(A&B): Epidemic duration and total incidence under three different parameter settings.

Effects of altering the transmission probability and infectious period half-life on simulation model results.

M. Carolyn Gates (543012)
Mark E. J. Woolhouse (163944)

March 2014

The values shown are the predicted endemic prevalence when all replacement breeding cattle moveme...

Arash Mehrjou (14493211)
Ashkan Soleymani (14493214)
Amin Abyaneh (14493217)
Samir Bhatt (144911)
Bernhard Schölkopf (54318)
Stefan Bauer (24356)

January 2023

a) The number of currently infected individuals is plotted versus time for different values of the i...

Simulated differences in the magnitudes of epidemics (maximum proportion of I individuals in the population) and durations of epidemics (number of days with proportion of I>0.10) resulting from changes in the values of important model parameters in versions of the model assuming epidemics were initiated (A) via recrudescence and (B) via immigration (Error bars represent ± SE).

Hsiao-Hsuan Wang (329205)
Nina Y. Kung (490827)
William E. Grant (329206)
Joe C. Scanlan (490828)
Hume E. Field (145859)

November 2013

Simulated differences in the magnitudes of epidemics (maximum proportion of I individuals in the ...

(A&B): A comparison of epidemic duration and total incidence with 10% “fleers” versus 10% “ignorers.”

Joshua M. Epstein (273441)
Jon Parker (375542)
Derek Cummings (375544)
Ross A. Hammond (350488)

February 2013

As before, each bar in the chart represents an average across 30 simulation runs for a given para...

Dynamics over time of for three different simulation runs, solid grey line represents global prevalence of infection across all patches (farms and markets), colored dashed lines represent abundance of infected individuals within each patch (farm and market).

Parviez Rana Hosseini (491800)
Trevon Fuller (439967)
Ryan Harrigan (491801)
Delong Zhao (408800)
Carmen Sofia Arriola (491802)
Armandoe Gonzalez (491803)
Matthew Joshua Miller (491804)
Xiangming Xiao (118239)
Tom B. Smith (491805)
Jamie Holland Jones (491806)
Peter Daszak (72525)

December 2013

(A) 1280 patches of size 25, longest simulation run, note only three patches infected, (B) 128 pa...

Time series of an epidemic outbreak in the five communities.

Stephan Kitchovitch (348031)
Pietro Liò (34327)

February 2013

The lower figure represents the case in which the mitigation strategies, as described in the text...

Proportions of the population infected at the end of an outbreak, conditional on the selection of vaccination strategy under different response times.

Yun Tao (36115)
Katriona Shea (58432)
Matthew Ferrari (324213)

May 2018

Given population density, 60 simulation replicates were run for each vaccination diffusion rate <...

Impact of pathogen avoidance when the infection rate depends on the number of infected individuals in the population.

David Fouchet (189894)
John O'Brien (377563)
Dominique Pontier (163631)

February 2013

We plot here the equilibrium proportion of infected individuals in the host population (Y-axis) a...

Distribution of Immune Escape over the Course of Infection.

Christian L. Althaus (112118)
Rob J. De Boer (5650318)

February 2013

(A) Viral escapes over time given as an expected number of escapes per month (average of 1000 sim...

Fig 10 -

Arash Mehrjou (14493211)
Ashkan Soleymani (14493214)
Amin Abyaneh (14493217)
Samir Bhatt (144911)
Bernhard Schölkopf (54318)
Stefan Bauer (24356)

January 2023

a) The simulation is executed without any control measure, and the number of infected individuals is...

Models/parameterizations included in the ensemble and their behavior.

Thomas Smith (74383)
Amanda Ross (187821)
Nicolas Maire (95627)
Nakul Chitnis (187823)
Alain Studer (95628)
Diggory Hardy (179135)
Alan Brooks (179125)
Melissa Penny (187827)
Marcel Tanner (33894)

January 2012

aIncidence of clinical episodes (episodes per person-year) in the absence of intervention at an E...

The maximum of the time to extinction.

Petter Holme (166216)

December 2013

Panel A shows the average time to extinction as a function of the per-contact transmission probab...

Outbreaks under the baseline scenario (top) and a scenario with no interventions (bottom).

Guido España (3368603)
T. Alex Perkins (7419161)
Simon D. Pollett (13924805)
Morgan E. Smith (5828672)
Sean M. Moore (8114876)
Paul O. Kwon (13924808)
Tara L. Hall (13924811)
Milford H. Beagle Jr. (13924814)
Clinton K. Murray (10918214)
Shilpa Hakre (736910)
Sheila A. Peel (8506227)
Kayvon Modjarrad (3212904)
Paul T. Scott (11142838)

October 2022

Left: Distributions of cumulative infections over the 70-day training period across 1,000 replicate ...

Stochastic demonstration of epidemic enhancement in partially immune populations.

Juliet R.C. Pulliam (67925)
Jonathan G. Dushoff (67926)
Simon A. Levin (67927)
Andrew P. Dobson (67928)

February 2013

Each plot is a comparison of the outcome of the runs starting with a particular immunity level to...

Epidemiological parsimony is measured across transient strain-transcending immunity parameter space.

David C. Farrow (733696)
Donald S. Burke (102890)
Roni Rosenfeld (19137)

May 2015

Sixty parameterizations of strain-transcending immunity (strength and duration) were simulated. W...

Effects of altering the transmission probability and infectious period half-life on simulation model results.

M. Carolyn Gates (543012)
Mark E. J. Woolhouse (163944)

March 2014

The values shown are the predicted endemic prevalence when all replacement breeding cattle moveme...

Fig 11 -

Arash Mehrjou (14493211)
Ashkan Soleymani (14493214)
Amin Abyaneh (14493217)
Samir Bhatt (144911)
Bernhard Schölkopf (54318)
Stefan Bauer (24356)

January 2023

a) The number of currently infected individuals is plotted versus time for different values of the i...

Simulated differences in the magnitudes of epidemics (maximum proportion of I individuals in the population) and durations of epidemics (number of days with proportion of I>0.10) resulting from changes in the values of important model parameters in versions of the model assuming epidemics were initiated (A) via recrudescence and (B) via immigration (Error bars represent ± SE).

Hsiao-Hsuan Wang (329205)
Nina Y. Kung (490827)
William E. Grant (329206)
Joe C. Scanlan (490828)
Hume E. Field (145859)

November 2013

Simulated differences in the magnitudes of epidemics (maximum proportion of I individuals in the ...

(A&B): A comparison of epidemic duration and total incidence with 10% “fleers” versus 10% “ignorers.”

Joshua M. Epstein (273441)
Jon Parker (375542)
Derek Cummings (375544)
Ross A. Hammond (350488)

February 2013

As before, each bar in the chart represents an average across 30 simulation runs for a given para...

Dynamics over time of for three different simulation runs, solid grey line represents global prevalence of infection across all patches (farms and markets), colored dashed lines represent abundance of infected individuals within each patch (farm and market).

Parviez Rana Hosseini (491800)
Trevon Fuller (439967)
Ryan Harrigan (491801)
Delong Zhao (408800)
Carmen Sofia Arriola (491802)
Armandoe Gonzalez (491803)
Matthew Joshua Miller (491804)
Xiangming Xiao (118239)
Tom B. Smith (491805)
Jamie Holland Jones (491806)
Peter Daszak (72525)

December 2013

(A) 1280 patches of size 25, longest simulation run, note only three patches infected, (B) 128 pa...

Time series of an epidemic outbreak in the five communities.

Stephan Kitchovitch (348031)
Pietro Liò (34327)

February 2013

The lower figure represents the case in which the mitigation strategies, as described in the text...

Proportions of the population infected at the end of an outbreak, conditional on the selection of vaccination strategy under different response times.

Yun Tao (36115)
Katriona Shea (58432)
Matthew Ferrari (324213)

May 2018

Given population density, 60 simulation replicates were run for each vaccination diffusion rate <...

Impact of pathogen avoidance when the infection rate depends on the number of infected individuals in the population.

David Fouchet (189894)
John O'Brien (377563)
Dominique Pontier (163631)

February 2013

We plot here the equilibrium proportion of infected individuals in the host population (Y-axis) a...

Distribution of Immune Escape over the Course of Infection.

Christian L. Althaus (112118)
Rob J. De Boer (5650318)

February 2013

(A) Viral escapes over time given as an expected number of escapes per month (average of 1000 sim...

Fig 10 -

Arash Mehrjou (14493211)
Ashkan Soleymani (14493214)
Amin Abyaneh (14493217)
Samir Bhatt (144911)
Bernhard Schölkopf (54318)
Stefan Bauer (24356)

January 2023

a) The simulation is executed without any control measure, and the number of infected individuals is...

Models/parameterizations included in the ensemble and their behavior.

Thomas Smith (74383)
Amanda Ross (187821)
Nicolas Maire (95627)
Nakul Chitnis (187823)
Alain Studer (95628)
Diggory Hardy (179135)
Alan Brooks (179125)
Melissa Penny (187827)
Marcel Tanner (33894)

January 2012

aIncidence of clinical episodes (episodes per person-year) in the absence of intervention at an E...

The maximum of the time to extinction.

Petter Holme (166216)

December 2013

Panel A shows the average time to extinction as a function of the per-contact transmission probab...

Outbreaks under the baseline scenario (top) and a scenario with no interventions (bottom).

Guido España (3368603)
T. Alex Perkins (7419161)
Simon D. Pollett (13924805)
Morgan E. Smith (5828672)
Sean M. Moore (8114876)
Paul O. Kwon (13924808)
Tara L. Hall (13924811)
Milford H. Beagle Jr. (13924814)
Clinton K. Murray (10918214)
Shilpa Hakre (736910)
Sheila A. Peel (8506227)
Kayvon Modjarrad (3212904)
Paul T. Scott (11142838)

October 2022

Left: Distributions of cumulative infections over the 70-day training period across 1,000 replicate ...

Stochastic demonstration of epidemic enhancement in partially immune populations.

Juliet R.C. Pulliam (67925)
Jonathan G. Dushoff (67926)
Simon A. Levin (67927)
Andrew P. Dobson (67928)

February 2013

Each plot is a comparison of the outcome of the runs starting with a particular immunity level to...

Epidemiological parsimony is measured across transient strain-transcending immunity parameter space.

David C. Farrow (733696)
Donald S. Burke (102890)
Roni Rosenfeld (19137)

May 2015

Sixty parameterizations of strain-transcending immunity (strength and duration) were simulated. W...

Effects of altering the transmission probability and infectious period half-life on simulation model results.

M. Carolyn Gates (543012)
Mark E. J. Woolhouse (163944)

March 2014

The values shown are the predicted endemic prevalence when all replacement breeding cattle moveme...

Fig 11 -

Arash Mehrjou (14493211)
Ashkan Soleymani (14493214)
Amin Abyaneh (14493217)
Samir Bhatt (144911)
Bernhard Schölkopf (54318)
Stefan Bauer (24356)

January 2023

a) The number of currently infected individuals is plotted versus time for different values of the i...

Simulated differences in the magnitudes of epidemics (maximum proportion of I individuals in the population) and durations of epidemics (number of days with proportion of I>0.10) resulting from changes in the values of important model parameters in versions of the model assuming epidemics were initiated (A) via recrudescence and (B) via immigration (Error bars represent ± SE).

Hsiao-Hsuan Wang (329205)
Nina Y. Kung (490827)
William E. Grant (329206)
Joe C. Scanlan (490828)
Hume E. Field (145859)

November 2013

Simulated differences in the magnitudes of epidemics (maximum proportion of I individuals in the ...

(A&B): Epidemic duration and total incidence under three different parameter settings.

Abstract

Extracted data

(A&B): Epidemic duration and total incidence under three different parameter settings.

Abstract

Extracted data

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