Author(s)

Ganga Ram Phaijoo, Dil Bahadur Gurung

Department of Natural Sciences (Mathematics), School of Science, Kathmandu University, Dhulikhel, Nepal.

Dengue disease is the most common vector borne infectious disease transmitted to humans by infected adult female Aedes mosquitoes. Over the past several years the disease has been increasing remarkably and it has become a major public health concern. Dengue viruses have increased their geographic range into new human population due to travel of humans from one place to the other. In the present paper, we have proposed a multi patch SIR-SI model to study the host-vector dynamics of dengue disease in different patches including the travel of human population among the patches. We have considered different disease prevalences in different patches and different travel rates of humans. The dimensionless number, basic reproduction number R0 which shows that the disease dies out if R0 < 1 and the disease takes hold if R0 ≥ 1, is calculated. Local and global stability of the disease free equilibrium are analyzed. Simulations are observed considering the two patches only. The results show that controlling the travel of infectious hosts from high disease dominant patch to low disease dominant patch can help in controlling the disease in low disease dominant patch while high disease dominant becomes even more disease dominant. The understanding of the effect of travel of humans on the spatial spread of the disease among the patches can be helpful in improving disease control and prevention measures. In the present study, a patch may represent a city, a village or some biological habitat.

Dengue, Patch, Basic Reproduction Number, Equilibrium Point, Stability

Phaijoo, G. and Gurung, D. (2016) Mathematical Study of Dengue Disease Transmission in Multi-Patch Environment. Applied Mathematics, 7, 1521-1533. doi: 10.4236/am.2016.714132.