Optimality in COVID-19 vaccination strategies determined by heterogeneity in human-human interaction networks

Goldenbogen, Björn; Adler, Stephan O.; Bodeit, Oliver; Wodke, Judith A. H.; Escalera‐Fanjul, Ximena; Korman, Aviv; Krantz, Marcus; Bonn, Lasse; Torres, Rafael Ubaldo Moran; Haffner, Johanna; Karnetzki, Maxim; Maintz, Ivo; Mallis, Lisa; Prawitz, Hannah; Segelitz, Patrick Steven; Seeger, M.A.; Linding, Rune; Klipp, Edda

doi:10.21203/rs.3.rs-128597/v1

Cited by 14 publications

(18 citation statements)

References 23 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Six studies reported that the trade-off between direct and indirect protection is sensitive to the proportion of people vaccinated. [12] [9] [21] [22] [15] [32] These papers stated that when vaccine supply is very low vaccination has a minimal impact on interrupting transmission, so more deaths can be prevented to vaccinate groups at risk of severe disease (e.g., key workers, seniors and clinical risk groups). However, as supply increases, this opens up the possibility of interrupting transmission, which can change prioritisation to the young or those with many contacts.…”

Section: Factors That Influence Prioritisation Strategymentioning

confidence: 99%

“…Seven studies recommended vaccination prioritisation based on social or occupational interactions compared to age group prioritisation. [28] [27] [31][32] [36][14] [37] Of these, three studies recommended prioritising essential workers to minimise cases[28] [27][14] and four studies recommended prioritising high social contact adults compared to other age groups. [31] [32] [37] [36]…”

mentioning

confidence: 99%

See 1 more Smart Citation

Models of COVID-19 vaccine prioritisation: a systematic literature search and narrative review

Saadi

Chi

Ghosh

et al. 2021

Preprint

View full text Add to dashboard Cite

Background: How best to prioritise COVID-19 vaccination within and between countries has been a public health and an ethical challenge for decision-makers globally. We systematically reviewed epidemiological and economic modelling evidence on population priority groups to minimise COVID-19 mortality, transmission and morbidity outcomes. Methods: We searched the National Institute of Health iSearch COVID-19 Portfolio (a database of peer-reviewed and pre-print articles), Econlit, the Centre for Economic Policy Research and the National Bureau of Economic Research for mathematical modelling studies evaluating the impact of prioritising COVID-19 vaccination to population target groups. We narratively synthesised the main study conclusions on prioritisation and the conditions under which the conclusions changed. Findings: The search identified 1820 studies. 36 studies met the inclusion criteria and were narratively synthesised. 83% of studies described outcomes in high-income countries. We found that for countries seeking to minimise deaths, prioritising vaccination of senior adults was the optimal strategy and for countries seeking to minimise cases the young were prioritised. There were several exceptions to the main conclusion, notably reductions in deaths could be increased, if groups at high risk of both transmission and death could be further identified. Findings were also sensitive to the level of vaccine coverage. Interpretation: The evidence supports WHO SAGE recommendations on COVID-19 vaccine prioritisation. There is however an evidence gap on optimal prioritisation for low- and middle- income countries, studies that included an economic evaluation, and studies that explore prioritisation strategies if the aim is to reduce overall health burden including morbidity.

show abstract

Section: Factors That Influence Prioritisation Strategymentioning

confidence: 99%

mentioning

confidence: 99%

Models of COVID-19 vaccine prioritisation: a systematic literature search and narrative review

Saadi

Chi

Ghosh

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…administer the vaccinations, and whether there is a strong healthcare infrastructure, sufficient funding and a system for vaccination monitoring [8]. The common strategies are aimed to reduce the mortality, decrease the pressure on the healthcare, and minimize the infection spread over a specific period of time [5].…”

Section: Discussionmentioning

confidence: 99%

A Vaccination Simulator for COVID-19: Effective and Sterilizing Immunization Cases

Karabay

Kuzdeuov

Lewis

et al. 2021

Preprint

View full text Add to dashboard Cite

Accurate modeling provides a means by which a complex problem can be examined for informed decision-making. We present a particle-based SEIR epidemic simulator as a tool to assess the impact of vaccination strategies on viral propagation and to model both sterilizing and effective immunization outcomes. The simulator includes modules to support contact tracing of the interactions amongst individuals as well as epidemiological testing of the general population. The simulator particles are distinguished by age, thus enabling a more accurate representation of the rates of infection and mortality in accordance with differential demographic susceptibilities and medical outcomes. The simulator can be calibrated by region of interest and variable vaccination strategies (i.e. random or prioritized by age) so as to enable locality-sensitive virus mitigation policy measures and resource allocation. The results described, based on the experience of the province of Lecco, Italy, indicate that the tool can be used to evaluate vaccination strategies in a way that incorporates local circumstances of viral propagation and demographic susceptibilities. Further, the simulator accounts for modeling the distinction between sterilizing immunization, in which immunized people are no longer contagious, and that of effective immunization, in which symptoms and mortality outcomes are diminished but individuals can still transmit the virus.

show abstract

“…Various levels of pre-existing immunity were also assumed, ranging from 5% to 20%, depending on the region. In [ 75 ], the authors studied the optimal choice of vaccination strategy under a partial or complete lockdown. Each of the individuals appearing in their model had a pre-assigned daily routine, specified on the resolution of 1 hour, with the routine determining the order in which the individuals move between different locations, such as workplaces, schools, public places, hospitals and homes.…”

Section: State Of the Artmentioning

confidence: 99%

Estimating the impact of interventions against COVID-19: From lockdown to vaccination

Thompson

Wattam²

2021

PLoS ONE

View full text Add to dashboard Cite

Coronavirus disease 2019 (COVID-19) is an infectious disease of humans caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Since the first case was identified in China in December 2019 the disease has spread worldwide, leading to an ongoing pandemic. In this article, we present an agent-based model of COVID-19 in Luxembourg, and use it to estimate the impact, on cases and deaths, of interventions including testing, contact tracing, lockdown, curfew and vaccination. Our model is based on collation, with agents performing activities and moving between locations accordingly. The model is highly heterogeneous, featuring spatial clustering, over 2000 behavioural types and a 10 minute time resolution. The model is validated against COVID-19 clinical monitoring data collected in Luxembourg in 2020. Our model predicts far fewer cases and deaths than the equivalent equation-based SEIR model. In particular, with R0 = 2.45, the SEIR model infects 87% of the resident population while our agent-based model infects only around 23% of the resident population. Our simulations suggest that testing and contract tracing reduce cases substantially, but are less effective at reducing deaths. Lockdowns are very effective although costly, while the impact of an 11pm-6am curfew is relatively small. When vaccinating against a future outbreak, our results suggest that herd immunity can be achieved at relatively low coverage, with substantial levels of protection achieved with only 30% of the population fully immune. When vaccinating in the midst of an outbreak, the challenge is more difficult. In this context, we investigate the impact of vaccine efficacy, capacity, hesitancy and strategy. We conclude that, short of a permanent lockdown, vaccination is by far the most effective way to suppress and ultimately control the spread of COVID-19.

show abstract

Optimality in COVID-19 vaccination strategies determined by heterogeneity in human-human interaction networks

Cited by 14 publications

References 23 publications

Models of COVID-19 vaccine prioritisation: a systematic literature search and narrative review

Models of COVID-19 vaccine prioritisation: a systematic literature search and narrative review

A Vaccination Simulator for COVID-19: Effective and Sterilizing Immunization Cases

Estimating the impact of interventions against COVID-19: From lockdown to vaccination

Contact Info

Product

Resources

About