The secondary transmission pattern of COVID-19 based on contact tracing in Rwanda

The secondary transmission pattern of COVID-19 based on contact tracing in Rwanda

Introduction COVID-19 has shown an exceptionally high spread rate across and within countries worldwide. Understanding the dynamics of such an infectious disease transmission is critical for devising strategies to control its spread. In particular, Rwanda was one of the African countries that starte...

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Main Authors: Sabin Nsanzimana, Muhammed Semakula, Christel Faes, Thierry Nyatanyi, Eric Remera, FranÇois Niragire, Angela Umutoni, Vedaste Ndahindwa, Edison Rwagasore
Format: Article
Language:English
Published: BMJ Publishing Group 2021-06-01
Series:BMJ Global Health
Online Access:https://gh.bmj.com/content/6/6/e004885.full
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spelling doaj-0adaabd3f46147bc90a254cd5431370a2021-08-01T09:30:22ZengBMJ Publishing GroupBMJ Global Health2059-79082021-06-016610.1136/bmjgh-2020-004885The secondary transmission pattern of COVID-19 based on contact tracing in RwandaSabin Nsanzimana0Muhammed Semakula1Christel Faes2Thierry Nyatanyi3Eric Remera4FranÇois Niragire5Angela Umutoni6Vedaste Ndahindwa7Edison Rwagasore8Institute of HIV, Disease Prevention and Control, Rwanda Biomedical Center, Gasabo, City of Kigali, RwandaInstitute of HIV, Disease Prevention and Control, Rwanda Biomedical Center, Gasabo, City of Kigali, RwandaData Science Institute (DSI), Interuniversity Institute for Biostatistics and Statistical Bioinformatics (I-BioStat), Hasselt University, Hasselt, Limburg, Belgium1Ministry of Health, Kigali, RwandaInstitute of HIV, Disease Prevention and Control, Rwanda Biomedical Center, Gasabo, City of Kigali, RwandaApplied Statistics, University of Rwanda College of Business and Economics – Gikondo Campus, Kigali, RwandaInstitute for HIV, Diseases Prevention and Control, Rwanda Biomedical Center, Kigali, RwandaCollege of Medicine and Health Sciences, University of Rwanda, Kigali, RwandaRwanda Biomedical Center, Rwanda Ministry of Health, Kigali, RwandaIntroduction COVID-19 has shown an exceptionally high spread rate across and within countries worldwide. Understanding the dynamics of such an infectious disease transmission is critical for devising strategies to control its spread. In particular, Rwanda was one of the African countries that started COVID-19 preparedness early in January 2020, and a total lockdown was imposed when the country had only 18 COVID-19 confirmed cases known. Using intensive contact tracing, several infections were identified, with the majority of them being returning travellers and their close contacts. We used the contact tracing data in Rwanda for understanding the geographic patterns of COVID-19 to inform targeted interventions.Methods We estimated the attack rates and identified risk factors associated to COVID-19 spread. We used Bayesian disease mapping models to assess the spatial pattern of COVID-19 and to identify areas characterised by unusually high or low relative risk. In addition, we used multiple variable conditional logistic regression to assess the impact of the risk factors.Results The results showed that COVID-19 cases in Rwanda are localised mainly in the central regions and in the southwest of Rwanda and that some clusters occurred in the northeast of Rwanda. Relationship to the index case, being male and coworkers are the important risk factors for COVID-19 transmission in Rwanda.Conclusion The analysis of contact tracing data using spatial modelling allowed us to identify high-risk areas at subnational level in Rwanda. Estimating risk factors for infection with SARS-CoV-2 is vital in identifying the clusters in low spread of SARS-CoV-2 subnational level. It is imperative to understand the interactions between the index case and contacts to identify superspreaders, risk factors and high-risk places. The findings recommend that self-isolation at home in Rwanda should be reviewed to limit secondary cases from the same households and spatiotemporal analysis should be introduced in routine monitoring of COVID-19 in Rwanda for policy making decision on real time.https://gh.bmj.com/content/6/6/e004885.full
collection DOAJ
language English
format Article
sources DOAJ
author Sabin Nsanzimana
Muhammed Semakula
Christel Faes
Thierry Nyatanyi
Eric Remera
FranÇois Niragire
Angela Umutoni
Vedaste Ndahindwa
Edison Rwagasore
spellingShingle Sabin Nsanzimana
Muhammed Semakula
Christel Faes
Thierry Nyatanyi
Eric Remera
FranÇois Niragire
Angela Umutoni
Vedaste Ndahindwa
Edison Rwagasore
The secondary transmission pattern of COVID-19 based on contact tracing in Rwanda
BMJ Global Health
author_facet Sabin Nsanzimana
Muhammed Semakula
Christel Faes
Thierry Nyatanyi
Eric Remera
FranÇois Niragire
Angela Umutoni
Vedaste Ndahindwa
Edison Rwagasore
author_sort Sabin Nsanzimana
title The secondary transmission pattern of COVID-19 based on contact tracing in Rwanda
title_short The secondary transmission pattern of COVID-19 based on contact tracing in Rwanda
title_full The secondary transmission pattern of COVID-19 based on contact tracing in Rwanda
title_fullStr The secondary transmission pattern of COVID-19 based on contact tracing in Rwanda
title_full_unstemmed The secondary transmission pattern of COVID-19 based on contact tracing in Rwanda
title_sort secondary transmission pattern of covid-19 based on contact tracing in rwanda
publisher BMJ Publishing Group
series BMJ Global Health
issn 2059-7908
publishDate 2021-06-01
description Introduction COVID-19 has shown an exceptionally high spread rate across and within countries worldwide. Understanding the dynamics of such an infectious disease transmission is critical for devising strategies to control its spread. In particular, Rwanda was one of the African countries that started COVID-19 preparedness early in January 2020, and a total lockdown was imposed when the country had only 18 COVID-19 confirmed cases known. Using intensive contact tracing, several infections were identified, with the majority of them being returning travellers and their close contacts. We used the contact tracing data in Rwanda for understanding the geographic patterns of COVID-19 to inform targeted interventions.Methods We estimated the attack rates and identified risk factors associated to COVID-19 spread. We used Bayesian disease mapping models to assess the spatial pattern of COVID-19 and to identify areas characterised by unusually high or low relative risk. In addition, we used multiple variable conditional logistic regression to assess the impact of the risk factors.Results The results showed that COVID-19 cases in Rwanda are localised mainly in the central regions and in the southwest of Rwanda and that some clusters occurred in the northeast of Rwanda. Relationship to the index case, being male and coworkers are the important risk factors for COVID-19 transmission in Rwanda.Conclusion The analysis of contact tracing data using spatial modelling allowed us to identify high-risk areas at subnational level in Rwanda. Estimating risk factors for infection with SARS-CoV-2 is vital in identifying the clusters in low spread of SARS-CoV-2 subnational level. It is imperative to understand the interactions between the index case and contacts to identify superspreaders, risk factors and high-risk places. The findings recommend that self-isolation at home in Rwanda should be reviewed to limit secondary cases from the same households and spatiotemporal analysis should be introduced in routine monitoring of COVID-19 in Rwanda for policy making decision on real time.
url https://gh.bmj.com/content/6/6/e004885.full
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