Ross, macdonald, and a theory for the dynamics and control of mosquito-transmitted pathogens.
about
Quantifying the Epidemiological Impact of Vector Control on DengueFighting Arbovirus Transmission: Natural and Engineered Control of Vector Competence in Aedes MosquitoesModel-based projections of Zika virus infections in childbearing women in the AmericasThe interplay of vaccination and vector control on small dengue networksLeading indicators of mosquito-borne disease eliminationPotential Risk of Dengue and Chikungunya Outbreaks in Northern Italy Based on a Population Model of Aedes albopictus (Diptera: Culicidae)Differential Effects of Azithromycin, Doxycycline, and Cotrimoxazole in Ingested Blood on the Vectorial Capacity of Malaria MosquitoesInferring the Spatio-temporal Patterns of Dengue Transmission from Surveillance Data in Guangzhou, ChinaAssessing potential countermeasures against the dengue epidemic in non-tropical urban citiesManifold habitat effects on the prevalence and diversity of avian blood parasitesSeasonality of Plasmodium falciparum transmission: a systematic reviewA critical assessment of vector control for dengue preventionMathematical modeling of infectious disease dynamicssiRNA-Mediated Silencing of doublesex during Female Development of the Dengue Vector Mosquito Aedes aegyptiBiodiversity can help prevent malaria outbreaks in tropical forestsBluetongue disease risk assessment based on observed and projected Culicoides obsoletus spp. vector densitiesDengueME: A Tool for the Modeling and Simulation of Dengue Spatiotemporal DynamicsGenome Investigations of Vector Competence in Aedes aegypti to Inform Novel Arbovirus Disease Control ApproachesThe Impact of Heterogeneity and Awareness in Modeling Epidemic Spreading on Multiplex NetworksPolyphenol-Rich Diets Exacerbate AMPK-Mediated Autophagy, Decreasing Proliferation of Mosquito Midgut Microbiota, and Extending Vector LifespanComparative Analysis of Dengue and Zika Outbreaks Reveals Differences by Setting and VirusPlasmodium knowlesi transmission: integrating quantitative approaches from epidemiology and ecology to understand malaria as a zoonosisClimate, environmental and socio-economic change: weighing up the balance in vector-borne disease transmissionMalaria's missing number: calculating the human component of R0 by a within-host mechanistic model of Plasmodium falciparum infection and transmissionThe interplay of intrinsic and extrinsic bounded noises in biomolecular networksVectorial capacity of Aedes aegypti for dengue virus type 2 is reduced with co-infection of Metarhizium anisopliaeStrategies for understanding and reducing the Plasmodium vivax and Plasmodium ovale hypnozoite reservoir in Papua New Guinean children: a randomised placebo-controlled trial and mathematical modelGlobal risk model for vector-borne transmission of Zika virus reveals the role of El Niño 2015Mosquito-Disseminated Insecticide for Citywide Vector Control and Its Potential to Block Arbovirus Epidemics: Entomological Observations and Modeling Results from Amazonian BrazilGlobal temperature constraints on Aedes aegypti and Ae. albopictus persistence and competence for dengue virus transmission.Modelling adult Aedes aegypti and Aedes albopictus survival at different temperatures in laboratory and field settingsMicro-epidemiological structuring of Plasmodium falciparum parasite populations in regions with varying transmission intensities in AfricaImplications of temperature variation for malaria parasite development across AfricaA global assembly of adult female mosquito mark-release-recapture data to inform the control of mosquito-borne pathogens.Climate 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.Outdoor and indoor monitoring of livestock-associated Culicoides spp. to assess vector-free periods and disease risks.Made-to-measure malaria vector control strategies: rational design based on insecticide properties and coverage of blood resources for mosquitoes.Simulating within-vector generation of the malaria parasite diversity.Integrative modelling for One Health: pattern, process and participation.
P2860
Q24278786-3776A2D0-C2B9-4B0B-9857-FDB2A357EE3FQ24701744-BDFDCCEC-42E7-46FA-9450-5E830D6E3CA8Q26250276-67392139-0BC3-4796-868C-6108026AD459Q26252266-DF581507-F396-4CA1-B423-A1AF77D8F2C7Q26314412-481AB741-11F7-4575-8561-A625933F06A2Q26314617-F06A76E9-D599-4F25-B822-2152583A26F9Q26315272-B133E2A4-FFA0-4A14-AF1C-DC786C0B3C5DQ26315504-C1007AC0-ED28-4BEF-8ECE-26F3C5912A41Q26315564-7767911A-677B-4799-BE57-93A5E658BA05Q26770350-91ECB396-6013-40B9-BDB9-B5C4619223C6Q26787055-B7DEF0F6-937B-49BF-99B9-EF49B828DBB5Q26824776-726AC5AD-0347-4C5D-B0E3-F108DDF920A5Q27003978-5D4E88DD-3BBC-46A7-A05B-5B21F578FCAAQ27303902-9EB6C02B-3C79-4535-8041-1FE8CDAE0BDBQ27305238-C2D8AF3B-2B7B-44CF-8BDC-29086ADB9AA7Q27330414-7EEA2D1E-930A-4538-ACF9-47487C117DBEQ27468688-2413BC3A-F371-4F87-8BC6-759CB8324825Q27787796-93F675BC-5358-4874-81E1-60CAFDA7C88FQ27927992-D65D5A74-4882-4DC8-AB27-4C8BF0C246F9Q27928027-00A1EAEB-1F81-472D-9B4F-B03D431C43EFQ27980447-6BA699B1-D646-4658-A71E-34A326EDDB2EQ28071740-1558845D-3AC8-437B-8EC0-E6C74BF59985Q28087411-E60A7658-140D-4513-BC4E-D1B57BBEA89FQ28486274-FEE44CB1-21AC-4A16-80D7-B5DF60433F33Q28486543-DD073DCE-2B9F-41B4-8B30-402F9186283BQ28487738-02BF8E0F-1BF3-4AD6-9DAB-9541297021EFQ28550515-3A50ACB3-436F-4FC1-9D8B-343A381CBC21Q28566466-58236188-1695-4832-A66D-953553A13530Q28595151-20A7AF78-A490-4AC0-9896-3C5B0C33094AQ28656167-A3FA170B-DFF5-4B90-8776-C2011D31B4EEQ29192850-E3989E99-5451-4E0A-B06A-6A40CE640185Q29464553-8D4A19D9-79C6-4007-B302-1828F8A9FB49Q30590474-67D0BE77-9540-4C70-B76C-BEA9C170A306Q30832268-375FA7DE-F902-4947-BBB7-5EB372432DEAQ30894015-43678851-BC88-4C59-98A3-13DBB9CCCE66Q30962205-18B2C2AC-4EC2-4E65-B61F-ADB0D9350DE4Q31105432-A56AC3DB-426B-4AE5-B96C-CD8542A43E03Q33697102-C1D5AC31-EE62-4CD9-84E9-7CF3E3EDCEFDQ33714470-7A115132-91CF-4DFE-A853-F86E1C798CA0Q33790972-AB77A066-40DA-4811-BBEF-B841B321E0D2
P2860
Ross, macdonald, and a theory for the dynamics and control of mosquito-transmitted pathogens.
description
2012 nî lūn-bûn
@nan
2012 թուականի Ապրիլին հրատարակուած գիտական յօդուած
@hyw
2012 թվականի ապրիլին հրատարակված գիտական հոդված
@hy
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
name
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@ast
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@en
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@nl
type
label
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@ast
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@en
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@nl
prefLabel
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@ast
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@en
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@nl
P2860
P50
P1433
P1476
Ross, macdonald, and a theory ...... osquito-transmitted pathogens.
@en
P2093
F Ellis McKenzie
P2860
P304
P356
10.1371/JOURNAL.PPAT.1002588
P577
2012-04-05T00:00:00Z