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Category: COVID-19 Impact of Social Distancing/Mitigation Measures
Poster Session: COVID-19 Impact of Social Distancing/Mitigation Measures
Carlos Ernesto Ferreira Starling
MD
Lifecenter Hospital
Belo Horizonte, Minas Gerais, Brazil
Disclosure: I do not have any relevant financial / non-financial relationships with any proprietary interests.
Bráulio Roberto Gonçalves Marinho Couto
Professor of Bioinformatics
Centro Universitário de Belo Horizonte
Belo Horizonte, Minas Gerais, Brazil
Disclosure: I do not have any relevant financial / non-financial relationships with any proprietary interests.
Joaquim José da Cunha Júnior
Professor
Centro Universitário de Belo Horizonte
Belo Horizonte, Minas Gerais, Brazil
Disclosure: I do not have any relevant financial / non-financial relationships with any proprietary interests.
André Luiz Alvim
Master's Degree
Universidade Federal de Minas Gerais
Belo Horizonte, Minas Gerais, Brazil
Disclosure: I do not have any relevant financial / non-financial relationships with any proprietary interests.
Cristóvão de Deus Martins Oliveira
Medical Student
Centro Universitário de Belo Horizonte
Belo Horizonte, Minas Gerais, Brazil
Disclosure: I do not have any relevant financial / non-financial relationships with any proprietary interests.
Gregory E. Souza
Medical Student
Centro Universitário de Belo Horizonte - UniBH
Belo Horizonte, Minas Gerais, Brazil
Disclosure: I do not have any relevant financial / non-financial relationships with any proprietary interests.
Handerson Dias Duarte de Carvalho
Student
Centro Universitário de Belo Horizonte - UniBH
Belo Horizonte, Minas Gerais, Brazil
Disclosure: I do not have any relevant financial / non-financial relationships with any proprietary interests.
Rhayssa Fernanda Andrade Rocha
Medical Student
Centro Universitário de Belo Horizonte
Belo Horizonte, Minas Gerais, Brazil
Disclosure: I do not have any relevant financial / non-financial relationships with any proprietary interests.
The critical step in the prediction of COVID-19 by a SEIR model are the values of the basic reproduction number (R0) and the infectious period, in days. R0 and the infectious periods were calculated by mathematical constrained optimization, and used to determine the numerically minimum SEIR model errors in a country, based on COVID-19 data until april 11th. The Community Mobility Reports from Google Maps (https://www.google.com/covid19/mobility/) provided mobility changes on april 5th compared to the baseline (Jan 3th to Feb 6th). The data was used to measure the non-pharmacological intervention adherence. The impact of each mobility component was made by logistic regression models. COVID-19 control was defined by R0 of the SEIR model in a country less than 1.0.Algorithm for the SEIR model applied to COVID-19 (initialization)
Table 01: Algorithm for the SEIR model applied to COVID-19 (calculation of new COVID-19 cases day-by-day)
Results:
Residential mobility restriction presented the higher logistic coefficient (17.7), meaning higher impact on outbreak control. Workplace mobility restriction was the second most effective measure, considering a restriction minimum of 56% for a 53% chance of outbreak control. Retail and recreation mobility presented 53%, and 86% respectively. Transit stations (96% and 54%) were also assessed. Park mobility restriction demonstrated the lowest effectiveness in outbreak control, considering that absolute (100%) restriction provided the lowest chance of outbreak control (46%).Table 2: The Community Mobility Reports from Google Maps: Mobility changes on April 5 compared to the baseline (5- week period; Jan 3–Feb 6, 2020): T_infectious and R0 obtained by using COVID-19 new cases day-by-day in each country, adjusted to the SEIR model by mathematical constrained optimization
Logistic regression models to evaluate the chance of an epidemic control based on the non-pharmacological interventions adherence
Simulation of the impact of the mobility component in the chance of outbreak control: analysis by using the logistic regression model summarized in Table 2
Conclusion: Residential mobility restriction is the most effective measure. The degree to which mobility restrictions increase or decrease the overall epidemic size depends on the level of risk in each community and the characteristics of the disease. More research is required in order to estimate the optimal balance between mobility restriction, outbreak control, economy and freedom of movement.