The construction of next-generation matrices for compartmental epidemic models
about
Transmission dynamics of the recently-identified BYD virus causing duck egg-drop syndromeThe interplay of vaccination and vector control on small dengue networksThe context of host competence: a role for plasticity in host-parasite dynamicsImplications of Heterogeneous Biting Exposure and Animal Hosts on Trypanosomiasis brucei gambiense Transmission and ControlStructure in the variability of the basic reproductive number (R0) for Zika epidemics in the Pacific islandsComparative 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 zoonosisEvolutionary analysis of human immunodeficiency virus type 1 therapies based on conditionally replicating vectorsTransmission potential of chikungunya virus and control measures: the case of Italy.The evolution of sex-specific virulence in infectious diseasesThe impact of control strategies and behavioural changes on the elimination of Ebola from Lofa County, LiberiaWhat is a vector?Modeling optimal treatment strategies in a heterogeneous mixing model.Characterizing the reproduction number of epidemics with early subexponential growth dynamics.Estimating reproduction numbers for adults and children from case data.The impact of stratified immunity on the transmission dynamics of influenza.Transmission characteristics of the 2009 H1N1 influenza pandemic: comparison of 8 Southern hemisphere countries.Effect of vaccines and antivirals during the major 2009 A(H1N1) pandemic wave in Norway--and the influence of vaccination timing.The time required to estimate the case fatality ratio of influenza using only the tip of an iceberg: joint estimation of the virulence and the transmission potentialModelling the effects of seasonality and socioeconomic impact on the transmission of rift valley Fever virus.Estimating the value of containment strategies in delaying the arrival time of an influenza pandemic: a case study of travel restriction and patient isolation.Age-specific contacts and travel patterns in the spatial spread of 2009 H1N1 influenza pandemic.Possible changes in the transmissibility of trachoma following MDA and transmission reduction: implications for the GET2020 goals.Integrated mapping of establishment risk for emerging vector-borne infections: a case study of canine leishmaniasis in southwest FranceModeling Chagas Disease at Population Level to Explain Venezuela's Real Data.Rabies Vaccination Targets for Stray Dog Populations.Pattern analysis of schistosomiasis prevalence by exploring predictive modeling in Jiangling County, Hubei Province, P.R. ChinaModeling Nosocomial Infections of Methicillin-Resistant Staphylococcus aureus with Environment Contamination.Challenges in developing methods for quantifying the effects of weather and climate on water-associated diseases: A systematic reviewAnalysis of rabies in China: transmission dynamics and control.Invasion and persistence of infectious agents in fragmented host populationsEfficacy of infection control interventions in reducing the spread of multidrug-resistant organisms in the hospital setting.Modelling transmission of vector-borne pathogens shows complex dynamics when vector feeding sites are limited.Why the proportion of transmission during early-stage HIV infection does not predict the long-term impact of treatment on HIV incidenceTwo-host, two-vector basic reproduction ratio (R(0)) for bluetongue.Identifying transmission cycles at the human-animal interface: the role of animal reservoirs in maintaining gambiense human african trypanosomiasisPhylodynamic analysis of the emergence and epidemiological impact of transmissible defective dengue virusesA mathematical model of chikungunya dynamics and control: the major epidemic on Réunion Island.The impact of model building on the transmission dynamics under vaccination: observable (symptom-based) versus unobservable (contagiousness-dependent) approaches.How effective is integrated vector management against malaria and lymphatic filariasis where the diseases are transmitted by the same vector?
P2860
Q21134857-E51A1D2D-EA64-4658-8917-437E90930AB6Q26252266-E591687A-492A-4CF9-856C-8295DF895806Q27026799-361F1C6F-9EC0-4558-A25D-1FBA04A11629Q27317424-F9E2E0CB-1674-4C9E-A756-16EF2D8E60E9Q27928568-7D1BF670-5762-40B2-B12D-6A2F97A76848Q27980447-015F288D-4EE0-4B0E-A97B-D7A613EA40C1Q28071740-A48C309E-FCC7-4F0F-92CC-C99EB6BBD8ECQ28484825-70D7F90D-B82A-462C-AFB7-A39E243579A5Q28656275-97E61E78-25D9-4021-9F09-B6C521B292F3Q28733461-3ED199DF-CC56-4730-87AA-0CCF22BDFBDAQ30251097-17168ED7-64A4-409C-9C69-BAE72784903DQ30252972-D9B8C7F0-5E04-4B3A-B2F9-743AD50957D6Q30381903-3418FD1B-4CE4-4B24-83EC-2110C4E792B5Q30393759-8B4A65B4-5483-42C0-B1F2-51962EF1EB56Q30400088-7391F9D4-1945-4111-B367-EBF917EA0C15Q30400970-D528DA40-06E3-4782-864B-4B42B22C9617Q30406967-6B204384-EE05-4375-9A22-004825D87717Q30411896-3CE3FE85-E22F-4D23-88B8-31098F52529FQ30417409-BC02B32A-AF13-4E76-8B8B-9D9CB856B305Q30421040-C58DD9DB-CEF8-43B5-A8C0-FD6CECCFCE3FQ30421876-D789D6F3-2EBB-40F7-B629-25E6682E1C3EQ30429413-AB369A5D-C945-41BB-8456-D5AAEE531BBDQ30670495-C999FA91-9E48-4594-A4FC-E31BBE4D026BQ31029656-138B72A8-4DE3-439C-992C-A535BF71919EQ31050769-8AE98C80-E85D-43CC-B090-B599C2013EB1Q33559163-D9264190-AA2D-4F18-AD6B-1F6D7968BB37Q33608710-2EFD8A78-8B8A-4D5E-9B53-268E1BB56B87Q33670262-2CC2EDEF-4D88-400E-9AB7-03A7D1C03F07Q33825700-1B2C5EEC-76B7-4276-BCFC-BFA38ED1AE7DQ33971052-E6DB7092-FEA3-44A4-BA52-FA2F6E4E3CEEQ34042777-00107B72-E7F1-4D77-ADB5-7AAB82C86549Q34169916-E873237B-D076-49FD-B9EC-266411ADFD1FQ34270968-9841809C-F79E-4D87-AF1F-492755101FB6Q34526461-FA78A5E2-10F8-45F2-8A55-9EA11D8A0744Q34544713-BDF71694-8A2A-4EBC-86C9-7D6498EB3CA1Q34557971-ECF698F9-F372-42C5-A114-A012EB6FC46CQ34611164-0E58BD5B-19F9-4204-A7D7-BFABC00AF21AQ34647827-C8A0FC3E-1928-4FB4-9BA4-770163DD04DDQ34675056-4A2EE04A-C25C-46CE-A7F3-6B9C7B6E4EBEQ34679880-91487F7B-BA78-4DD5-8118-1F5588677996
P2860
The construction of next-generation matrices for compartmental epidemic models
description
2009 nî lūn-bûn
@nan
2009 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
name
The construction of next-generation matrices for compartmental epidemic models
@ast
The construction of next-generation matrices for compartmental epidemic models
@en
type
label
The construction of next-generation matrices for compartmental epidemic models
@ast
The construction of next-generation matrices for compartmental epidemic models
@en
prefLabel
The construction of next-generation matrices for compartmental epidemic models
@ast
The construction of next-generation matrices for compartmental epidemic models
@en
P2860
P356
P1476
The construction of next-generation matrices for compartmental epidemic models
@en
P2093
M G Roberts
O Diekmann
P2860
P304
P356
10.1098/RSIF.2009.0386
P577
2009-11-05T00:00:00Z