Exploiting the potential of vector control for disease prevention
about
Global status of DDT and its alternatives for use in vector control to prevent diseaseIntegrating vector control across diseasesRelationship between insecticide resistance and kdr mutations in the dengue vector Aedes aegypti in Southern ChinaThe Emergence of Zika Virus as a Global Health Security Threat: A Review and a Consensus Statement of the INDUSEM Joint working Group (JWG)Malaria vectors in Angola: distribution of species and molecular forms of the Anopheles gambiae complex, their pyrethroid insecticide knockdown resistance (kdr) status and Plasmodium falciparum sporozoite rates.Expanding Integrated Vector Management to promote healthy environmentsAssessing Interventions to Manage West Nile Virus Using Multi-Criteria Decision Analysis with Risk Scenarios.Attracting, trapping and killing disease-transmitting mosquitoes using odor-baited stations -The Ifakara Odor-Baited StationsAssessing the effects of Aedes aegypti kdr mutations on pyrethroid resistance and its fitness costModelling co-infection with malaria and lymphatic filariasisEffect of leaf type and pesticide exposure on abundance of bacterial taxa in mosquito larval habitatsInsensitivity to the spatial repellent action of transfluthrin in Aedes aegypti: a heritable trait associated with decreased insecticide susceptibilityEcology: a prerequisite for malaria elimination and eradicationThe Fleas (Siphonaptera) in Iran: Diversity, Host Range, and Medical ImportanceInstitutional evolution of a community-based programme for malaria control through larval source management in Dar es Salaam, United Republic of Tanzania.Sustainable control of water-related infectious diseases: a review and proposal for interdisciplinary health-based systems research.Diversity of mosquitoes and the aquatic insects associated with their oviposition sites along the Pacific coast of MexicoVector control programs in Saint Johns County, Florida and Guayas, Ecuador: successes and barriers to integrated vector management.Community-based surveillance of malaria vector larval habitats: a baseline study in urban Dar es Salaam, TanzaniaMulti-locus assortment (MLA) for transgene dispersal and elimination in mosquito populations.Achieving high coverage of larval-stage mosquito surveillance: challenges for a community-based mosquito control programme in urban Dar es Salaam, TanzaniaAn experimental test of the effects of behavioral and immunological defenses against vectors: do they interact to protect birds from blood parasites?Potential for the Anopheles gambiae densonucleosis virus to act as an "evolution-proof" biopesticideAll that glisters is not gold: sampling-process uncertainty in disease-vector surveys with false-negative and false-positive detectionsEffects of Cu/Zn superoxide dismutase (sod1) genotype and genetic background on growth, reproduction and defense in Biomphalaria glabrata.Toward integrated opisthorchiasis control in northeast Thailand: the Lawa project.Vectorial status and insecticide resistance of Anopheles funestus from a sugar estate in southern MozambiqueVector research addressing country control needsMapping, bayesian geostatistical analysis and spatial prediction of lymphatic filariasis prevalence in Africa.Field efficacy of Vectobac GR as a mosquito larvicide for the control of anopheline and culicine mosquitoes in natural habitats in Benin, West AfricaDevelopment and assessment of plant-based synthetic odor baits for surveillance and control of malaria vectors.Considerations for the use of human participants in vector biology research: a tool for investigators and regulators.Community-owned resource persons for malaria vector control: enabling factors and challenges in an operational programme in Dar es Salaam, United Republic of Tanzania.The field evaluation of a push-pull system to control malaria vectors in northern Belize, Central America.Larval source management for malaria control in Africa: myths and reality.Integrated vector management for malaria control in Uganda: knowledge, perceptions and policy developmentGenome-Wide Scan and Test of Candidate Genes in the Snail Biomphalaria glabrata Reveal New Locus Influencing Resistance to Schistosoma mansoni.An exploratory study of community factors relevant for participatory malaria control on Rusinga Island, western Kenya.Global trends in the use of insecticides to control vector-borne diseasesIntegrating Transgenic Vector Manipulation with Clinical Interventions to Manage Vector-Borne Diseases.
P2860
Q21032455-6446F650-742C-430E-B688-4922AD92B7F5Q22000634-B904FDE9-8437-4CA0-BF9B-0151630022C8Q24288854-D2B5104E-544E-4E6B-9009-88E406202AEFQ24570666-8A458129-1DE5-4ED7-AA0A-0BCB8D11DE60Q25255949-0BED4741-9602-43A2-800E-CC503C1DA894Q26991433-093361DE-D179-47CE-9CF5-B4FEEF86737EQ27468896-ACFA9F24-891D-4178-AB81-1FFFAD3CC4F3Q27491251-9C14BD47-1CA5-4E30-8FA8-69340EBB14EAQ28486078-CF9E0509-73E4-4689-961D-9D25DB056AD7Q28533871-CB932B00-B44D-4616-A219-16133CF3880BQ28535078-71B18C4C-0EC4-45BB-A86F-5A8AB5128B44Q28546474-729E7440-A108-497E-B8C2-1C14CE723450Q28749981-DC3F2458-F512-49C1-9631-86B05466C668Q28818638-4DE8002A-1B62-45B5-8736-4470177F5C04Q30391296-91C405E3-28D0-4478-9260-2FBFD325F831Q30397321-BFFB0EB7-6F09-4165-ACF2-4F662732CC15Q30739440-7F3F971B-B1AA-4B9E-AB41-1B887FAD653EQ31170356-71C26A2A-2888-42AD-8B5B-FE2F6F28B85CQ33246846-A0CAC93D-7971-4D80-AE72-C6FCB0EF52D8Q33463400-D41A31B7-40A8-45B2-A088-31D4C40E7843Q33590195-1BCE6C1A-6002-454E-9BFD-AD79A35BA758Q33828533-EE853003-1950-43BE-9F97-7AB203D48AD2Q33964177-BE728B71-0FB3-4DF2-A1CA-7296C8B8EC14Q34214829-94D20A7A-1D5A-492B-AB56-E8A746781FBFQ34314514-1C8CAA01-3D9A-4482-A51D-7B677B1C3649Q34432763-570F8424-8773-4E39-841A-5BD3F60EA342Q34633589-5AA9605F-30A1-4BDD-AC7D-769E7D4D57AAQ34874378-3E5D1ABD-D68D-4ECB-B603-9C2AFF84F380Q34949936-3581DF51-2E82-4CDC-A936-A3CE926BFFE0Q35088305-33907602-7E38-4C9A-AEBD-DD3A41D6D984Q35108165-3B75466C-453D-4AE1-89F9-C73764ECF06BQ35121975-819160F9-6C77-48D2-B960-54579725A79FQ35477932-8E84D9B8-88CB-490A-A542-0BC5CE1C27DBQ35588524-CAAA5DC1-6D01-41C8-851C-78B3D3D1DAE2Q35739767-729A4D23-45EF-449D-89CC-0BE1504711AAQ35760997-1DDBFE85-0672-42E8-8C67-D4AF9F327FC1Q35776000-946261F2-9079-4BAC-9CCF-621ACF07A1F7Q35799737-5DE26ED8-DBEA-4562-B854-46CA14E307C7Q35920268-79F01C1D-E023-42C9-BA8F-7A814DE830BAQ35952111-0C7CE50D-62AA-4C35-8F3E-007989E17805
P2860
Exploiting the potential of vector control for disease prevention
description
2005 nî lūn-bûn
@nan
2005 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2005 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
2005年の論文
@ja
2005年論文
@yue
2005年論文
@zh-hant
2005年論文
@zh-hk
2005年論文
@zh-mo
2005年論文
@zh-tw
2005年论文
@wuu
name
Exploiting the potential of vector control for disease prevention
@ast
Exploiting the potential of vector control for disease prevention
@en
Exploiting the potential of vector control for disease prevention
@nl
type
label
Exploiting the potential of vector control for disease prevention
@ast
Exploiting the potential of vector control for disease prevention
@en
Exploiting the potential of vector control for disease prevention
@nl
prefLabel
Exploiting the potential of vector control for disease prevention
@ast
Exploiting the potential of vector control for disease prevention
@en
Exploiting the potential of vector control for disease prevention
@nl
P2093
P3181
P1476
Exploiting the potential of vector control for disease prevention
@en
P2093
Kindhauser M
P304
P3181
P356
/S0042-96862005001200017
P407
P577
2005-12-01T00:00:00Z