tftycrvc

Property	Value
?:abstract	Background: Several COVID-19 vaccine candidates are in the final stage of testing. Interim trial results for two vaccines suggest at least 90% efficacy against symptomatic disease (VEDIS). It remains unknown whether this efficacy is mediated predominately by lowering SARS-CoV-2 infection susceptibility (VESUSC) or development of symptoms after infection (VESYMP). A vaccine with high VESYMP but low VESUSC has uncertain population impact. Methods: We developed a mathematical model of SARS-CoV-2 transmission, calibrated to demographic, physical distancing and epidemic data from King County, Washington. Different rollout scenarios starting December 2020 were simulated assuming different combinations of VESUSC and VESYMP resulting in up to 100% VEDIS with constant vaccine effects over 1 year. We assumed no further increase in physical distancing despite expanding case numbers and no reduction of infectivity upon infection conditional on presence of symptoms. Proportions of cumulative infections, hospitalizations and deaths prevented over 1 year from vaccination start are reported. Results: Rollouts of 1M vaccinations (5,000 daily) using vaccines with 50% VEDIS are projected to prevent 30%-58% of infections and 38%-58% of deaths over one year. In comparison, vaccines with 90% VEDIS are projected to prevent 47%-78% of the infections and 58%-77% of deaths over one year. In both cases, there is a greater reduction if VEDIS is mediated mostly by VESUSC. The use of a \'\'symptom reducing\'\' vaccine will require twice as many people vaccinated than a \'\'susceptibility reducing\'\' vaccine with the same 90% VEDIS to prevent 50% of the infections and death over one year. Delaying the start of the vaccination by 3 months decreases the expected population impact by approximately 40%. Conclusions: Vaccines which prevent COVID-19 disease but not SARS-CoV-2 infection, and thereby shift symptomatic infections to asymptomatic infections, will prevent fewer infections and require larger and faster vaccination rollouts to have population impact, compared to vaccines that reduce susceptibility to infection. If uncontrolled transmission across the U.S. continues, then expected vaccination in Spring 2021 will provide only limited benefit.
is ?:annotates of	<https://research.tib.eu/covid-19/entity/tftycrvc_hasAnnotation_C1457887> <https://research.tib.eu/covid-19/entity/tftycrvc_hasAnnotation_C1824370> <https://research.tib.eu/covid-19/entity/tftycrvc_hasAnnotation_C1825598> <https://research.tib.eu/covid-19/entity/tftycrvc_hasAnnotation_C3539957> <https://research.tib.eu/covid-19/entity/tftycrvc_hasAnnotation_C3714514> <https://research.tib.eu/covid-19/entity/tftycrvc_hasAnnotation_C5203676>
?:creator	<https://research.tib.eu/covid-19/entity/Swan%2C_D._A.%3B_Bracis%2C_C.%3B_Janes%2C_H.%3B_Moore%2C_M.%3B_Matrajt%2C_L.%3B_Reeves%2C_D._B.%3B_Burns%2C_E.%3B_Donnell%2C_D.%3B_Cohen%2C_M._S.%3B_Schiffer%2C_J.%3B_Dimitrov%2C_D._T.>
?:doi	10.1101/2020.12.13.20248142
?:doi	<https://research.tib.eu/covid-19/entity/10.1101/2020.12.13.20248142>
?:license	medrxiv
?:pdf_json_files	document_parses/pdf_json/91faa1a3290d7c794283e573d8af097b04909af1.json
?:publication_isRelatedTo_Disease	<https://research.tib.eu/covid-19/entity/COVID-19>
is ?:relation_isRelatedTo_publication of	<https://research.tib.eu/covid-19/entity/tftycrvc_HAS_C0042210_PREVENTS_C3714514> <https://research.tib.eu/covid-19/entity/tftycrvc_HAS_C5387588_PREVENTS_C1457887>
?:sha_id	<https://research.tib.eu/covid-19/entity/91faa1a3290d7c794283e573d8af097b04909af1>
?:source	MedRxiv; WHO
?:title	COVID-19 vaccines that reduce symptoms but do not block infection need higher coverage and faster rollout to achieve population impact
?:type	<https://research.tib.eu/covid-19/vocab/Publication>
?:year	2020-12-14

Property

Value

?:abstract

Background: Several COVID-19 vaccine candidates are in the final stage of testing. Interim trial results for two vaccines suggest at least 90% efficacy against symptomatic disease (VEDIS). It remains unknown whether this efficacy is mediated predominately by lowering SARS-CoV-2 infection susceptibility (VESUSC) or development of symptoms after infection (VESYMP). A vaccine with high VESYMP but low VESUSC has uncertain population impact. Methods: We developed a mathematical model of SARS-CoV-2 transmission, calibrated to demographic, physical distancing and epidemic data from King County, Washington. Different rollout scenarios starting December 2020 were simulated assuming different combinations of VESUSC and VESYMP resulting in up to 100% VEDIS with constant vaccine effects over 1 year. We assumed no further increase in physical distancing despite expanding case numbers and no reduction of infectivity upon infection conditional on presence of symptoms. Proportions of cumulative infections, hospitalizations and deaths prevented over 1 year from vaccination start are reported. Results: Rollouts of 1M vaccinations (5,000 daily) using vaccines with 50% VEDIS are projected to prevent 30%-58% of infections and 38%-58% of deaths over one year. In comparison, vaccines with 90% VEDIS are projected to prevent 47%-78% of the infections and 58%-77% of deaths over one year. In both cases, there is a greater reduction if VEDIS is mediated mostly by VESUSC. The use of a \'\'symptom reducing\'\' vaccine will require twice as many people vaccinated than a \'\'susceptibility reducing\'\' vaccine with the same 90% VEDIS to prevent 50% of the infections and death over one year. Delaying the start of the vaccination by 3 months decreases the expected population impact by approximately 40%. Conclusions: Vaccines which prevent COVID-19 disease but not SARS-CoV-2 infection, and thereby shift symptomatic infections to asymptomatic infections, will prevent fewer infections and require larger and faster vaccination rollouts to have population impact, compared to vaccines that reduce susceptibility to infection. If uncontrolled transmission across the U.S. continues, then expected vaccination in Spring 2021 will provide only limited benefit.

is ?:annotates of