The effect of temperature on Anopheles mosquito population dynamics and the potential for malaria transmission.
about
Modelling the influence of temperature and rainfall on the population dynamics of Anopheles arabiensis.The Role of Climatic and Density Dependent Factors in Shaping Mosquito Population Dynamics: The Case of Culex pipiens in Northwestern ItalyRemote Sensing-Driven Climatic/Environmental Variables for Modelling Malaria Transmission in Sub-Saharan AfricaArbovirosis and potential transmission blocking vaccinesClimate, environmental and socio-economic change: weighing up the balance in vector-borne disease transmissionZika and chikungunya: mosquito-borne viruses in a changing worldA method for screening climate change-sensitive infectious diseasesClimate influences on the cost-effectiveness of vector-based interventions against malaria in elimination scenariosModelling Anopheles gambiae s.s. Population Dynamics with Temperature- and Age-Dependent Survival.Seasonal associations of climatic drivers and malaria in the highlands of Ethiopia.Association of Climatic Variability, Vector Population and Malarial Disease in District of Visakhapatnam, India: A Modeling and Prediction AnalysisAn integrated risk and vulnerability assessment framework for climate change and malaria transmission in East Africa.Effect of climatic variability on malaria trends in Baringo County, Kenya.Seasonally lagged effects of climatic factors on malaria incidence in South Africa.Fine-scale variation in microclimate across an urban landscape shapes variation in mosquito population dynamics and the potential of Aedes albopictus to transmit arboviral disease.Epidemiological and clinical profile of paediatric malaria: a cross sectional study performed on febrile children in five epidemiological strata of malaria in Cameroon.Urbanization increases Aedes albopictus larval habitats and accelerates mosquito development and survivorship.Temperature during larval development and adult maintenance influences the survival of Anopheles gambiae s.s.Spatio-Temporal Identification of Areas Suitable for West Nile Disease in the Mediterranean Basin and Central Europe.Remotely Sensed Environmental Conditions and Malaria Mortality in Three Malaria Endemic Regions in Western KenyaEvidence for temporal population replacement and the signature of ecological adaptation in a major Neotropical malaria vector in Amazonian Peru.The ecological foundations of transmission potential and vector-borne disease in urban landscapesSpatiotemporal epidemic characteristics and risk factor analysis of malaria in Yunnan Province, ChinaA Weather-Based Prediction Model of Malaria Prevalence in Amenfi West District, Ghana.The impact of temperature changes on vector-borne disease transmission: Culicoides midges and bluetongue virus.Interplay of population genetics and dynamics in the genetic control of mosquitoes.Resting and feeding preferences of Anopheles stephensi in an urban setting, perennial for malaria.Some like it hot: a differential response to changing temperatures by the malaria vectors Anopheles funestus and An. gambiae s.l.The importance of temperature fluctuations in understanding mosquito population dynamics and malaria risk.The Influence of Dams on Malaria Transmission in Sub-Saharan Africa.A Malaria Transmission Model with Temperature-Dependent Incubation Period.Modeling the Impact of Bed-Net Use and Treatment on Malaria Transmission Dynamics.Epidemiological consequences of immune sensitisation by pre-exposure to vector saliva.Why some sites are responding better to anti-malarial interventions? A case study from western Kenya.Long-term pathogenic response to Plasmodium relictum infection in Culex pipiens mosquito.The associations between malaria, interventions, and the environment: a systematic review and meta-analysis.Variations in household microclimate affect outdoor-biting behaviour of malaria vectors.Rethinking the extrinsic incubation period of malaria parasites.Microclimate variables of the ambient environment deliver the actual estimates of the extrinsic incubation period of Plasmodium vivax and Plasmodium falciparum: a study from a malaria-endemic urban setting, Chennai in India.Climate drivers of vector-borne diseases in Africa and their relevance to control programmes
P2860
Q26315267-A06F036C-24A5-4FBA-9015-90E45816E153Q26315507-363B4D19-093A-4442-A135-44D3CFEA4117Q26744477-B83538AE-4BAA-4F56-A4FD-4CC46FC31554Q27468657-61F98BBC-2F0D-4618-B61B-47CFF73075D0Q28087411-72C5FF3E-5C68-4D8C-9B0C-14EF32F37962Q28804217-F3974D3F-BCBB-41A8-996C-3C444E397499Q30884705-78B3DA2A-4730-469E-AD97-84E2AAA2E18BQ30894015-7840AD60-47F3-4D66-8902-C41B7F107DDAQ30962205-135AFB58-0023-486D-90AF-9A3586A897A7Q30976208-08870263-EA1D-4159-97C0-E4CF708CBACAQ30976679-52755248-953F-460B-83C2-529A9DF6345CQ31141964-141F0AD8-9BD6-4A2B-BE34-60C8FE3A69DFQ33730064-E4062EDF-111A-4EED-81C0-898A7F45D416Q33736389-C6065113-A2F5-4157-B092-74C8874A97D2Q33783790-69C6A1A7-DA05-4565-A447-5B27439983B1Q33909533-6988A437-AA44-4EAF-B9CD-863D43F5BB52Q34505624-9FC66FFE-3AA8-4B0A-A1E9-FFFB7738F8D4Q34537554-E80BBA17-6DC1-44ED-A6EC-028C7214A262Q35881937-819BE5B0-5C4D-4A9D-A76E-FAA98481D3BFQ35999556-29D99B99-30AD-41DD-B378-4241B5803707Q36105031-D4B7DA1F-394E-406D-97E0-2DC5DAEC4EA6Q36244302-8A9D6BFC-200C-46F5-8213-F77404AE7CEEQ36246760-98E6E982-E2CD-4E1E-B80D-F5E2CC773B52Q36296124-B16B3514-0997-4AED-B0EE-D589446FF817Q36309747-407AB783-06E3-45C4-81A0-5CBC8E1F5E51Q37592773-C0B43178-FC6F-4807-9727-FEE81CABE191Q37694048-7BA430FD-1617-476D-B55F-DFD42293D7CCQ37729589-746E4EDF-F78B-4BCD-95E8-EE7B9BA5D220Q37740830-F006AF7C-8F2A-49F5-97FA-08261C581EC7Q38390563-1243B9AE-C018-44CD-A172-316989CA5AC4Q38846929-59D7F0E9-6027-4642-AFA1-D51AD1746BF9Q41403618-CD60B01C-1A8F-4DFE-A8E0-06BD469F74EDQ44168829-83A62F6E-131A-4453-8601-FDCC382A8857Q47238075-0083D1A3-C452-4764-A189-BBA9F92CFEEBQ48105145-DBFF8908-596F-4A0D-9E0F-5C0DEA630B6CQ50043813-BE1809DF-21F1-4C9B-8F8F-29F442216EF5Q51146762-26DDFDDB-8EAB-49D9-A71F-C9EBBF77E82AQ52660161-5272ACF4-89E2-4D92-ACEA-7C5844F2CA79Q54976016-2DF58061-97A5-4682-A2B7-51436FF46F6DQ56344505-494E971E-0C6E-4F6F-8FE6-DF83D64DAE9E
P2860
The effect of temperature on Anopheles mosquito population dynamics and the potential for malaria transmission.
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年学术文章
@wuu
2013年学术文章
@zh-cn
2013年学术文章
@zh-hans
2013年学术文章
@zh-my
2013年学术文章
@zh-sg
2013年學術文章
@yue
2013年學術文章
@zh
2013年學術文章
@zh-hant
name
The effect of temperature on A ...... tial for malaria transmission.
@en
The effect of temperature on A ...... tial for malaria transmission.
@nl
type
label
The effect of temperature on A ...... tial for malaria transmission.
@en
The effect of temperature on A ...... tial for malaria transmission.
@nl
prefLabel
The effect of temperature on A ...... tial for malaria transmission.
@en
The effect of temperature on A ...... tial for malaria transmission.
@nl
P2093
P2860
P1433
P1476
The effect of temperature on A ...... tial for malaria transmission.
@en
P2093
Krijn P Paaijmans
Lindsay M Beck-Johnson
Matthew B Thomas
William A Nelson
P2860
P304
P356
10.1371/JOURNAL.PONE.0079276
P407
P577
2013-11-14T00:00:00Z