Super-spreaders and the rate of transmission of the SARS virus

Abstract: We describe a stochastic small-world network model of transmission of the SARS virus. Unlike the standard Susceptible-Infected-Removed models of disease transmission, our model exhibits both geographically localised outbreaks and "super-spreaders". Moreover, the combination of localised and long range links allows for more accurate modelling of partial isolation and various public health policies. From this model, we derive an expression for the probability of a widespread outbreak and a condition to ensure th… Show more

“…The model included as agents those who were infected but not yet infectious, and as the main result the authors found that outbreaks could be prevented if the patients with symptoms were isolated as soon as possible. Another model applied to SARS spreading of virus in Hong Kong can be found in [405]. In 2007, Small et al [406] studied the distribution of avian influenza virus among wild and domestic birds and obtained a network with scale-free topology with no epidemic threshold.…”

Analyzing and modeling real-world phenomena with complex networks: a survey of applications

“…The model included as agents those who were infected but not yet infectious, and as the main result the authors found that outbreaks could be prevented if the patients with symptoms were isolated as soon as possible. Another model applied to SARS spreading of virus in Hong Kong can be found in [405]. In 2007, Small et al [406] studied the distribution of avian influenza virus among wild and domestic birds and obtained a network with scale-free topology with no epidemic threshold.…”

Analyzing and modeling real-world phenomena with complex networks: a survey of applications

“…The obtained results on heterogenous networks are based on the hypothesis that the larger the degree of an infected individual, the greater the capability for infection it has, i.e., hub=super −spreader [13] . However, in [6][7][8], Zhou, et al argued that this hypothesis is not always true.…”

Staged progression model for epidemic spread on homogeneous and heterogeneous networks

“…Recently, the study on dynamical behaviors of complex networks has become a focus of great interest in this research field, such as the synchronization and the pinning control of dynamical networks, the epidemic of disease [4][5][6][7][8][9][10][11][12][13][14][15][16], etc. Especially, there are attempts to control the dynamics of a complex network and drive the network to an desired state.…”

On pinning control of some typical discrete-time dynamical networks