key: cord-280747-k0x6rjdi
authors: Hashim, Muhammad Jawad; Alsuwaidi, Ahmed R.; Khan, Gulfaraz
title: Population Risk Factors for COVID-19 Mortality in 93 Countries
date: 2020-09-17
journal: J Epidemiol Glob Health
DOI: 10.2991/jegh.k.200721.001
sha: 
doc_id: 280747
cord_uid: k0x6rjdi

Death rates due to COVID-19 pandemic vary considerably across regions and countries. Case Mortality Rates (CMR) per 100,000 population are more reliable than case-fatality rates per 100 test-positive cases, which are heavily dependent on the extent of viral case testing carried out in a country. We aimed to study the variations in CMR against population risk factors such as aging, underlying chronic diseases and social determinants such as poverty and overcrowding. Data on COVID-19 CMR in 93 countries was analyzed for associations with preexisting prevalence rates of eight diseases [asthma, lung cancer, Chronic Obstructive Pulmonary Disease (COPD), Alzheimer’s Disease (AD), hypertension, ischemic heart disease, depression and diabetes], and six socio-demographic factors [Gross Domestic Product (GDP) per capita, unemployment, age over 65 years, urbanization, population density, and socio-demographic index]. These data were analyzed in three steps: correlation analysis, bivariate comparison of countries, and multivariate modelling. Bivariate analysis revealed that COVID-19 CMR were higher in countries that had high prevalence of population risk factors such as AD, lung cancer, asthma and COPD. On multivariate modeling however, AD, COPD, depression and higher GDP predicted increased death rates. Comorbid illnesses such as AD and lung diseases may be more influential than aging alone.

The COVID-19 outbreak was first reported at the end of December 2019 from the city of Wuhan in China [1] . Within a short period of just 4 months, SARS-CoV-2, the coronavirus causing COVID-19, had spread to virtually all countries and territories worldwide [1] . In spite of implementing stringent measures such as travel restrictions, social distancing, lockdowns, and increased testing, many countries have struggled to control the spread and minimize the death toll [2] . At individual country level, the number of deaths and Case Fatality Rates (CFR) of confirmed cases vary enormously. This can be due to numerous reasons, including the extent of testing, the measures taken to mitigate the spread, healthcare access, underlying population demographics, socio-economic development and prevalence of comorbidities [3] .

Moreover, different countries are at different stages of the COVID-19 pandemic and CFR can change depending on how each country responds to the epidemic. For example, UK, as of 25th June, had over 306,000 confirmed cases with over 43,000 deaths (CFR: 14.0%). By contrast, Germany had 193,000 cases with just over 9000 death (CFR: 4.6%). A recent study has indicated that SARS-CoV-2 has mutated into several different types which could have different virulence [4] . However, the order of magnitude difference in CFR noted between some countries cannot simply be explained by the variation in the virulence of the virus strains, since some of these countries have the same strain circulating [5] . Although the extent of testing is another obvious factor for these difference, it too does not explain all the differences.

The most common reported predictors of severe COVID-19 include age above 65 years and comorbidities such as cancer, asthma, hypertension and heart disease [6, 7] . Thus, countries with larger older population and/or with higher burden of chronic diseases are expected to have the highest mortality rates. However, it is unclear how mortality rates interact with these reported predictors when examined at country population level by age and prevalence of comorbidities. We chose to analyze Case Mortality Rates (CMR) by country population, rather than by the number of test-positive cases (CFR), since the latter is dependent on the number of tests performed in each country and this varies enormously from country to country [8] [9] [10] . In this study, we aimed to examine CMR for 93 countries against eight diseases and six socio-demographic factors.

We analyzed COVID-19 pandemic data for variations in mortality rates across different countries. Data from Johns Hopkins University Coronavirus Resource Center (https://coronavirus.jhu.edu/data) were obtained on COVID-19 death rates per 100,000 population. These rates were used to classify countries into an elevated risk category. Prevalence data for selected diseases was retrieved from the Global Burden of Disease (GBD) dataset (http://ghdx.healthdata.org/gbd-results-tool). While this expansive dataset includes a wide range of health-related conditions including trauma and congenital birth defects, we limited our analysis to potential risk factors for COVID-19 mortality. These included asthma, Chronic Obstructive Pulmonary Disease (COPD), lung cancer, diabetes, depression, hypertension, Ischemic Heart Disease (IHD) and Alzheimer's Disease (AD). Socio-economic indicators were obtained from the World Bank data (https://databank.worldbank. org/home). Selected indicators were chosen to assess social risk factors for susceptibility. These included Gross Domestic Product (GDP) per capita in US dollars, unemployment rates (percent of workforce), urban population as a percent of total population, population density per square kilometer and population over age 65 years. An additional measure of social development, the Sociodemographic Index (SDI), from GBD was also analyzed. Expressed on a scale of 0 to 1, SDI is the mean ranking of the national income per capita, educational attainment, and fertility rates. Data were merged with multiple error checking steps and redundancies.

Data were analyzed for 93 countries (primarily limited by availability of COVID-19 data). World Bank data from 2018 was used as it had a lower proportion of missing values compared with 2019. Missing values ranged from none (in the GBD data), to three countries (GDP) to 25 (unemployment rates) in the World Bank data. No data transformations were applied. The primary dependent (outcome) variable was COVID-19 death rates (CMR) per 100,000 population. We believe this metric is a more accurate measure than COVID-19 deaths per 100 confirmed cases (CFR) which is heavily dependent on the extent of viral case testing carried out in a country and the reliability of testing [8] [9] [10] . The data was analyzed in three steps: correlation analysis, bivariate comparison of countries, and finally, multivariate modelling.

Statistical data analysis was conducted using Jamovi version 1.1.7 (The jamovi project, 2020, https://www.jamovi.org, Sydney, Australia). Generalized linear model (GAMLj module) was used to evaluate predictors for the dependent variable, CMR. Poisson regression was applied using the Log link function. Log likelihood ratio tests were used to evaluate the predictive performance of each covariate, while R 2 was maximized for overall model error reduction. Backward stepwise process was used to remove covariates with the greatest p-value at each iteration. Covariates were centered but not standardized. A fixed intercept was used. Two-way interaction terms were reviewed; however, none of them were statistically significant. Collinearity among predictor variables was assessed using a correlation matrix and tolerance in linear regression. Oneway ANOVA was used to compare the risk factors in elevated risk versus other countries. Mean differences in rates (including 95% confidence intervals) were obtained as a measure of effect size. A correlation coefficient (cut-off) of <0.25 was considered as indicating lack of statistical association.

Globally, CMR was 10.4 COVID-19 deaths per 100,000 population, with highest rates in Belgium (84.9), Andorra (67. 5 

Country-wise correlations showed an association between total confirmed cases and total COVID-19 deaths (r = 0.93) and between confirmed cases and CMR (r = 0.29). SDI of the countries did not correlate with any of their COVID indicators such as confirmed cases and CMR (r < 0.25). Greater GDP per capita correlated with CMR (r = 0.39) but not with other COVID-19 variables such as number of cases. Having a relatively older population structure with a higher number of over 65 year old persons was associated with more confirmed cases (r = 0.36) and deaths (r = 0.33) but not with CMR. Social overcrowding as measured by population density and urbanization did not correlate with CMR (r < 0.25). From amongst the clinical risk factors, positive correlations with CMR included Alzheimer's disease (r = 0.36), lung cancer (r = 0.39), and weakly with asthma (r = 0.28) and COPD (r = 0.27). These correlations should be interpreted as preliminary exploratory analysis as confounding variables can mediate these findings.

Countries were divided into two groups: those with CMR greater than 25 or more COVID-related deaths per 100,000 population, versus those with fewer deaths. The mean values of predictor variables were compared in these two groups using one-way ANOVA ( Table 1 ). The results were consistent with correlation analysis, reaffirming greater prevalence of AD and respiratory illnesses in countries with high COVID-19 CMR. However, more conclusive inferences were derived using multivariate modeling.

With COVID-19 CMR per 100,000 population as the primary outcome (dependent) variable, multivariate modeling showed that certain risk factors were independent predictors (R 2 = 0.35, log likelihood ratio tests, p < 0.05). These risk factors included Alzheimer's disease, COPD, depression and GDP per capita (Figure 1 ).

Key findings from our analysis highlight certain population risk factors that were associated with COVID-19 mortality. These included chronic respiratory diseases such as lung cancer, asthma and COPD and age-related illnesses like AD. A surprise finding from this study was the strong correlation between AD and COVID-19 death rates. Of the risk factors assessed, AD was a dominant and statistically significant risk factor, even on multivariate analysis (which controls for other risk factors including aging) [6, 11] . Our findings support several recent studies that also point to a positive correlation between COVID-19 severity and neurological disorders, including AD [12] [13] [14] . The details of this association however, remain unknown. It has been reported that the virus has neurotropic characteristics, exploiting the angiotensin-converting enzyme 2 receptor to gain entry into cells of the central nervous system [15] [16] [17] .

Another notable finding from this analysis was that countries with lower socio-economic development and social overcrowding were not associated with higher death rates. One of the major concerns has been the impact this pandemic will have on developing countries with poor infrastructure and healthcare systems. Our analysis appears to give some hope that low socio-economic status does not necessarily mean a guarantee of poor outcome for COVID-19. We must stress however, that our study focused on mortality and not on the risk of transmission. Interestingly, a previous study assessing infectious disease vulnerability scores also indicated that low income status does not necessarily correlate with high vulnerability to infections [18] .

Studies have identified certain comorbidities such as age above 65 and hypertension as important risk factors for increased mortality [6, 19] . Although this may be true when looking at crude figures, analyzing the risk of mortality in multivariate modeling shows only weak correlation. Thus, countries with a higher percentage of older people may witness a higher burden of deaths [19, 20] but this is not because older people are specifically at higher risk of developing severe disease compared with younger individuals in the population. Other clinical risk factors such as co-morbid illnesses, Alzheimer's dementia and chronic lung diseases (COPD) may be more influential.

In a recent systematic review, hypertension and diabetes were reported as leading risk factors for COVID-19 severity [21] . These were followed by cardiovascular diseases and respiratory conditions. It is pertinent to note that data from hospital-based series should not be used to make public health decisions elsewhere as these associations are context dependent. Each medical center receives a unique set of patients depending on referral patterns, pre-hospital care and clinical expertise.

Limitations of our study include the use of secondary data, estimation techniques used by the data sources, accuracy of data estimates and the potential of ecological bias due to confounding by countrylevel analysis. We sought to minimize bias and systematic errors by removing outliers and not relying on case-fatality rates. It is worth mentioning that observational studies on clinical cases suffer from similar confounding effects that are difficult to remove even by adjustment or stratification. Definitive proof via randomized exposure to the causative virus would be unethical. Hence, observational data provide the best available source for public health and clinical decision making.

The current COVID-19 pandemic has exposed some of the weaknesses in the public healthcare systems and lack of preparedness for dealing with infectious disease outbreaks [22] . Emerging and re-emerging infections, particularly due to viruses are not new and COVID-19 is certainly not going to be the last. Previous pandemics such as the 1918 influenza pandemic, famously known as the 'Spanish flu' and the two subsequent influenza pandemics of 1957 and 1968 resulted in millions of deaths [23, 24] . To limit the devastating impact such pandemics can have on human health and healthcare systems, our only options are to be better prepared for such events. One essential component for this preparedness is to have established policies for future pandemics. Early identification, testing, contact tracing, and isolation are fundamental principles of public health that have to be implemented. Determining which groups in a population are at increased risk of severe disease can help to better manage the limited resources and stretched healthcare systems in such situations. Moreover, any planning for lifting the existing lockdown measures should take into consideration these vulnerable groups. This is also true for prioritizing recipients for candidate vaccines against COVID-19.

The authors declare they have no conflicts of interest.

MJH Design of the protocol, acquisition of data, data analysis/ interpretation, preparing first draft and critically reviewing the paper, giving approval for the final version to be published. ARA Critically reviewing the paper, giving approval for the final version to be published. GK Principal investigator and corresponding author, conception/design of the protocol, data analysis/interpretation, preparing first draft and critically reviewing the paper, giving approval for the final version to be published.

This research received no external funding.

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We would like to thank the sources of original data including Johns Hopkins University, Institute of Health Metrics (University of Washington, Seattle) and the World Bank.

Supplementary data related to this article can be found at https:// doi.org/10.2991/jegh.k.200721.001.