Prediction of the spread of highly pathogenic avian influenza using a multifactor network: Part 1 – Development and application of computational fluid dynamics simulations of airborne dispersion

Highly pathogenic avian influenza (HPAI) virus can be spread rapidly, resulting in high mortality and severe economic damage to the poultry industry. A prediction of HPAI dispersion is challenging considering various spread factors, such as indirect transmission by airborne spread as well as direct...

Full description

Saved in:
Bibliographic Details
Published in:Biosystems engineering 2014-05, Vol.121, p.160-176
Main Authors: Seo, Il-Hwan, Lee, In-Bok, Moon, Oun-Kyung, Jung, Nam-Su, Lee, Hyung-Jin, Hong, Se-Woon, Kwon, Kyeong-Seok, Bitog, Jessie P.
Format: Article
Language:English
Subjects:
Aerosol
aerosols
Agricultural machinery and engineering
Agronomy. Soil science and plant productions
airborne transmission
Animal productions
Animal viral diseases
avian influenza
Biological and medical sciences
disease outbreaks
Dispersion modelling
field experimentation
fluid mechanics
Fundamental and applied biological sciences. Psychology
Generalities. Biometrics, experimentation. Remote sensing
geographic information systems
GIS
humans
Infectious diseases
Influenza A virus
livestock
Livestock disease
Medical sciences
migratory birds
mortality
poultry industry
prediction
Terrestrial animal productions
topography
Vertebrates
Viral diseases
viruses
wild animals
wind
Wind frequency
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Highly pathogenic avian influenza (HPAI) virus can be spread rapidly, resulting in high mortality and severe economic damage to the poultry industry. A prediction of HPAI dispersion is challenging considering various spread factors, such as indirect transmission by airborne spread as well as direct transmission through contact by humans, vehicles, wild animals, and migratory birds. Because of the complexity of the spread of HPAI, it is difficult to provide prompt treatments against epidemics. Moreover, there is little information on the airborne spread of the HPAI virus because of the limitations of field experiments for determining the mechanism of the spread of the disease due to the difficulty of making accurate measurements in the presence of unstable and uncontrollable weather conditions. In this study, CFD (computational fluid dynamics) was used to estimate the dispersion of the virus attached to aerosols produced by livestock using a GIS (geographical information system) to model a three-dimensional specific topography that includes the farm location, road network, and related facilities. The CFD simulation was conducted to predict the dispersion of virus from source farms according to various wind conditions. The weather conditions during the period of interest were analysed using CFD simulations to complete a frequency matrix form. The results were used as background data, to be used to take preventive measures against HPAI occurrences and spread based on the multifactor network process introduced in Part II. •CFD was used to predict airborne spread of HPAI virus.•Complex topography were considered in the CFD model.•HPAI spread was estimated by wind frequency analysis grafting CFD simulation.•Simulated airborne spread of HPAI was used to make multifactor network.
ISSN:1537-5110
1537-5129
DOI:10.1016/j.biosystemseng.2014.02.013