scholarly journals Covid-19 testing strategies and lockdowns: the European closed curves, analysed by “skew-normal” distributions, the forecasts for the UK, Sweden, and the USA, and the ongoing outbreak in Brazil

2020 ◽  
Author(s):  
Stefano De Leo
Keyword(s):  
Early Stage ◽  
Spreading Rate ◽  
European Countries ◽  
Mitigation Measures ◽  
Local Authorities ◽  
Normal Distributions ◽  
Testing Strategies ◽  
The Usa ◽  
The Uk ◽  
Skew Normal

AbstractAs the number of Covid-19 infections worldwide overtakes 6 millions of Total Confirmed Cases (TCC), the data reveal almost closed outbreaks in many European countries. Using the European data as a basis for our analysis, we study the spreading rate of Covid-19 and model the Daily Confirmed Cases and Deaths per Million (DCCpM and DDpM) curves by using “skew-normal” probability density functions. The use of these asymmetrical distributions allows to get a more realistic prediction of the end of the disease in each country and to evaluate the effectiveness of the local authorities strategies in facing the European outbreak. The initial stage of the Brazilian disease is compared with the early phase of the European one. This is done by using the weekly spreading rate of Covid-19. For Sweden, UK, and USA, we shall give a forecast for the end of pandemic and for Brazil the prediction of the peak of DDpM. We also discuss additional factors that could play an important role in the fight against Covid-19, such as the fast response of the local authorities, the testing strategies, the number of beds in the intensive care units, and, last but not least, the measures of isolation adopted. The Brazilian mitigation measures can be placed between the strict lockdown of many European countries and the Swedish approach, but clearly much comparable to the European ones (in particular to the Netherlands).MethodsFor Brazil, the weekly spreading rates of Covid-19, as more people are getting infected, was used to compare the outbreak in these countries with the ones of the European countries when they were at the same stage of infection. In the early stage of the disease, normal distributions have been used to obtain what we call a dynamic prediction of the peaks. After reaching the peak of daily infections and/or deaths, skew-normal distributions are required to correctly fit the asymmetrical DCCpM and DDpM curves and get a realistic forecast of the pandemic end.FindingsThe European data analysis shows that the spreading rate of Covid-19 increased similarly for all countries in its initial stage, but it changed as the number of TCCpM in each country grew. This was caused by the different timely action of the authorities in adopting isolation measures and/or massive testing strategies. The early stage of the outbreak in the USA and Brazil shows for their α factor (DCCpM) a behaviour similar to Italy and Sweden, respectively. For the β factor (DDpM), the American spreading is similar to the one of Switzerland, whereas the Brazilian factor is greater than the ones of Portugal, Germany, and Austria (which showed, in terms of TDpM, the best results in Europe) but, at the moment, it is lower than the other European countries.InterpretationThe fitting skew parameters used to model the DCCpM and DDpM curves allow a more realistic prediction of the end of the pandemic and give us the possibility to compare the mitigation measures adopted by the local authorities by analysing their respective skew normal parameters (mean, mode, standard deviation, and skewness). In Europe, Sweden and the UK show the greatest asymmetries, a kind of marathon instead of the sprint of other European countries (as observed by Swedish authorities). This also happens for the USA. The Brazilian weekly spreading rate for deaths is lower than most of the European countries at the same stage of the outbreak.FundingIndividual grants by CNPq (2018/303911) and Fapesp (2019/06382–9).

scholarly journals Covid-19 testing strategies and lockdowns: the European closed curves, analysed by ``skew-normal'' distributions, the forecasts for the UK, Sweden, and the USA, and the ongoing outbreak in Brazil (Preprint)

2020 ◽  
Author(s):  
Stefano De Leo
Keyword(s):  
Early Stage ◽  
Spreading Rate ◽  
European Countries ◽  
Mitigation Measures ◽  
Local Authorities ◽  
Normal Distributions ◽  
Testing Strategies ◽  
The Usa ◽  
The Uk ◽  
Skew Normal

BACKGROUND As the number of Covid-19 infections worldwide overtakes 6 millions of Total Confirmed Cases (TCC), the data reveal almost closed outbreaks in many European countries. Using the European data as a basis for our analysis, we study the spreading rate of Covid-19 and model the Daily Confirmed Cases and Deaths per Million (DCCpM and DDpM) curves by using ``skew-normal'' probability density functions. OBJECTIVE The use of these asymmetrical distributions allows to get a more realistic prediction of the end of the disease in each country and to evaluate the effectiveness of the local authorities strategies in facing the European outbreak. The initial stage of the Brazilian disease is compared with the early phase of the European one. This is done by using the weekly spreading rate of Covid-19. For Sweden, UK, and USA, we shall give a forecast for the end of pandemic and for Brazil the prediction of the peak of DDpM. We also discuss additional factors that could play an important role in the fight against Covid-19, such as the fast response of the local authorities, the testing strategies, the number of beds in the intensive care units, and, last but not least, the measures of isolation adopted. The Brazilian mitigation measures can be placed between the strict lockdown of many European countries and the Swedish approach, but clearly much comparable to the European ones (in particular to the Netherlands). METHODS For Brazil, the weekly spreading rates of Covid-19, as more people are getting infected, was used to compare the outbreak in these countries with the ones of the European countries when they were at the same stage of infection. In the early stage of the disease, normal distributions have been used to obtain what we call a dynamic prediction of the peaks. After reaching the peak of daily infections and/or deaths, skew-normal distributions are required to correctly fit the asymmetrical DCCpM and DDpM curves and get a realistic forecast of the pandemic end. RESULTS The European data analysis shows that the spreading rate of Covid-19 increased similarly for all countries in its initial stage, but it changed as the number of TCCpM in each country grew. This was caused by the different timely action of the authorities in adopting isolation measures and/or massive testing strategies. The early stage of the outbreak in the USA and Brazil shows for their $\boldsymbol{\alpha}$ factor (DCCpM) a behaviour similar to Italy and Sweden, respectively. For the $\boldsymbol{\beta}$ factor (DDpM), the American spreading is similar to the one of Switzerland, whereas the Brazilian factor is greater than the ones of Portugal, Germany, and Austria (which showed, in terms of TDpM, the best results in Europe) but, at the moment, it is lower than the other European countries. CONCLUSIONS The fitting skew parameters used to model the DCCpM and DDpM curves allow a more realistic prediction of the end of the pandemic and give us the possibility to compare the mitigation measures adopted by the local authorities by analysing their respective skew normal parameters (mean, mode, standard deviation, and skewness). In Europe, Sweden and the UK show the greatest asymmetries, a kind of marathon instead of the sprint of other European countries (as observed by Swedish authorities). This also happens for the USA. The Brazilian weekly spreading rate for deaths is lower than most of the European countries at the same stage of the outbreak.

Legal Deposit of Electronic Publications and Other Non-Print Material: An International Overview

1997 ◽  
Vol 9 (1) ◽  
pp. 59-79 ◽  
Author(s):  
Peter Hoare
Keyword(s):  
The Netherlands ◽  
Current Situation ◽  
European Countries ◽  
Print Material ◽  
International Coordination ◽  
The Usa ◽  
Electronic Publications ◽  
The Uk ◽  
West European

In many countries, including the UK, proposals are currently being made for the extension of legal deposit to electronic and other non-print material. Some countries such as Switzerland and the Netherlands have no national legal deposit legislation, though voluntary deposit works well in the latter. Norway has the most advanced legislation, requiring the deposit of all lands of media. In few countries is any range of material actively handled, and a very few deal with online publications. There is scope for international coordination of proposals through such bodies as CDNL, CENL, IFLA and UNESCO. The aim of totally comprehensive collecting of all published material may be accepted as unrealistic, and some selectively is likely to be necessary. The current situation with regard to deposit of non-print material in 11 west European countries, Australia, Canada and the USA is recounted.

Pregnancy in adolescence: incidence and outcome in European countries

1978 ◽  
Vol 10 (S5) ◽  
pp. 101-116 ◽  
Author(s):  
J. P. Deschamps ◽  
G. Valantin
Keyword(s):  
Social Workers ◽  
Sexual Behaviour ◽  
School Health ◽  
The Other ◽  
European Countries ◽  
Pregnancy In Adolescence ◽  
The World ◽  
The Usa ◽  
The Uk ◽  
Clinical Problems

Pregnancy in adolescence is now a very great concern for doctors, teachers and social workers throughout the world and yet about 95% of the publications on this topic have come from the USA. The remainder are mainly from the UK and Scandinavia. Other countries have produced only a small number of papers, focusing mainly on clinical problems such as the pathological events and complications during pregnancy or delivery. In France, the first paper to appear in a paediatric journal was published in 1977 in the French journal of school health (Martin, 1977). On the other hand, teenage magazines often contain articles about sexual behaviour and pregnancy in adolescence. There is now a great concern in the adolescents' press about the problems of sexuality, contraception, abortion and pregnancy, including advertising for pregnancy tests.

Union Autonomy, a Terminal Case in the UK? A Comparison with the Approach in Other European Countries and the USA

1993 ◽  
Vol 15 (3) ◽  
pp. 3-21 ◽  
Author(s):  
Patricia Fosh ◽  
Huw Morris ◽  
Roderick Martin ◽  
Paul Smith ◽  
Roger Undy
Keyword(s):  
European Countries ◽  
The Usa ◽  
The Uk

scholarly journals Analysing and comparing the COVID-19 data: The closed cases of Hubei and South Korea, the dark March in Europe, the beginning of the outbreak in South America

2020 ◽  
Author(s):  
Stefano De Leo ◽  
Gabriel G. Maia ◽  
Leonardo Solidoro
Keyword(s):  
South America ◽  
South Korea ◽  
Early Stage ◽  
Spreading Rate ◽  
European Countries ◽  
Time Interval ◽  
Angular Coefficient ◽  
Infected People ◽  
Time Integral ◽  
Fitting Parameters

The present work is a statistical analysis of the COVID-19 pandemic. As the number of cases worldwide overtakes one million, data reveals closed outbreaks in Hubei and South Korea, with a new slight increase in the number of infected people in the latter. Both of these countries have reached a plateau in the number of Total Confirmed Cases per Million (TCCpM) residents, suggesting a trend to be followed by other affected regions. Using Hubei’s data as a basis of analysis, we have studied the spreading rate of COVID-19 and modelled the epidemic center for 10 European countries. We have also given the final TCCpM curves for Italy and Lombardia. The introduction of the α-factor allows us to analyse the different stages of the outbreak, compare the European countries amongst each other, and, finally, to confront the initial phase of the disease between Europe and South America.MethodsBy dividing the TCCpM curves in multiple sections spanning short time frames we were able to fit each section to a linear model. By pairing then the angular coefficient (α factor) of each section to the total number of confirmed infections at the center of the corresponding time interval, we have analysed how the spreading rate of Covid-19 changes as more people are infected. Also, by modelling the TCCpM curves with an asymmetrical time integral of a Normal Distribution, we were able to study, by fitting progressively larger data ensembles, how the fitting parameters change as more data becomes available.FindingsThe data analysis shows that the spreading rate of COVID-19 increases similarly for all countries in its early stage, but changes as the number of TCCpM in each country grows. Regarding the modelling of the TCCpM curves, we have found that the fitting parameters oscillate with time before reaching constant values. The estimation of such values allows the determination of better parameters for the model, which in turn leads to more trustworthy forecasts on the pandemic development.InterpretationThe analysis of the oscillating fitting parameters allows an early prediction of the TCC, epidemic center and standard deviation of the outbreak. The α factor and the recovered over confirmed cases ratio can be used to understand the pandemic development in each country and to compare the protective measures taken by local authorities and their impact on the spreading of the disease.FundingCNPq (grant number 2018/303911) and Fapesp (grant numebr 2019/06382-9).

Analysing and comparing the COVID-19 data: The closed cases of Hubei and South Korea, the dark March in Europe, the beginning of the outbreak in South America (Preprint)

2020 ◽  
Author(s):  
Stefano De Leo ◽  
Gabriel Gulak Maia ◽  
Leonardo Solidoro
Keyword(s):  
South America ◽  
South Korea ◽  
Early Stage ◽  
Spreading Rate ◽  
European Countries ◽  
Time Interval ◽  
Angular Coefficient ◽  
Infected People ◽  
Alpha Factor ◽  
Fitting Parameters

BACKGROUND The present work is a statistical analysis of the COVID-19 pandemic. As the number of cases worldwide overtakes one million, data reveals closed outbreaks in Hubei and South Korea, with a new slight increase in the number of infected people in the latter. Both of these countries have reached a plateau in the number of Total Confirmed Cases per Million (TCCpM) residents, suggesting a trend to be followed by other affected regions. OBJECTIVE Using Hubei's data as a basis of analysis, we have studied the spreading rate of COVID-19 and modelled the epidemic center for 10 European countries. We have also given the final TCCpM curves for Italy and Lombardia. The introduction of the $\boldsymbol{\alpha}$-factor allows us to analyse the different stages of the outbreak, compare the European countries amongst each other, and, finally, to confront the initial phase of the disease between Europe and South America. METHODS By dividing the TCCpM curves in multiple sections spanning short time frames we were able to fit each section to a linear model. By pairing then the angular coefficient ( factor) of each section to the total number of confirmed infections at the center of the corresponding time interval, we have analysed how the spreading rate of Covid-19 changes as more people are infected. Also, by modelling the TCCpM curves with an asymmetrical time integral of a Normal Distribution, we were able to study, by fitting progressively larger data ensembles, how the fitting parameters change as more data becomes available. RESULTS The data analysis shows that the spreading rate of COVID-19 increases similarly for all countries in its early stage, but changes as the number of TCCpM in each country grows. Regarding the modelling of the TCCpM curves, we have found that the fitting parameters oscillate with time before reaching constant values. The estimation of such values allows the determination of better parameters for the model, which in turn leads to more trustworthy forecasts on the pandemic development. CONCLUSIONS The analysis of the oscillating fitting parameters allows an early prediction of the TCC, epidemic center and standard deviation of the outbreak. The alpha factor and the recovered over confirmed cases ratio can be used to understand the pandemic development in each country and to compare the protective measures taken by local authorities and their impact on the spreading of the disease. INTERNATIONAL REGISTERED REPORT RR2-doi.org/10.1101/2020.04.06.20055327

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