance) or 1-2 wk later (vector index).

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Year:  2009        PMID: 19960707      PMCID: PMC2802831          DOI: 10.1603/033.046.0641

Source DB:  PubMed          Journal:  J Med Entomol        ISSN: 0022-2585            Impact factor:   2.278


  32 in total

1.  A THREE-YEAR STUDY OF THE FEEDING HABITS OF CULEX TARSALIS IN KERN COUNTY, CALIFORNIA.

Authors:  C H TEMPELIS; W C REEVES; R E BELLAMY; M F LOFY
Journal:  Am J Trop Med Hyg       Date:  1965-01       Impact factor: 2.345

2.  Emergence of West Nile virus in mosquito (Diptera: Culicidae) communities of the New Mexico Rio Grande Valley.

Authors:  Mark A DiMenna; Rudy Bueno; Robert R Parmenter; Douglas E Norris; Jeff M Sheyka; Josephine L Molina; Elisa M LaBeau; Elizabeth S Hatton; Gregory E Glass
Journal:  J Med Entomol       Date:  2006-05       Impact factor: 2.278

3.  Epidemiology of the arthropod-borne viral encephalitides in Kern County, California, 1943-1952.

Authors:  W C REEVES; W M HAMMON; W A LONGSHORE; H E McCLURE; A F GEIB
Journal:  Publ Public Health Univ Calif       Date:  1962-06-06

4.  Entomological studies along the Colorado Front Range during a period of intense West Nile virus activity.

Authors:  B G Bolling; C G Moore; S L Anderson; C D Blair; B J Beaty
Journal:  J Am Mosq Control Assoc       Date:  2007-03       Impact factor: 0.917

5.  West Nile virus in host-seeking mosquitoes within a residential neighborhood in Grand Forks, North Dakota.

Authors:  Jeffrey A Bell; Nathan J Mickelson; Jefferson A Vaughan
Journal:  Vector Borne Zoonotic Dis       Date:  2005       Impact factor: 2.133

6.  Rapid detection of west nile virus from human clinical specimens, field-collected mosquitoes, and avian samples by a TaqMan reverse transcriptase-PCR assay.

Authors:  R S Lanciotti; A J Kerst; R S Nasci; M S Godsey; C J Mitchell; H M Savage; N Komar; N A Panella; B C Allen; K E Volpe; B S Davis; J T Roehrig
Journal:  J Clin Microbiol       Date:  2000-11       Impact factor: 5.948

7.  Relationships among weather, mosquito abundance, and encephalitis virus activity in California: Kern County 1990-98.

Authors:  J Wegbreit; W K Reisen
Journal:  J Am Mosq Control Assoc       Date:  2000-03       Impact factor: 0.917

8.  Seasonal blood-feeding behavior of Culex tarsalis (Diptera: Culicidae) in Weld County, Colorado, 2007.

Authors:  Rebekah Kent; Lara Juliusson; Michael Weissmann; Sara Evans; Nicholas Komar
Journal:  J Med Entomol       Date:  2009-03       Impact factor: 2.278

9.  Behavioral risks for West Nile virus disease, northern Colorado, 2003.

Authors:  Indira B Gujral; Emily C Zielinski-Gutierrez; Adrienne LeBailly; Roger Nasci
Journal:  Emerg Infect Dis       Date:  2007-03       Impact factor: 6.883

10.  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
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  29 in total

1.  Population genetic data suggest a role for mosquito-mediated dispersal of West Nile virus across the western United States.

Authors:  Meera Venkatesan; Jason L Rasgon
Journal:  Mol Ecol       Date:  2010-03-08       Impact factor: 6.185

2.  Insect-specific flaviviruses from Culex mosquitoes in Colorado, with evidence of vertical transmission.

Authors:  Bethany G Bolling; Lars Eisen; Chester G Moore; Carol D Blair
Journal:  Am J Trop Med Hyg       Date:  2011-07       Impact factor: 2.345

3.  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

4.  Temporal and Spatial Variability of Entomological Risk Indices for West Nile Virus Infection in Northern Colorado: 2006-2013.

Authors:  Joseph R Fauver; Lauren Pecher; Jessica A Schurich; Bethany G Bolling; Mike Calhoon; Nathan D Grubaugh; Kristen L Burkhalter; Lars Eisen; Barbara G Andre; Roger S Nasci; Adrienne LeBailly; Gregory D Ebel; Chester G Moore
Journal:  J Med Entomol       Date:  2016-03       Impact factor: 2.278

5.  Predicting human West Nile virus infections with mosquito surveillance data.

Authors:  A Marm Kilpatrick; W John Pape
Journal:  Am J Epidemiol       Date:  2013-07-03       Impact factor: 4.897

6.  The roles of mosquito and bird communities on the prevalence of West Nile virus in urban wetland and residential habitats.

Authors:  Brian J Johnson; Kristin Munafo; Laura Shappell; Nellie Tsipoura; Mark Robson; Joan Ehrenfeld; Michael V K Sukhdeo
Journal:  Urban Ecosyst       Date:  2012-09       Impact factor: 3.005

Review 7.  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

8.  Impact of West Nile Virus on Bird Populations: Limited Lasting Effects, Evidence for Recovery, and Gaps in Our Understanding of Impacts on Ecosystems.

Authors:  A Marm Kilpatrick; Sarah S Wheeler
Journal:  J Med Entomol       Date:  2019-10-28       Impact factor: 2.278

9.  Satellite Microwave Remote Sensing for Environmental Modeling of Mosquito Population Dynamics.

Authors:  Ting-Wu Chuang; Geoffrey M Henebry; John S Kimball; Denise L Vanroekel-Patton; Michael B Hildreth; Michael C Wimberly
Journal:  Remote Sens Environ       Date:  2012-10       Impact factor: 10.164

10.  Estimating West Nile virus transmission period in Pennsylvania using an optimized degree-day model.

Authors:  Shi Chen; Justine I Blanford; Shelby J Fleischer; Michael Hutchinson; Michael C Saunders; Matthew B Thomas
Journal:  Vector Borne Zoonotic Dis       Date:  2013-04-16       Impact factor: 2.133
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