Difference between revisions of "Epidemics:guineapigs:model"
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=== Extraction of unknown parameters === | === Extraction of unknown parameters === | ||
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Revision as of 14:21, 14 November 2008
Society epidemics | Guinea pigs epidemics | Virus genetic evolution |
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Data | Model | Results |
Contents
Model's assumptions
We have formulated a discrete stochastic model based on the probability of infection. To estimate this probability, we apply a simple generalized linear model (GLM), with as the link function. This is a standard approach that has been successfully adopted in various related contexts for modeling influenza^{[1]}^{[2]}. The model starts from day zero, when all non pre-infected animals are healthy. For each consecutive day, we calculate the probabilities that each individual, among those not yet infected, will be infected on that day, and then we randomly check whether any of the possible infections actually happens. The infection history is subsequently updated, and the algorithm moves to the next day.
We assume the four following conditions:
1. The probability that the ith individual will be infected on a particular day (provided that it had not been infected previously) is
where is a measure of virus concentration in the respiratory tract of the jth individual (decimal logarithm of the number of PFU in one ml of its nasal wash). The summation goes over individuals placed on the same and on adjacent shelves. Spatial coefficients are related to the probabilities that an aerosol drop, shed by the jth animal, will get to the ith guinea pig's cage. The coefficient reflects the dependence of the virus transmission rate on the air temperature (T) and relative humidity (H).
2. The course of influenza (virus concentration in nasal wash on the days subsequent to infection) depends only on the ambient temperature. Therefore, for each individual that became infected via air during the course of each particular experiment, the concentrations were assigned values reflecting the average case for that temperature. Table 1 shows the mean concentrations measured on particular days after infection, separately for each temperature. Functions comprising two linear pieces appear to be a reasonable guess, as shown in Figure 1.
Day | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 |
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Concentration, | 1.52 | 4.52 | 5.63 | 6.89 | 6.06 | 3.26 | 1.88 | - | - |
Concentration, | 1.91 | 4.40 | 5.72 | 7.02 | 6.01 | 4.54 | 3.52 | 1.77 | - |
Std. deviation square | 0.40 | 0.59 | 1.26 | 0.32 | 2.38 | 1.44 | 3.18 | 2.34 | - |
The two piecewise linear approximations of the infection course. For the best fit is for the growing part and for the falling; for it is and respectively. We assume if the amount of virus is undetectable or zero |
This may be interpreted as a two-phase infection course: first, the virus concentration grows exponentially (the scale is logarithmic), and subsequently (mostly as a result of the immune system activation) it exponentially falls. The transition between phase 1 and 2 is always sharp.
3. A detectable virus presence in the respiratory tract begins 2 days after the infection. Such an assumption is drawn from the fact that the virus was not detectable in nasal wash earlier than the third day of experiment. A lack of infections during the first day, when the virus concentrations in pre-infected individuals is supposed to be high, is of little probability. This is consistent with the major biological and clinical experience, which shows that the influenza proper begins rapidly after 2-3 days of a rather asymptomatic and non-infectious incubation period^{[3]}^{[4]}.
Accordingly, we shifted the assumed average infection course such that on the first day. The final concentration values are shown in Table 2.
4. The infection course in pre-infected individuals also consists of two linear (on a logarithmic scale) phases. Concentration values for the descending phase come from the measurement^{[5]} (We fitted a linear function for these values. However, they were originally of a nearly linear nature.). Due to the lack of the respective experimental data, for the ascending phase we assumed the slope to be the same as for animals infected via air. The virus concentration values for those individuals are also shown in Table 2.
Propagation of infection
An infection space
Extraction of unknown parameters
References
- ↑ FERGUSON N M, Cummings D, Cauchemez S, Fraser C, Riley S, Meeyai A, Iamsirithaworn S, and Burke D, Strategies for containing an emerging influenza pandemic in Southeast Asia, Nature, 437 (2005), p209
- ↑ STEGEMAN A, Bouma A, Elbers A R W, de Jong M C M, Nodelijk G, de Klerk F, Koch G, van Boven M,Avian Influenza A Virus (H7N7) Epidemic in The Netherlands in 2003: Course of the Epidemic and Effectiveness of Control Measures, J. Inf. Dis. 190, 2004
- ↑ Carrat F, Vergu E, Ferguson N M, Lemaitre M, Cauchemez S, Leach S, Valleron A J, Time Lines of Infection and Disease in Human Influenza: A Review of Volunteer Challenge Studies, Am. J. Epid. 167(7), 2008
- ↑ Collier L, Oxford J, Human virology, Oxford University Press, 1993
- ↑ Lowen A C, Mubareka S, Steel J, Palese P, Influenza Virus Transmission Is Dependent on Relative Humidity and Temperature, PLoS Pathogens 3(10), 2007, p151