Development of a Dose‐Response Model for SARS Coronavirus
Identifieur interne : 002834 ( Main/Exploration ); précédent : 002833; suivant : 002835Development of a Dose‐Response Model for SARS Coronavirus
Auteurs : Toru Watanabe [Japon, États-Unis] ; Timothy A. Bartrand [États-Unis] ; Mark H. Weir [États-Unis] ; Tatsuo Omura [Japon] ; Charles N. Haas [États-Unis]Source :
- Risk Analysis [ 0272-4332 ] ; 2010-07.
Descripteurs français
- KwdFr :
- Animaux, Bases de données factuelles, Charge virale, Flambées de maladies, Fonctions de vraisemblance, Hong Kong (épidémiologie), Humains, Infections à coronavirus (virologie), Infections à coronavirus (étiologie), Loi de Poisson, Modèles animaux de maladie humaine, Modèles biologiques, Risque, Souris, Souris transgéniques, Syndrome respiratoire aigu sévère (virologie), Syndrome respiratoire aigu sévère (épidémiologie), Syndrome respiratoire aigu sévère (étiologie), Virus de l'hépatite murine (pathogénicité), Virus du SRAS (pathogénicité).
- MESH :
- pathogénicité : Virus de l'hépatite murine, Virus du SRAS.
- virologie : Infections à coronavirus, Syndrome respiratoire aigu sévère.
- épidémiologie : Hong Kong, Syndrome respiratoire aigu sévère.
- étiologie : Infections à coronavirus, Syndrome respiratoire aigu sévère.
- Animaux, Bases de données factuelles, Charge virale, Flambées de maladies, Fonctions de vraisemblance, Humains, Loi de Poisson, Modèles animaux de maladie humaine, Modèles biologiques, Risque, Souris, Souris transgéniques.
- Wicri :
- geographic : Hong Kong.
English descriptors
- KwdEn :
- Animals, Coronavirus Infections (etiology), Coronavirus Infections (virology), Databases, Factual, Disease Models, Animal, Disease Outbreaks, Hong Kong (epidemiology), Humans, Likelihood Functions, Mice, Mice, Transgenic, Models, Biological, Murine hepatitis virus (pathogenicity), Poisson Distribution, Risk, SARS Virus (pathogenicity), Severe Acute Respiratory Syndrome (epidemiology), Severe Acute Respiratory Syndrome (etiology), Severe Acute Respiratory Syndrome (virology), Viral Load.
- MESH :
- geographic , epidemiology : Hong Kong.
- epidemiology : Severe Acute Respiratory Syndrome.
- etiology : Coronavirus Infections, Severe Acute Respiratory Syndrome.
- pathogenicity : Murine hepatitis virus, SARS Virus.
- virology : Coronavirus Infections, Severe Acute Respiratory Syndrome.
- Teeft :
- Airborne transmission, American journal, Amoy, Amoy gardens, Animal coronaviruses, Animals, Apartment residents, Attack rate, Cellular biology, Cloacal inoculation, Comparative pathology, Coronavirus, Coronaviruses, Critical value, Cynomolgus monkeys, Data sets, Databases, Factual, Disease Models, Animal, Disease Outbreaks, Dos, Dose points, Empirical strategies, England journal, Environmental engineering, Environmental science center, Epidemiological data, Experimental medicine, Exponential, Exponential model, Exponential models, High mortality, Hong kong, Human susceptibility, Humans, Index case, Infectious viruses, Infectivity, Inoculation, Intranasal infection, Intranasal inoculation, Japanese journal, Likelihood Functions, Maximum likelihood method, Mice, Mice, Transgenic, Model application, Model development, Model parameters, Models, Biological, Mouse, Mouse hepatitis virus, Murine hepatitis virus strain, Other coronaviruses, Other hand, Other nidovirus diseases, Outbreak, Physical strength, Plaque assay, Poisson Distribution, Primary cause, Relevant model, Respiratory syndrome, Respiratory syndrome coronavirus, Respiratory tract, Risk, Risk analysis, Sars, Sars cases, Sars coronavirus, Sars epidemic, Sars outbreak, Sars pandemic, Sars patients, Sars propagation, Sole model, Swine haemagglutinating encephalomyelitis virus, Syndrome, Toru watanabe, Total number, Transgenic mice, Viral, Viral Load, Virus dispersion, Virus host animal host, Watanabe, Young mice.
Abstract
In order to develop a dose‐response model for SARS coronavirus (SARS‐CoV), the pooled data sets for infection of transgenic mice susceptible to SARS‐CoV and infection of mice with murine hepatitis virus strain 1, which may be a clinically relevant model of SARS, were fit to beta‐Poisson and exponential models with the maximum likelihood method. The exponential model (k= 4.1 × l02) could describe the dose‐response relationship of the pooled data sets. The beta‐Poisson model did not provide a statistically significant improvement in fit. With the exponential model, the infectivity of SARS‐CoV was calculated and compared with those of other coronaviruses. The does of SARS‐CoV corresponding to 10% and 50% responses (illness) were estimated at 43 and 280 PFU, respectively. Its estimated infectivity was comparable to that of HCoV‐229E, known as an agent of human common cold, and also similar to those of some animal coronaviruses belonging to the same genetic group. Moreover, the exponential model was applied to the analysis of the epidemiological data of SARS outbreak that occurred at an apartment complex in Hong Kong in 2003. The estimated dose of SARS‐CoV for apartment residents during the outbreak, which was back‐calculated from the reported number of cases, ranged from 16 to 160 PFU/person, depending on the floor. The exponential model developed here is the sole dose‐response model for SARS‐CoV at the present and would enable us to understand the possibility for reemergence of SARS.
Url:
- https://api.istex.fr/ark:/67375/WNG-HQGX9PJ1-X/fulltext.pdf
- http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7169223
DOI: 10.1111/j.1539-6924.2010.01427.x
Affiliations:
- Japon, États-Unis
- Pennsylvanie, Région de Kantō, Région de Tōhoku
- Sendai, Tokyo
- Université de Tokyo, Université du Tōhoku
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Le document en format XML
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Infections</term><term>Severe Acute Respiratory Syndrome</term></keywords><keywords scheme="MESH" qualifier="pathogenicity" xml:lang="en"><term>Murine hepatitis virus</term><term>SARS Virus</term></keywords><keywords scheme="MESH" qualifier="pathogénicité" xml:lang="fr"><term>Virus de l'hépatite murine</term><term>Virus du SRAS</term></keywords><keywords scheme="MESH" qualifier="virologie" xml:lang="fr"><term>Infections à coronavirus</term><term>Syndrome respiratoire aigu sévère</term></keywords><keywords scheme="MESH" qualifier="virology" xml:lang="en"><term>Coronavirus Infections</term><term>Severe Acute Respiratory Syndrome</term></keywords><keywords scheme="MESH" qualifier="épidémiologie" xml:lang="fr"><term>Hong Kong</term><term>Syndrome respiratoire aigu sévère</term></keywords><keywords scheme="MESH" qualifier="étiologie" xml:lang="fr"><term>Infections à coronavirus</term><term>Syndrome respiratoire aigu sévère</term></keywords><keywords scheme="Teeft" 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Kong</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">In order to develop a dose‐response model for SARS coronavirus (SARS‐CoV), the pooled data sets for infection of transgenic mice susceptible to SARS‐CoV and infection of mice with murine hepatitis virus strain 1, which may be a clinically relevant model of SARS, were fit to beta‐Poisson and exponential models with the maximum likelihood method. The exponential model (k= 4.1 × l02) could describe the dose‐response relationship of the pooled data sets. The beta‐Poisson model did not provide a statistically significant improvement in fit. With the exponential model, the infectivity of SARS‐CoV was calculated and compared with those of other coronaviruses. The does of SARS‐CoV corresponding to 10% and 50% responses (illness) were estimated at 43 and 280 PFU, respectively. Its estimated infectivity was comparable to that of HCoV‐229E, known as an agent of human common cold, and also similar to those of some animal coronaviruses belonging to the same genetic group. Moreover, the exponential model was applied to the analysis of the epidemiological data of SARS outbreak that occurred at an apartment complex in Hong Kong in 2003. The estimated dose of SARS‐CoV for apartment residents during the outbreak, which was back‐calculated from the reported number of cases, ranged from 16 to 160 PFU/person, depending on the floor. The exponential model developed here is the sole dose‐response model for SARS‐CoV at the present and would enable us to understand the possibility for reemergence of SARS.</div></front></TEI><affiliations><list><country><li>Japon</li><li>États-Unis</li></country><region><li>Pennsylvanie</li><li>Région de Kantō</li><li>Région de Tōhoku</li></region><settlement><li>Sendai</li><li>Tokyo</li></settlement><orgName><li>Université de Tokyo</li><li>Université du Tōhoku</li></orgName></list><tree><country name="Japon"><region name="Région de Kantō"><name sortKey="Watanabe, Toru" sort="Watanabe, Toru" uniqKey="Watanabe T" first="Toru" last="Watanabe">Toru Watanabe</name></region><name sortKey="Omura, Tatsuo" sort="Omura, Tatsuo" uniqKey="Omura T" first="Tatsuo" last="Omura">Tatsuo Omura</name><name sortKey="Watanabe, Toru" sort="Watanabe, Toru" uniqKey="Watanabe T" first="Toru" last="Watanabe">Toru Watanabe</name></country><country name="États-Unis"><region name="Pennsylvanie"><name sortKey="Watanabe, Toru" sort="Watanabe, Toru" uniqKey="Watanabe T" first="Toru" last="Watanabe">Toru Watanabe</name></region><name sortKey="Bartrand, Timothy A" sort="Bartrand, Timothy A" uniqKey="Bartrand T" first="Timothy A." last="Bartrand">Timothy A. Bartrand</name><name sortKey="Haas, Charles N" sort="Haas, Charles N" uniqKey="Haas C" first="Charles N." last="Haas">Charles N. Haas</name><name sortKey="Weir, Mark H" sort="Weir, Mark H" uniqKey="Weir M" first="Mark H." last="Weir">Mark H. Weir</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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