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Authors
Nguyen, Van KinhBinder, Sebastian C
Boianelli, Alessandro
Müller, A
Hernandez-Vargas, Esteban Abelardo
Issue Date
2015
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Show full item recordAbstract
The recent outbreaks of Ebola virus (EBOV) infections have underlined the impact of the virus as a major threat for human health. Due to the high biosafety classification of EBOV (level 4), basic research is very limited. Therefore, the development of new avenues of thinking to advance quantitative comprehension of the virus and its interaction with the host cells is urgently needed to tackle this lethal disease. Mathematical modeling of the EBOV dynamics can be instrumental to interpret Ebola infection kinetics on quantitative grounds. To the best of our knowledge, a mathematical modeling approach to unravel the interaction between EBOV and the host cells is still missing. In this paper, a mathematical model based on differential equations is used to represent the basic interactions between EBOV and wild-type Vero cells in vitro. Parameter sets that represent infectivity of pathogens are estimated for EBOV infection and compared with influenza virus infection kinetics. The average infecting time of wild-type Vero cells by EBOV is slower than in influenza infection. Simulation results suggest that the slow infecting time of EBOV could be compensated by its efficient replication. This study reveals several identifiability problems and what kind of experiments are necessary to advance the quantification of EBOV infection. A first mathematical approach of EBOV dynamics and the estimation of standard parameters in viral infections kinetics is the key contribution of this work, paving the way for future modeling works on EBOV infection.Citation
Ebola virus infection modeling and identifiability problems. 2015, 6:257 Front MicrobiolAffiliation
Helmholtz Center for Infection ResearchJournal
Frontiers in microbiologyPubMed ID
25914675Type
ArticleLanguage
enISSN
1664-302Xae974a485f413a2113503eed53cd6c53
10.3389/fmicb.2015.00257
Scopus Count
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