The effect modification of institutional delivery on the expected time to vaccination for BCG and polio dose 0, across different demographic groups, according to an accelerated failure time model with a Weibull distribution.

Results of the Model without Incentives

Raffaele Vardavas (24868)
Romulus Breban (24867)
Sally Blower (24869)

February 2013

<div><p>The vaccination coverage dynamic has a memory parameter <i>s</i> = 0.7, an adaptability para...

Impact of vaccine introduction.

Michael A. Andrews (750091)
Chris T. Bauch (119485)

June 2015

<p>Example of a baseline scenario of our model where vaccination becomes available in season 10, cau...

Vaccination strategies in structured populations under partial immunity and reinfection

Rodríguez Maroto, Gabriel
Atienza-Diez, Iker
Ares, Saúl
Manrubia Cuevas, Susanna

November 2021

Optimal protocols of vaccine administration to minimize the effects of infectious diseases depend on...

The expected time to vaccination for four different vaccine series across different demographic groups, according to a fully adjusted accelerated failure time model with a Weibull distribution.

Matthew L. Boulton (563930)
Bradley F. Carlson (4471489)
Abram L. Wagner (563927)
Julia M. Porth (4060477)
Berhanu Gebremeskel (6377099)
Yemesrach Abeje (4285645)

February 2019

The expected time to vaccination for four different vaccine series across different demographic grou...

Modelling the Effects of Booster Dose Vaccination Schedules and Recommendations for Public Health Immunization Programs: The Case of Haemophilus Influenzae Serotype B

Charania, N
Moghadas, SM

January 2017

Background Haemophilus influenzae serotype b (Hib) has yet to be eliminated despite the implementati...

Efficacy versus abundancy: Comparing vaccination schemes.

Omar El Deeb
Maya Jalloul

January 2022

We introduce a novel compartmental model accounting for the effects of vaccine efficacy, deployment ...

Modelling the effects of booster dose vaccination schedules and recommendations for public health immunization programs: the case of Haemophilus influenzae serotype b

Nadia A. Charania
Seyed M. Moghadas

September 2017

Abstract Background Haemophilus influenzae serotype b (Hib) has yet to be eliminated despite the imp...

: A Microsimulation Model of the Indirect Effects of Vaccination

Nurhonen Markku
Cheng Allen C.
Auranen Kari

February 2013

The degree and time frame of indirect effects of vaccination (serotype replacement and herd immunity...

Effects of COVID-19 Vaccination Timing and Risk Prioritization on Mortality Rates, United States

Xutong Wang
Zhanwei Du
Kaitlyn E. Johnson
Remy F. Pasco
Spencer J. Fox
Michael Lachmann
Jason S. McLellan
Lauren Ancel Meyers

July 2021

During rollout of coronavirus disease vaccination, policymakers have faced critical trade-offs. Usin...

Herd immunity alters the conditions for performing dose schedule comparisons: an individual-based model of pneumococcal carriage

Alan Yang
Francisco Cai
Marc Lipsitch

March 2019

Abstract Background There is great interest in the use of reduced dosing schedules for pneumococcal ...

Printed In USA

Cholera Vaccines
Azhar Nizam
Malla Rao

October 2016

The authors present a nonparametric method for estimating vaccine efficacy as a smooth function of t...

The effect of timing of vaccination start on A) pandemic clinical attack rate, B) peak prevalence of symptomatic infections and C) time delay of peak relative to unmitigated pandemic; no use of antivirals implemented in these simulations (p_use = 0%).

Birgitte Freiesleben de Blasio (143012)
Bjørn G. Iversen (335667)
Gianpaolo Scalia Tomba (42331)

February 2013

<p>For comparison, the predicted relative reduction in the baseline scenario with vaccine and antivi...

Effects of timing and amount of available vaccine on influenza prevalence using (A) Model 1 with periodic transmission rate (B) Model 2 with extracted transmission rate, β<sub>t</sub> (C) Model 3 with two weakly interacting sub-populations (D) Model 4 with virus mutation causing delayed susceptibility of some individuals (E) Model 5 with waning immunity.

Anna Mummert (405753)
Howard Weiss (405754)
Li-Ping Long (398876)
José M. Amigó (405755)
Xiu-Feng Wan (254964)

April 2013

<p>The model generated disease prevalence with the vaccination strategy indicated, compared with the...

Evaluation of response scenarios to potential polio outbreaks using mathematical models

Kimberly M. Thompson
Radboud J. Duintjer Tebbens
Mark A. Pallansch

January 2006

Appropriate response to polio outbreaks represents an important prerequisite for achieving and maint...

The Epidemiological Impact of Delayed Vaccination

Shweta Bansal (252473)
Babak Pourbohloul (104292)
Lauren Ancel Meyers (27605)

February 2013

<div><p>(A) The morbidity-based strategy is more effective than the mortality-based strategy when <i...

Results of the Model without Incentives

Raffaele Vardavas (24868)
Romulus Breban (24867)
Sally Blower (24869)

February 2013

<div><p>The vaccination coverage dynamic has a memory parameter <i>s</i> = 0.7, an adaptability para...

Impact of vaccine introduction.

Michael A. Andrews (750091)
Chris T. Bauch (119485)

June 2015

<p>Example of a baseline scenario of our model where vaccination becomes available in season 10, cau...

Vaccination strategies in structured populations under partial immunity and reinfection

Rodríguez Maroto, Gabriel
Atienza-Diez, Iker
Ares, Saúl
Manrubia Cuevas, Susanna

November 2021

Optimal protocols of vaccine administration to minimize the effects of infectious diseases depend on...

The expected time to vaccination for four different vaccine series across different demographic groups, according to a fully adjusted accelerated failure time model with a Weibull distribution.

Matthew L. Boulton (563930)
Bradley F. Carlson (4471489)
Abram L. Wagner (563927)
Julia M. Porth (4060477)
Berhanu Gebremeskel (6377099)
Yemesrach Abeje (4285645)

February 2019

The expected time to vaccination for four different vaccine series across different demographic grou...

Modelling the Effects of Booster Dose Vaccination Schedules and Recommendations for Public Health Immunization Programs: The Case of Haemophilus Influenzae Serotype B

Charania, N
Moghadas, SM

January 2017

Background Haemophilus influenzae serotype b (Hib) has yet to be eliminated despite the implementati...

Efficacy versus abundancy: Comparing vaccination schemes.

Omar El Deeb
Maya Jalloul

January 2022

We introduce a novel compartmental model accounting for the effects of vaccine efficacy, deployment ...

Modelling the effects of booster dose vaccination schedules and recommendations for public health immunization programs: the case of Haemophilus influenzae serotype b

Nadia A. Charania
Seyed M. Moghadas

September 2017

Abstract Background Haemophilus influenzae serotype b (Hib) has yet to be eliminated despite the imp...

: A Microsimulation Model of the Indirect Effects of Vaccination

Nurhonen Markku
Cheng Allen C.
Auranen Kari

February 2013

The degree and time frame of indirect effects of vaccination (serotype replacement and herd immunity...

Effects of COVID-19 Vaccination Timing and Risk Prioritization on Mortality Rates, United States

Xutong Wang
Zhanwei Du
Kaitlyn E. Johnson
Remy F. Pasco
Spencer J. Fox
Michael Lachmann
Jason S. McLellan
Lauren Ancel Meyers

July 2021

During rollout of coronavirus disease vaccination, policymakers have faced critical trade-offs. Usin...

Herd immunity alters the conditions for performing dose schedule comparisons: an individual-based model of pneumococcal carriage

Alan Yang
Francisco Cai
Marc Lipsitch

March 2019

Abstract Background There is great interest in the use of reduced dosing schedules for pneumococcal ...

Printed In USA

Cholera Vaccines
Azhar Nizam
Malla Rao

October 2016

The authors present a nonparametric method for estimating vaccine efficacy as a smooth function of t...

The effect of timing of vaccination start on A) pandemic clinical attack rate, B) peak prevalence of symptomatic infections and C) time delay of peak relative to unmitigated pandemic; no use of antivirals implemented in these simulations (p_use = 0%).

Birgitte Freiesleben de Blasio (143012)
Bjørn G. Iversen (335667)
Gianpaolo Scalia Tomba (42331)

February 2013

<p>For comparison, the predicted relative reduction in the baseline scenario with vaccine and antivi...

Effects of timing and amount of available vaccine on influenza prevalence using (A) Model 1 with periodic transmission rate (B) Model 2 with extracted transmission rate, β<sub>t</sub> (C) Model 3 with two weakly interacting sub-populations (D) Model 4 with virus mutation causing delayed susceptibility of some individuals (E) Model 5 with waning immunity.

Anna Mummert (405753)
Howard Weiss (405754)
Li-Ping Long (398876)
José M. Amigó (405755)
Xiu-Feng Wan (254964)

April 2013

<p>The model generated disease prevalence with the vaccination strategy indicated, compared with the...

Evaluation of response scenarios to potential polio outbreaks using mathematical models

Kimberly M. Thompson
Radboud J. Duintjer Tebbens
Mark A. Pallansch

January 2006

Appropriate response to polio outbreaks represents an important prerequisite for achieving and maint...

The Epidemiological Impact of Delayed Vaccination

Shweta Bansal (252473)
Babak Pourbohloul (104292)
Lauren Ancel Meyers (27605)

February 2013

<div><p>(A) The morbidity-based strategy is more effective than the mortality-based strategy when <i...

Results of the Model without Incentives

Raffaele Vardavas (24868)
Romulus Breban (24867)
Sally Blower (24869)

February 2013

<div><p>The vaccination coverage dynamic has a memory parameter <i>s</i> = 0.7, an adaptability para...

Impact of vaccine introduction.

Michael A. Andrews (750091)
Chris T. Bauch (119485)

June 2015

<p>Example of a baseline scenario of our model where vaccination becomes available in season 10, cau...

Vaccination strategies in structured populations under partial immunity and reinfection

Rodríguez Maroto, Gabriel
Atienza-Diez, Iker
Ares, Saúl
Manrubia Cuevas, Susanna

November 2021

Optimal protocols of vaccine administration to minimize the effects of infectious diseases depend on...

The effect modification of institutional delivery on the expected time to vaccination for BCG and polio dose 0, across different demographic groups, according to an accelerated failure time model with a Weibull distribution.

Abstract

Extracted data

The effect modification of institutional delivery on the expected time to vaccination for BCG and polio dose 0, across different demographic groups, according to an accelerated failure time model with a Weibull distribution.

Abstract

Extracted data

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