FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3084553732> ?p ?o ?g. }

• W3084553732 endingPage "e0238815" @default.
• W3084553732 startingPage "e0238815" @default.
• W3084553732 abstract "The Philippines confirmed its first epidemic of Highly Pathogenic Avian Influenza (HPAI) on August 11, 2017. It ended in November of 2017. Despite the successful management of the epidemic, reemergence is a continuous threat. The aim of this study was to conduct a mathematical model to assess the spatial transmission of HPAI among poultry farms in Central Luzon. Different control strategies and the current government protocol of 1 km radius pre-emptive culling (PEC) from infected farms were evaluated. The alternative strategies include 0.5km PEC, 1.5km PEC, 2 km PEC, 2.5 km PEC, and 3 km PEC, no pre-emptive culling (NPEC). The NPEC scenario was further modeled with a time of government notification set at 24hours, 48 hours, and 72 hours after the detection. Disease spread scenarios under each strategy were generated using an SEIR (susceptible-exposed-infectious-removed) stochastic model. A spatial transmission kernel was calculated and used to represent all potential routes of infection between farms. We assumed that the latent period occurs between 1-2 days, disease detection at 5-7 days post-infection, notification of authorities at 5-7 days post-detection and start of culling at 1-3 days post notification. The epidemic scenarios were compared based on the number of infected farms, the total number of culled farms, and the duration of the epidemic. Our results revealed that the current protocol is the most appropriate option compared with the other alternative interventions considered among farms with reproductive ratio (Ri) > 1. Shortening the culling radius to 0.5 km increased the duration of the epidemic. Further increase in the PEC zone decreased the duration of the epidemic but may not justify the increased number of farms to be culled. Nonetheless, the no-pre-emptive culling (NPEC) strategy can be an effective alternative to the current protocol if farm managers inform the government immediately within 24 hours of observation of the presence of HPAI in their farms. Moreover, if notification is made on days 1-3 after the detection, the scale and length of the outbreak have been significantly reduced. In conclusion, this study provided a comparison of various control measures for confronting the spread of HPAI infection using the simulation model. Policy makers can use this information to enhance the effectiveness of the current control strategy." @default.
• W3084553732 created "2020-09-21" @default.
• W3084553732 creator A5016266491 @default.
• W3084553732 creator A5042829606 @default.
• W3084553732 creator A5047334222 @default.
• W3084553732 creator A5078446606 @default.
• W3084553732 creator A5086094345 @default.
• W3084553732 creator A5057571973 @default.
• W3084553732 creator A5091343533 @default.
• W3084553732 date "2020-09-10" @default.
• W3084553732 modified "2023-10-09" @default.
• W3084553732 title "Evaluation of strategies using simulation model to control a potential outbreak of highly pathogenic avian influenza among poultry farms in Central Luzon, Philippines" @default.
• W3084553732 cites W1496073738 @default.
• W3084553732 cites W1961602420 @default.
• W3084553732 cites W1969093861 @default.
• W3084553732 cites W1979916871 @default.
• W3084553732 cites W1983966548 @default.
• W3084553732 cites W1984841045 @default.
• W3084553732 cites W1988827926 @default.
• W3084553732 cites W1989817043 @default.
• W3084553732 cites W1994937723 @default.
• W3084553732 cites W2007675821 @default.
• W3084553732 cites W2009678335 @default.
• W3084553732 cites W2015735227 @default.
• W3084553732 cites W2026511353 @default.
• W3084553732 cites W2029373497 @default.
• W3084553732 cites W2029758788 @default.
• W3084553732 cites W2032206789 @default.
• W3084553732 cites W2039850897 @default.
• W3084553732 cites W2044060078 @default.
• W3084553732 cites W2046234133 @default.
• W3084553732 cites W2047418006 @default.
• W3084553732 cites W2047952247 @default.
• W3084553732 cites W2050033116 @default.
• W3084553732 cites W2051646218 @default.
• W3084553732 cites W2052712768 @default.
• W3084553732 cites W2052871036 @default.
• W3084553732 cites W2054377449 @default.
• W3084553732 cites W2054377897 @default.
• W3084553732 cites W2058963141 @default.
• W3084553732 cites W2067508944 @default.
• W3084553732 cites W2074064260 @default.
• W3084553732 cites W2078048396 @default.
• W3084553732 cites W2078668343 @default.
• W3084553732 cites W2086215158 @default.
• W3084553732 cites W2089171200 @default.
• W3084553732 cites W2094002662 @default.
• W3084553732 cites W2095570416 @default.
• W3084553732 cites W2101306708 @default.
• W3084553732 cites W2114736649 @default.
• W3084553732 cites W2116670929 @default.
• W3084553732 cites W2117147349 @default.
• W3084553732 cites W2117619263 @default.
• W3084553732 cites W2121883410 @default.
• W3084553732 cites W2123446581 @default.
• W3084553732 cites W2125930129 @default.
• W3084553732 cites W2136455940 @default.
• W3084553732 cites W2136998030 @default.
• W3084553732 cites W2137933962 @default.
• W3084553732 cites W2138432936 @default.
• W3084553732 cites W2148812002 @default.
• W3084553732 cites W2151421138 @default.
• W3084553732 cites W2153455151 @default.
• W3084553732 cites W2153594566 @default.
• W3084553732 cites W2155907077 @default.
• W3084553732 cites W2179727412 @default.
• W3084553732 cites W2891290974 @default.
• W3084553732 cites W2950219540 @default.
• W3084553732 cites W4246100348 @default.
• W3084553732 cites W579633810 @default.
• W3084553732 doi "https://doi.org/10.1371/journal.pone.0238815" @default.
• W3084553732 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/7482972" @default.
• W3084553732 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/32913363" @default.
• W3084553732 hasPublicationYear "2020" @default.
• W3084553732 type Work @default.
• W3084553732 sameAs 3084553732 @default.
• W3084553732 citedByCount "4" @default.
• W3084553732 countsByYear W30845537322021 @default.
• W3084553732 countsByYear W30845537322023 @default.
• W3084553732 crossrefType "journal-article" @default.
• W3084553732 hasAuthorship W3084553732A5016266491 @default.
• W3084553732 hasAuthorship W3084553732A5042829606 @default.
• W3084553732 hasAuthorship W3084553732A5047334222 @default.
• W3084553732 hasAuthorship W3084553732A5057571973 @default.
• W3084553732 hasAuthorship W3084553732A5078446606 @default.
• W3084553732 hasAuthorship W3084553732A5086094345 @default.
• W3084553732 hasAuthorship W3084553732A5091343533 @default.
• W3084553732 hasBestOaLocation W30845537321 @default.
• W3084553732 hasConcept C116675565 @default.
• W3084553732 hasConcept C159047783 @default.
• W3084553732 hasConcept C18903297 @default.
• W3084553732 hasConcept C194775826 @default.
• W3084553732 hasConcept C205649164 @default.
• W3084553732 hasConcept C2522874641 @default.
• W3084553732 hasConcept C2781368420 @default.
• W3084553732 hasConcept C3019819676 @default.
• W3084553732 hasConcept C41008148 @default.
• W3084553732 hasConcept C42972112 @default.

• next