TY - JOUR
T1 - Traveling waves in the Lethargic Crab Disease
AU - Ávila, Ricardo P.
AU - Mancera, Paulo F.A.
AU - Esteva, Lourdes
AU - Pie, Marcio R.
AU - Ferreira, Cláudia P.
N1 - Funding Information:
LE acknowledges a grant from PAPIIT IN08607-UNAM and CPF acknowledges a grant from FAPESP 05265-1/2007 and CNPq 478544/2007-3 . MRP was partially funded by Companhia de Desenvolvimento Industrial e de Recursos Minerais de Sergipe (CODISE) and CNPq 571334/2008-3 . PFAM acknowledges grants from FUNDUNESP 00807/2010-DFP and CAPES Pró-equipamentos 01/2007 .
PY - 2012/6/1
Y1 - 2012/6/1
N2 - Since 1997, the Lethargic Crab Disease (LCD) has decimated native populations of the mangrove land crab Ucides cordatus (Decapoda: Ocypodidae) along the Brazilian coast, spreading preferentially in the North-South direction and showing a periodic epidemic behavior. To study the spatial dissemination of LCD between estuaries, we propose a mathematical model using a system of partial differential reaction-diffusion equations. After a suitable change of variables, an analysis of the model shown that it presents four possible scenarios, namely, the trivial equilibrium, the disease-free equilibrium, endemic equilibrium, and limit cycles arising from a Hopf bifurcation. The threshold values depend on the basic reproductive number of crabs and fungi, and on the contact rate between these two population, modeled through mass action law. The existence of traveling wave solutions connecting disease free-equilibrium and endemic equilibrium is analyzed and the minimum wave speed for disease propagation obtained. A sensitivity analysis of the wave speed related to model parameters enables an understanding of how LCD can be controlled.
AB - Since 1997, the Lethargic Crab Disease (LCD) has decimated native populations of the mangrove land crab Ucides cordatus (Decapoda: Ocypodidae) along the Brazilian coast, spreading preferentially in the North-South direction and showing a periodic epidemic behavior. To study the spatial dissemination of LCD between estuaries, we propose a mathematical model using a system of partial differential reaction-diffusion equations. After a suitable change of variables, an analysis of the model shown that it presents four possible scenarios, namely, the trivial equilibrium, the disease-free equilibrium, endemic equilibrium, and limit cycles arising from a Hopf bifurcation. The threshold values depend on the basic reproductive number of crabs and fungi, and on the contact rate between these two population, modeled through mass action law. The existence of traveling wave solutions connecting disease free-equilibrium and endemic equilibrium is analyzed and the minimum wave speed for disease propagation obtained. A sensitivity analysis of the wave speed related to model parameters enables an understanding of how LCD can be controlled.
KW - Control
KW - Partial differential equations
KW - Traveling waves
KW - Wave speed
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U2 - 10.1016/j.amc.2012.03.076
DO - 10.1016/j.amc.2012.03.076
M3 - Article (journal)
AN - SCOPUS:84860434349
SN - 0096-3003
VL - 218
SP - 9898
EP - 9910
JO - Applied Mathematics and Computation
JF - Applied Mathematics and Computation
IS - 19
ER -