about
Statics and dynamics of malaria infection in Anopheles mosquitoesThe risk of a mosquito-borne infection in a heterogeneous environmentModeling and biological control of mosquitoesPlasmodium knowlesi transmission: integrating quantitative approaches from epidemiology and ecology to understand malaria as a zoonosisMathematical models for a new era of malaria eradicationA generic schema and data collection forms applicable to diverse entomological studies of mosquitoesHost control of malaria infections: constraints on immune and erythropoeitic response kineticsThe impact of human reservoir of malaria at a community-level on individual malaria occurrence in a low malaria transmission setting along the Thai-Myanmar border.Interpreting malaria age-prevalence and incidence curves: a simulation study of the effects of different types of heterogeneity.Ross, macdonald, and a theory for the dynamics and control of mosquito-transmitted pathogens.The role of mathematical modelling in guiding the science and economics of malaria eliminationRaised temperatures over the Kericho tea estates: revisiting the climate in the East African highlands malaria debate.ANOSPEX: a stochastic, spatially explicit model for studying Anopheles metapopulation dynamics.The distribution of incubation and relapse times in experimental human infections with the malaria parasite Plasmodium vivax.Parameterization and sensitivity analysis of a complex simulation model for mosquito population dynamics, dengue transmission, and their control.Adult vector control, mosquito ecology and malaria transmissionSpatial heterogeneity, host movement and mosquito-borne disease transmissionThe role of mathematical modeling in evidence-based malaria control.Application of the lumped age-class technique to studying the dynamics of malaria-mosquito-human interactions.A systems science perspective and transdisciplinary models for food and nutrition securityA biologic basis for integrated malaria controlA regional-scale, high resolution dynamical malaria model that accounts for population density, climate and surface hydrology.Modelling malaria pathogenesis.The transmission potential of Rift Valley fever virus among livestock in the Netherlands: a modelling study.On the delayed Ross-Macdonald model for malaria transmission.Optimally timing primaquine treatment to reduce Plasmodium falciparum transmission in low endemicity Thai-Myanmar border populationsMan bites mosquito: understanding the contribution of human movement to vector-borne disease dynamics.Recasting the theory of mosquito-borne pathogen transmission dynamics and control.Complex dynamics and stability of resistance to antimalarial drugs.A realistic host-vector transmission model for describing malaria prevalence pattern.Using modelling to assess the risk of malarial infection during the dry season, on a local scale in an endemic area of rural Burkina Faso.The portfolio effect cushions mosquito populations and malaria transmission against vector control interventions
P2860
Q24802158-91896A5C-8219-4837-B77F-39545DE78E4BQ24804178-FDDE8773-F92D-406B-8887-6E89E5E670A8Q27490289-0635C975-F033-4ED8-8C69-2D0C3C9911FEQ28071740-FFA42CC4-8257-4DB1-AB01-9D6B7E312422Q28474133-065126DA-74E6-46F1-9BFC-1133BCD667EAQ28601877-D351F978-390F-4A95-8C61-7E4A9CC13CD2Q33363069-B3E9E4CC-EFA3-4995-B9E4-1E837206EF85Q33922065-95F4CD1C-8E4D-4525-A16C-C08D6867BB0CQ33926064-32F23B11-0EDB-4C48-BE82-251882EE2DABQ34229599-D7D4CEE3-9AC6-4D3A-8CA8-76B6254D5CD4Q34415327-1640B986-DABA-4BD8-91F6-7F07D72F70B9Q34541159-891B7341-552C-4863-A846-0C45EE641778Q34826704-BBB71093-F487-42B4-AC92-1CA4A52A583EQ34869961-58EF7F0F-37AF-40F1-A6D3-D543DB8EAF15Q35131386-0C90BB89-865A-4AB7-BAB4-E22CA3ABA81FQ35171798-2A5920EC-6103-475B-8083-7D55D98FFB16Q35648336-CA480136-BEA1-4A64-AB3F-1B822DA977C1Q35872642-33EB6E43-CAD6-4369-9E7B-82AA6CF4BFA6Q35982765-6C1AE831-96D7-4868-8D87-A48B56872F27Q36140464-AB1440E4-4D10-49CD-BEBA-96C61C09EFC9Q36824086-931BE544-5338-4A02-812B-F36291BE7287Q36851778-1578C564-CA0D-4518-84DC-1A97C7611383Q37035491-4B10216A-A053-4805-83FC-F39427A6B10AQ37071493-E54FF295-3097-44E1-B88B-C7634FDD67F1Q37169984-DBB740DC-6C04-400D-925B-6C07D4858B99Q37284075-E1B40F54-A31A-4DC5-9174-6AEA3C68FBAEQ37307596-98BA9229-5C96-46A5-B505-1ECFEA973728Q37635100-9D753006-E0D9-46D9-9DF1-81898523A55BQ39055325-76EF1BAF-780B-4668-87B1-5D9FCCE082DBQ39209719-51872B7F-C55F-449A-94EB-C2C182804FC6Q39799993-CD73F538-D24E-4370-B6C6-7DC7C028025CQ56344956-D2B80525-B2C1-45B4-B519-14C943097CC1
P2860
description
2000 nî lūn-bûn
@nan
2000 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2000 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
2000年の論文
@ja
2000年論文
@yue
2000年論文
@zh-hant
2000年論文
@zh-hk
2000年論文
@zh-mo
2000年論文
@zh-tw
2000年论文
@wuu
name
Why model malaria?
@ast
Why model malaria?
@en
Why model malaria?
@nl
type
label
Why model malaria?
@ast
Why model malaria?
@en
Why model malaria?
@nl
prefLabel
Why model malaria?
@ast
Why model malaria?
@en
Why model malaria?
@nl
P1476
Why model malaria?
@en
P2093
F E McKenzie
P304
P356
10.1016/S0169-4758(00)01789-0
P577
2000-12-01T00:00:00Z