key: cord-0817138-gt32u883
authors: Nimgaonkar, Ila; Valeri, Linda; Susser, Ezra; Hussain, Sabiha; Sunderram, Jag; Aviv, Abraham
title: The age pattern of the male-to-female ratio in mortality from COVID-19 mirrors that of cardiovascular disease in the general population
date: 2021-02-07
journal: Aging (Albany NY)
DOI: 10.18632/aging.202639
sha: 827fbadd6ccda9f300ccac0a1f0e7f1103bfb73e
doc_id: 817138
cord_uid: gt32u883

Males are at a higher risk of dying from COVID-19 than females. Older age and cardiovascular disease are also associated with COVID-19 mortality. To better understand how age and sex interact (in) contributing to COVID-19 mortality, we stratified the male-to-female (sex) ratios in mortality by age group. We then compared the age-stratified sex ratios with those of cardiovascular mortality and cancer mortality in the general population. Data were obtained from official government sources in the US and five European countries: Italy, Spain, France, Germany, and the Netherlands. The sex ratio of deaths from COVID-19 exceeded one throughout adult life, increasing up to a peak in midlife, and declining markedly in later life. This pattern was also observed for the sex ratio of deaths from cardiovascular disease, but not cancer, in the general populations of the US and European countries. Therefore, the sex ratios of deaths from COVID-19 and from cardiovascular disease share similar patterns across the adult life course. The underlying mechanisms are poorly understood and warrant further investigation.

More males than females die from COVID-19, the disease caused by SARS-CoV-2. This was first observed in China, where 64% of COVID-19 deaths occurred in males [1] . As the epidemic spread worldwide, other countries similarly observed a higher percentage of deaths from COVID-19 in males [1] . The higher number of deaths among males is consistent with mortality patterns observed in several major viral epidemics/pandemics of the 20 th and 21 st centuries, including the Western African Ebola virus epidemic (2013-2016) [2] and the H1N1 Spanish Flu pandemic of 1918 [3] . Adult men also have an overall higher mortality rate than adult women from seasonal influenza based on data in the US between 1997-2007, with some variation depending on age group and underlying conditions [4] .

In contrast, COVID-19 mortality by age differs from other viral pandemics. More than 80% of COVID-19 deaths in the US and European countries have occurred in adults older than 65 years [5] , with very few deaths in young children [6] . Seasonal influenza causes relatively more pediatric deaths, especially in infants under the age of six months [7] , in addition to a disproportionate number of deaths in older adults over the age of 65 years [8] . Several major viral pandemics of the 20 th and AGING 21 st centuries have also shown different age-based mortality patterns from COVID-19. For instance, in the Spanish Flu of 1918 a large proportion of deaths were in young adults [9] , and in the 2009 H1N1 influenza pandemic a large proportion occurred in children and adults under 60 years [10] . Therefore, COVID-19 mortality trends are consistent with sex-based, but not with age-based patterns seen in many other viral pandemics.

In searching for explanations for the distinctive pattern of deaths in COVID-19, we first examined variation by age group in the male-to-female (sex) ratio of mortality in data from the US and five European countries. Given that cardiovascular disease (CVD) has been strongly associated with increased risk of mortality in COVID-19 [11] , we next examined variation in the sex ratio of CVD mortality by age group in the same countries. As CVD and cancer are the two major age-related disease categories that largely determine survival of adults in middle-and-high income societies [12] , we further examined variation by age in the sex ratio of cancer mortality. Here we report our findings and offer potential explanations regarding their meaning.

Stratified by age, and adjusted for population at risk in each age group (Supplementary Figure 1,  Supplementary Table 2) , the sex ratios for COVID-19 deaths among adults in the US and five European countries (Italy, Spain, France, Germany, and the Netherlands) showed similar overall patterns, initially rising to a peak in midlife and then falling ( Figure 1 ). Specifically, the sex ratio of mortality peaked between the ages of 35-44 years in the US and 60-69 years in the European countries, and then progressively declined at older ages without dropping below one. We next examined the sex ratio of CVD mortality by age in these countries ( Figure 2 , Supplementary Figure  2 ). The sex ratio for CVD mortality initially rose to a peak in midlife and then declined, in both the US and Europe. For ages younger than 70 years, the sex ratio for CVD mortality in Europe was higher than in the US.

As cancer is the other leading cause of adult mortality in the US and Europe [13], we also examined the sex ratio for cancer mortality by age ( Figure 3 , Supplementary  Figures 3, 4) . The sex ratio for cancer mortality increased after midlife with no evidence of decline thereafter.

When the sex ratios of mortality by age for COVID-19, CVD and cancer were overlaid, the COVID-19 profile mirrored that of CVD, although, the sex ratio for CVD was much higher in Europe than the US for ages younger than 70 years ( Figure 4 ). The profile of the sex ratio by age for cancer mortality, however, clearly differed from the ratios for COVID-19 and for CVD.

Our key findings are as follows: (i) for all age groups, the death rate from COVID-19 was higher in males than females; (ii) the sex mortality ratio for COVID-19 rose to a peak in midlife and then narrowed with increasing age; and (iii) the sex mortality ratio for COVID-19 by age mirrored that for CVD but not cancer. Since the COVID-19 data were not linked to population databases with individual-level health information, we could not specifically examine the potential contribution of CVD to the age pattern of the sex mortality ratio from COVID-19. We propose, nonetheless, based on data displayed in Figure 4 , that the sex ratio for COVID-19 mortality, particularly for adults older than 60 years, might partially reflect the mechanisms that drive the age pattern of the sex mortality ratio for CVD in the general population.

What then might be these mechanisms? The underlying biological reasons are likely multifactorial and complex. We review several potential explanations: pre-existing cardiovascular risk factors, sex hormones, and X chromosome mosaicism.

Early available clinical data suggest that patients who become critically ill from COVID-19 are more likely to have pre-existing CVD risk factors such as hypertension and diabetes than patients who experience a milder disease course [14, 15] . Certain CVD risk factors also show different prevalence rates among males and females. For example, hypertension rates are higher in males than in females under the age of 60, but are not significantly different at ages 60 and over [16] . Males also have higher rates of both diagnosed and undiagnosed cases of diabetes, and typically develop atherosclerotic disease earlier than females [17] . These patterns for hypertension and atherosclerotic disease, which occur at higher rates in younger males and at more equal rates at older ages, share similarities with the sex ratios observed for COVID-19 and CVD mortality, and may partially explain the age pattern of the sex ratio in COVID-19 mortality. Though suggestive by our findings, definitive studies are needed to establish direct links between CVD risk factors and COVID-19 mortality.

Endogenous estrogens have been associated with a protective effect against CVD in premenopausal women [18] , while predisposing women to certain cancers [19] .

Higher estrogen [20] and progesterone [21] levels in premenopausal women might also modulate immune responses and attenuate the severity of COVID-19. In this regard, data from the US show a decline in the sex ratio of COVID-19 mortality after ages 45-54 years, AGING which coincides with the average age that women undergo menopause [22] . However, the data from the European countries show a drop in the sex ratio of COVID-19 mortality starting in the 60-69-year age group-later than the average age of menopause. Clinical trials are currently investigating whether estrogen or progesterone treatment can alleviate COVID-19 symptoms, which may provide more clarity to the role of ovarian hormones in COVID-19 pathogenesis (https://www.clinicaltrials.gov/ identifiers NCT04359329, NCT04365127).

Androgen increases the expression of TMPRSS2 [23] , a gene encoding Type II Transmembrane Serine Protease AGING (TMPRSS2) which activates the SARS-CoV-2 spike protein, facilitating SARS-CoV-2 entry into cells [24] . A recent study suggests that androgen-deprivation therapies lowers the risk of SARS-CoV-2 infection [25] . Since testosterone level decreases with age, a higher level of the hormone in young and middle age men may upregulate TMPRSS2 and thus contribute to the higher sex ratio for COVID-19 mortality before the sixth decade. That said, the knowledge of the effect of testosterone replacement therapy on the cardiovascular system is incomplete [26] .

The two X chromosomes provide an advantage related to X-linked recessive diseases and other potentially deleterious mutations on the X chromosome. Random inactivation in utero of one X chromosome in each somatic cell engenders mosaicism that provides females with somatic cell diversity and the potential for selection of cells with an X chromosome harboring advantageous variant genes [27] . X chromosome mosaicism might be particularly advantageous for surviving infectious disease, since the X chromosome harbors a number of genes engaged in immune function [28] therefore having two copies of these genes confers additional immunological diversity in women [29] . In addition, ACE2, the gene encoding angiotensinconverting enzyme 2, the cellular receptor for SARS-CoV-2 is on the X chromosome [30] . ACE2 variants might play a role in left ventricular hypertrophy that is often the outcome of hypertension [31] , which tracks with age [32] . Some of these variants might also influence CVD [33] , but no association of ACE2 polymorphisms with COVID-19 was observed thus far [34, 35] .

Limitations to this study include: (a) potential differences in reporting COVID-19 deaths between the countries analyzed; (b) the lack of linked individuallevel health and social databases; and (c) no information on the sex ratio of survival rates among people who acquired COVID-19. The latter would require, at a minimum, COVID-19 infection rates by age and sex in the general population (including asymptomatic infections) in order to determine whether there are sex-and age-based differences in survival from it.

Additionally, the study does not account for nuanced differences in the overall similar patterns for COVID-19 and CVD in the United States versus Europe. The peak sex ratio for COVID-19 occurs at an earlier age in the United States than Europe, and the sex ratio for CVD mortality is higher for Europe than the United States until the older age groups. Finally, we could not rule out that the lower sex ratios in COVID-19 and CVD for the oldest age groups were partly due to selection, in that males who survive to an exceptionally old age are "escapers" who hardly represent the general population of older males; in contrast, females who survive to such an old age might be "delayers" who largely represent the general population of older females [36, 37] .

Our analyses show similar trends in the sex ratio by age of mortality from COVID-19 and from CVD. We propose that these findings might be due to some shared underlying biological mechanisms. Individual-level data are essential to examine potential shared mechanisms and to establish the potential contribution of CVD to the age patterning of the sex ratio of mortality in COVID-19. We suggest that this line of research should be pursued and might uncover some of the causal mechanisms underlying COVID-19 mortality.

We focused our analysis on the US, Italy, Spain, France, Germany, and the Netherlands because of (a) availability of their sex-and age-disaggregated mortality data from COVID-19, (b) data stratification into age group bins of 10 years or less, and (c) a high number of cumulative deaths from COVID-19 (sources are shown in Supplementary Table 1) . COVID-19 mortality data were retrieved from national databases including the US Centers for Disease Control, the Italian National Institute of Health, the French Institute for Demographic Studies, the Spanish Ministry of Health, the German Federal Ministry of Health, and the Dutch Ministry for Health, Welfare and Sport. The data were retrieved on October 14 th , 2020 and reflect the cumulative COVID-19 deaths in each country from the beginning of the pandemic up to dates between May 22 nd -October 13 th 2020 (see Supplementary Tables 1,  2 for details). (Note that after May 22 nd , the Spanish Ministry of Health stopped providing sex-and agedisaggregated data on COVID-19 deaths [38] .) In the US, data were included for age groups 25 years and older, and stratified into 10-year bins. For the European Countries, data were included for age groups 30 years and above and stratified into 10-year bins, and deaths were combined across the five countries by age group and sex. Age groups below 25 years were excluded from the analysis due to the smaller number of cases. The population at risk in each age group was retrieved from populationpyramid.net, a website that aggregates data from the United Nations Department of Economic and Social Affairs, Population Division.

For the analysis of mortality from CVD and cancer, data were extracted from the World Health Organization Mortality Database (https://www.who.int/healthinfo/ mortality_data/en/), which collects national data on deaths from civil registries. The Database contains number of deaths by country, year, sex, age group and cause of death, and population size by country, year, sex and age group. The causes of death are categorized by International Classification of Disease (ICD)-10 codes. CVD deaths principally included deaths from coronary heart disease (ICD-10 codes I20-I25) or stroke (I60-I69) [39] . Cancer death data included deaths from all neoplasms (C00-C97, D00-D48) (Supplementary Table  3 ). The non-sex-biased cancers (Supplementary Figure  4 Tables 4-6 ). Population adjustment was done using population data from the same years as the mortality data. These population data were also extracted from the World Health Organization Mortality Database.

Plots and data visualizations were created using the ggplot2 package in R (https://ggplot2.tidyverse.org).

I.N., L.V., E.S. and A.A. provided substantial contributions to the design of the study. I.N. and A.A. wrote the first draft of the manuscript. All coauthors provided substantial contributions to the analysis and interpretation of data, critically reviewed the manuscript for important intellectual content, provided final approval of the version to be published, and agree to be accountable for all aspects of the work presented.

The authors declare that they have no conflicts of interest.

Supplementary Figure 1 . Ratios of male to female deaths from COVID-19 (raw data) for the (A) United States, and (B) combined ratios for five European countries: Italy, France, Spain, Germany, and the Netherlands. A 1:1 ratio is indicated by white markers. Numbers below plots indicate number of male deaths (turquoise) and female deaths (orange).

Ratios of male to female deaths from cardiovascular disease (raw data) for the (A) United States, and (B) combined ratios for five European countries: Italy, France, Spain, Germany, and the Netherlands. A 1:1 ratio is indicated by white markers. Numbers below plots indicate number of male deaths (turquoise) and female deaths (orange). Note that y-axes have different scales. 

COVID-19 sex-disaggregated data tracker

and WHO Ebola Response Team. Ebola virus disease among male and female persons in West Africa

The 1918 influenza epidemic's effects on sex differentials in mortality in the United States

Age-and sex-related risk factors for influenza-associated mortality in the United States between 1997-2007

Department of Health and Human Services

CDC COVID-19 Response Team. Coronavirus disease 2019 in children -United States

Influenza-associated pediatric deaths in the United States

Department of Health and Human Services

1918 influenza: the mother of all pandemics

and Writing Committee of the WHO Consultation on Clinical Aspects of Pandemic (H1N1) 2009 Influenza. Clinical aspects of pandemic 2009 influenza a (H1N1) virus infection

COVID-19 and the cardiovascular system: implications AGING for risk assessment, diagnosis, and treatment options

From causes of aging to death from COVID-19

COVID-19 and cardiovascular disease: from basic mechanisms to clinical perspectives

and China Medical Treatment Expert Group for Covid-19. Clinical characteristics of coronavirus disease 2019 in China

Hypertension prevalence among adults aged 18 and over: United States

Sex as a biological variable in atherosclerosis

The effects of oestrogens and their receptors on cardiometabolic health

Endogenous estrogens and the risk of breast, endometrial, and ovarian cancers

Sex and gender differences in health: what the COVID-19 pandemic can teach us

Progesterone-based compounds affect immune responses and susceptibility to infections at diverse mucosal sites

Age at natural menopause in Spain and the United States: results from the DAMES project

Prostate-localized and androgen-regulated expression of the membranebound serine protease TMPRSS2

SARS-CoV-2 cell entry depends on ACE2 and TMPRSS2 and is blocked by a clinically proven protease inhibitor

Androgen-deprivation therapies for prostate cancer and risk of infection by SARS-CoV-2: a population-based study (N = 4532)

Testosterone replacement therapy and cardiovascular risk

Why females are mosaics, x-chromosome inactivation, and sex differences in disease

Sex differences in immune responses

The X chromosome in immune functions: when a chromosome makes the difference

ACE2 receptor polymorphism: susceptibility to SARS-CoV-2, hypertension, multi-organ failure, and COVID-19 disease outcome

Association of angiotensinconverting enzyme 2 (ACE2) gene polymorphisms with parameters of left ventricular hypertrophy in men. Results of the MONICA augsburg echocardiographic substudy

Age related prevalence of severe left ventricular hypertrophy in essential hypertension: echocardiographic findings from the ETODH study

The ACE2 gene: its potential as a functional candidate for cardiovascular disease

ACE2 and TMPRSS2 variants and expression as candidates to sex and country differences in COVID-19 severity in Italy

Lack of association between genetic variants at ACE2 and TMPRSS2 genes involved in SARS-CoV-2 infection and human quantitative phenotypes

Male centenarians: how and why are they different from their female counterparts?

Becoming centenarians: disease and functioning trajectories of older US adults as they survive to 100

The need for detailed COVID-19 data in Spain

Sex differences in coronary heart disease and stroke mortality: a global assessment of the effect of ageing between

 Please browse Full Text version to see the data of Supplementary Table 3 

Year Sex 0-9 10-19 20-29 30-39 40-49 50-59 60-69 70-79 80-89  90+  Netherlands  2016  F  1  0  4  15  92  248  600  1523  3953  2715  Netherlands  2016 M  0  1  9  26  150  524  1371  2414  3410  1091  Germany  2015  F  7  11  33  86  488  1654  4004 15749 41202 30116  Germany  2015 M  6  8  52  247  1473 5720 11281 27166 35472 10437  Italy  2015  F  11  6  23  73  278  828  2300  8775 32644 28310  Italy  2015 M  10  11  39  207  954  2698  6127 13858 26324