Annals of Public Health Reports

ISSN: 2642-4924

Review Article | Volume 4 | Issue 1 | DOI: 10.36959/856/508 Open Access

Does Nature Have a Systematic Sex Bias: Prevalence, Mortality, and Trend of COVID-19

Niharika Srivastava, Arinjita Bhattacharyya, Anand Seth, Shesh N Rai

  • Niharika Srivastava 1#
  • Arinjita Bhattacharyya 2#
  • Anand Seth 3*
  • Shesh N Rai 2,4,5,6*
  • Arnold School of Public Health, University of South Carolina, Columbia, SC, USA
  • Department of Bioinformatics and Biostatistics, University of Louisville, Louisville, KY, USA
  • SK Patent Associates, LLC, Dublin, Ohio, USA
  • Biostatistics and Bioinformatics Facility, JG Brown Cancer Center, University of Louisville, Louisville, KY, USA
  • The Christina Lee Brown Envirome Institute, University of Louisville, Louisville, KY, USA
  • University of Louisville Alcohol Research Center, Louisville, KY, USA
#These authors contributed equally to this work.

Srivastava N, Bhattacharyya A, Seth A, et al. (2020) Does Nature Have a Systematic Sex Bias: Prevalence, Mortality, and Trend of COVID-19. Ann Public Health Reports 4(1):129-135.

Accepted: December 17, 2020 | Published Online: December 19, 2020

Does Nature Have a Systematic Sex Bias: Prevalence, Mortality, and Trend of COVID-19

Abstract


Background

The unprecedented outbreak of a contagious respiratory disease similar to pneumonia caused by a novel coronavirus termed as COVID-19 has led to a pandemic claiming millions of lives worldwide. Potential vaccine candidates are underdevelopment to contain and mitigate the spread of global cases and deaths. Preliminary reports suggest that males and females are affected in cases and deaths differentially.

Objective

To study the statistical significance of sex and gender bias in COVID-19 infection and deaths across 75 selected countries in the world, specifically for the United States.

To summarize, the prevalence and incidence rates of this infectious disease globally segmented by developed, developing, and transitioning countries.

Methods

Data on sex are collected from the sex-disaggregated data tracker Global Health 50/50, University College London until September 21, 2020, UN COVID-19 and gender monitor, and CDC COVID data tracker. The hypothesis was tested using the binomial proportion test to be 50% within males and females for infection rate and mortality. Prevalence and Incidence rates by sex are illustrated graphically.

Results

Females in countries with transitioning and developed economies have a higher number of cases and deaths than males, but in developing countries, males have high mortality due to coronavirus. Also, men are at greater risk of worse outcomes if infected with the SARS-Cov-2 virus, including mortality. The differential effect of gender in death counts in the US is statistically significant, with reported p-values < 0.05. In the oldest US population (85+ years), female's death rate is higher due to the virus. Monthly deaths in the US was at its peak during March - April 2020 for both sexes.

Conclusion

Clinical researchers, health insurance planners can follow the suggested approach outlined here to target a specific population for inaugural vaccination and immunization. Although everyone should follow the CDC guidelines of prevention, it is recommended that the females strictly follow the CDC guidelines due to a higher rate of Covid-19 infection. Also, the effect of age is delineated to help vaccine administration priority.

Keywords


COVID-19 review, Coronavirus, SARS-Cov-2, Pandemic, Gender, Clinical trials, Sex, Mortality, Prevalence rate, Cancer, Demographics, P-Value, Statistical significance, Case fatality rate

Introduction


In late December 2019, clusters and community transmission of peculiar pneumonia cases arose in Wuhan, Hubei province of China [1]. It soon started spreading over hundreds of countries, and this 'severe acute respiratory syndrome coronavirus 2' (SARS-CoV-2) virus was declared a global pandemic in March. COVID-19, officially named by World Health Organization (WHO), has a total case count of 30,175,496 cases and 944,887 deaths as of September 22, 2020, according to John Hopkins's Coronavirus Resource Center [2]. The rapid spread of the disease at a pandemic speed can only end with the rapid development of vaccines and therapeutics. Potential vaccine candidates are under development from major pharmaceutical companies and several universities around the world. To increase the impact of vaccine and therapeutic intervention and better inform the clinical researchers that sex and other critical demographics should be considered in designing clinical trials [3]; this research aimed to provide a lucid yet constructive and systematic summary of the significance of sex and the impact of COVID-19 on gender roles.

Often sex and gender are used interchangeably. Sex is a biological characteristic that defines males and females, and gender refers to the roles, behaviors, and activities that societies define for men and women [4]. Males and females differ at many biological levels starting from their DNA structure as males have XY chromosomes and female have XX chromosomes. In the case of an X-linked mutation, it will be expressed in half of the female cells and all the male cells; therefore, males have a higher rate of X-linked immunodeficiencies than females. Further, men and women have different reproductive organs and hormone levels. Gender roles differ by society, and they can impact how an individual is educated, seeks healthcare, or is exposed to certain infectious diseases. Both the biological and social roles of men and women play a role in the spread and impact of infectious diseases. Sex-based differences are prominent in epidemiology, clinical manifestations progression, course, and therapy of disease [5] with varying hormonal levels, the reproduction potential in women makes them more susceptible to many infectious diseases. For instance, there is rare evidence for intrauterine infection caused by vertical transmission or transplacental transmission in women who develop COVID-19 pneumonia during late pregnancy, but a single case of severe maternal presentation makes the possibility of vertical transmission [6,7] irrefutable. Currently, there is no evidence to believe that pregnant women are at increased risk of Covid-19 [8,9].

Nevertheless, baseline characteristics like sex, gender, and age should be considered in COVID-19 research. In this research work, we discuss and statistically prove that the global outbreak is modified by sex, gender, and age. To better inform clinicians and health planners, this detailed study on the association of demographics is deemed necessary. The rest of the article includes sections i) Materials and Methods, which has the data collection and statistical methods used for analysis; ii) Results where the findings from multiple data sources are illustrated in tabular and graphical forms; iii) Discussion section elaborates the findings and data-driven reasoning and justifications are provided.

Materials and Methods


Data were collected from the different sources for assessing the gender- bias in infection rate and mortality due to the Coronavirus in the United States population: Global Health 50/50. COVID-19 Sex-disaggregated Data Tracker (https://globalhealth5050.org/the-sex-gender-and-covid-19-project/) updated upto September 21, 2020. United Nations COVID-19 and gender monitor (https://data.unwomen.org/COVID19) provided the sex-specific data and further supplemented by the Centers for Disease Control and Prevention (CDC) COVID Data Tracker (https://covid.cdc.gov/covid-data-tracker/#demographics).

Binomial proportion test of significance assessed the following hypotheses: a) Is sex a highly significant factor in determining its differential effect in COVID cases and deaths globally?; b) Are females in developing countries less prone to infection?; c) Are monthly deaths in the US are statistically significant?

No adjustment for multiple comparisons was made since we are drawing inferences at each country level.

Daily Case Incidence rate (IR) and prevalence (P) as of September 23, 2020, for the first six most affected countries (USA, India, Brazil, Colombia, Peru, Mexico) and three recovered countries (China, South Korea, Italy) are obtained.

Results


The data from Global 50/50 consists of 275 countries, of which only 27% have reported sex-disaggregated data, and 18% can be categorized as having reported partial data with either death percentage or case percentage. According to three economies based on the United Nations' World Economic Situation and Prospectus (WESP) [10], the countries are segregated within three economies. Transitioning economies like Russia, Belarus, developed economies like New Zealand, Japan, Singapore have none to partial sex-disaggregated data on Covid-19, while developing countries like India, China and South Korea have reported data on both the cases and deaths. Table 1 shows that females have a higher number of cases in transitioning and developed economies, while in developing countries, males have a higher number of cases.

Table 2 and Table 3 categorize countries by statistical significance (highly significant, significant, and not significant) Covid-19 cases and deaths by sex and by type of world economy. United States, India, China, European countries like France and Sweden, irrespective of their economic dissimilarity, have noteworthy sex differences, and are statistically significant.

Table 4a presents the countries with a larger number of female cases and deaths, and Table 4b has low female cases. There is hardly any difference in infection rates among males and females in developed countries.

Figure 1 shows a higher female case prevalence in the US, Italy, South Korea, and Brazil. Death prevalence is consistently higher for males across countries. Figure 2 concentrates on the sex distribution by age for the US, with female mortality increasing after (85+ years). There is not much difference in Covid-19 related deaths between males and females.

Finally, Figure 3 shows the monthly deaths by sex in the US with a peak in March-April. Though the monthly deaths taper off in September, the presence of death lag behind surging infections may be a reason, but researchers anticipate a rising trend with the onset of fall and winter season in addition to the flu season. As of September 28, the daily incidence rates are 2.4 and 6.07 per 1000,000 for the USA and India.

Discussion


Significant sex differences in Covid-19 cases have been noted in various studies across the world [11]. As the sex- disaggregate data (37% of the confirmed cases, as of July 2020) started getting reported mostly in the developed economies with few exceptions, we considered data from countries over the world and the association of age and sex. Higher mortality risk for men became apparent during the first few months of the pandemic, especially in China [12]. Prevalence of COVID-19 in men and women in the USA and other case series from other parts of the world, death rates differed between males and females. The odds ratio of cases in males vs. females is 1.1; that of hospitalizations is 1.3, ICU admissions are 1.8, deaths are 1.4, so for every ten females, there are 11 male cases globally, based on Global Health analysis 50/50 data. Based on the above statistics, it is recommended that the researchers include sex and gender as important analytical variables in designing drug and vaccine clinical trails. It is evident that sex and gender have major roles in any kind of disease, and Covid-19 is no exception. SARS-CoV-2 infects host cells through Angiotensin-converting enzyme 2 (ACE2) receptors, leading to coronavirus disease (COVID-19)-related pneumonia, highly expressed in males and also causing acute myocardial injury and chronic damage to the cardiovascular system [13]. Heart diseases are more common in men than women due to frequent smoking (35%, 6%), alcohol consumption, and air-pollution prone work environment, so that ACE2 enzyme expression may be one of the biological evidence of high mortality in men. There are several biological evidences and theories for the high mortality in men. The frequent occurrence of endothelial dysfunction as a risk of cardiovascular disease in men with erectile dysfunction and type 2 diabetes, coagulopathy, highly expressed TNFSF13b (BAFF) cytokine proteins leading to increased inflammation and progression of COPD [14]. Females with higher expression of TLR7 and TLR8 genes active on both X-chromosomes, responsible for immune responses, whereas, in men, there is just a single copy. At the same time, gender differences and inequality have widened for women. One study [15], using single-cell sequencing, found that expression of ACE2 was more predominant in Asian men, which might be why the higher prevalence of COVID-19 in these Asian male patients than in women patients as compared to other ethnicities. A study with 140 patients with COVID-19 in China [16] found the sex distribution to be equal. In a study of critically ill patients [17], more men were affected (67%) than women. In the latest report [18] of 1099 patients with COVID-19 from 552 hospitals in 30 provinces in China, 58% were men. The data seem to indicate that there might be a sex predisposition to COVID-19, with men more prone to being affected [19]. It is noticeable that there is a striking disparity in the number of cases and deaths between females and males in developing countries. The trend of the low-case and death percentage in females is apparent in South-Asian countries where the women labor force is low (< = 25%) like Afghanistan (21.4%), Bangladesh (30.5%), Pakistan (20.3%), Yemen (7.7%), with data derived from World Bank [20]. The women from these countries are less in the workforce. Their attire may also confer an advantage in having a lower percentage of cases, despite the sex ratio to be 0.98:1.0 [21]. The high percentage of female positives in developing countries like South Korea (Republic of Korea) and South Africa are in the high-income and the upper-middle-income group as per United 'Nation's 2020 World Economic situation prospectus (WESP) [10] with the percentage of the woman labor force being 42.1% and 45.4% respectively than other developing economies. So, there is an imminent increase in virus exposure among working women in these countries. Also, the first study in South Korea did report the number of cases to be high in females, with mainly four clusters: of the church (first case, a woman), gym and fitness classes in Cheonan (all women) [22], hospital and pilgrimage [23]. Gender inequality has been further widened by this pandemic, with United Nations for Women reporting marginalized groups being more prone to death like Black women have 4.3% and two-times higher mortality than white women in the United Kingdom and Brazil, respectively. Loss of working hours in Asia and Pacific, job losses in Europe and Central Asia, 80% of domestic workers, accommodation, and domestic sectors are evident more in women than men [24]. Globally, 70% of healthcare workers are females, with three times higher infection rates. Several instances of increased domestic violence due to social distancing and house confinement in Tunisia, New Zealand [25], and intensified unpaid care and domestic workloads, along with school closures, have imposed challenges in maintaining work-life balance [26].

There is also a constant gender bias in leadership positions, primarily in Asian-African countries, in minority groups, with women of color, be it in senior management business positions, political leadership, discrimination in equal pay, equal rights, or even household chores and a constant fight for gender equality (50/50) in all aspects. Interestingly, there is still hope in demolishing these stereotypes slowly but permanently when research shows that countries with political leadership as female presidents (women heads of states) like New Zealand, Finland, Bangladesh, Denmark, tend to have better public health metrics based on testing and number of positive cases, reproduction number (R0) [27]. This study will help clinical researchers incorporate sex and gender appropriately while designing Covid-19 clinical trials and targeting age-sex specific populations for future vaccination programs, allocating medical resources. Investment in sex and age-segregated data collection should be prioritized.

Acknowledgments


This work was supported by the National Institute of Health grant P42 ES023716 to the principal investigator: Dr. S Srivastava, the National Institute of Health grants 1P50 AA024337 and 1P20 GM113226 to the principal investigator: Dr. Craig McClain, and 1P30ES030283 to the principal investigator Dr. C States. Dr. Rai, Wendell Cherry Chair in Clinical Trial Research, has also partially supported the research. Except for Dr. Rai, the funders had no role in study design, data collection, analysis, decision to publish, or manuscript preparation.

Author's Contribution


AB has contributed towards analysis, data collection, and preparation of graphics, and writing the manuscript. NS conducted a preliminary analysis to identify data trends and understand the mechanism. AS and SNR have contributed with valuable comments, developing ideas, editing. All the authors have contributed to the final preparation of the manuscript.

Competing Interests


The authors declare no competing interests.

References


  1. Huang C, Wang Y, Li X, et al. (2020) Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. Lancet 395: 497-506.
  2. (2020) COVID-19 Map - Johns Hopkins Coronavirus Resource Center.
  3. Scully EP, Haverfield J, Ursin RL, et al. (2020) Considering how biological sex impacts immune responses and COVID-19 outcomes. Nat Rev Immunol 20: 442-447.
  4. Regitz-Zagrosek V (2012) Sex and gender differences in health. Science & society series on sex and science. EMBO Rep 13: 596-603.
  5. Federman DD (2006) The biology of human sex differences. N Engl J Med 354: 1507-1514.
  6. Alzamora MC, Paredes T, Caceres D, et al. (2020) Severe COVID-19 during pregnancy and possible vertical transmission. Am J Perinatol 37: 861-865.
  7. Zaigham M, Andersson O (2020) Maternal and perinatal outcomes with COVID-19: A systematic review of 108 pregnancies. Acta Obstet Gynecol Scand 99: 823-829.
  8. Chen L, Li Q, Zheng D, et al. (2020) Clinical characteristics of pregnant women with Covid-19 in Wuhan, China. N Engl J Med 382: e100.
  9. Karimi-Zarchi M, Neamatzadeh H, Dastgheib SA, et al. (2020) Vertical transmission of coronavirus disease 19 (COVID-19) from infected pregnant mothers to neonates: A review. Fetal and Pediatric Pathology 39: 246-250.
  10. (2020) World Economic Situation and Prospects as of mid-2020. Department of Economic and Social Affairs.
  11. Li L quan, Huang T, Wang Y qing, et al. (2020) COVID-19 patients’ clinical characteristics, discharge rate, and fatality rate of meta-analysis. J Med Virol 92: 577-583.
  12. Jin J-M, Bai P, He W, et al. (2020) Gender differences in patients with COVID-19: Focus on severity and mortality. Front Public Heal 8: 152.
  13. Zheng YY, Ma YT, Zhang JY, et al. (2020) COVID-19 and the cardiovascular system. nature reviews cardiology 17: 259-260.
  14. White A, Kirby M (2020) COVID-19: Biological factors in men’s vulnerability. Trends Urol Men’s Heal 11: 7-9a.
  15. Zhao Y, Zhao Z, Wang Y, et al. (2020) Single-cell RNA expression profiling of ACE2, the putative receptor of Wuhan 2019-nCov. bioRxiv.
  16. Zhang J jin, Dong X, Cao Y yuan, et al. (2020) Clinical characteristics of 140 patients infected with SARS-CoV-2 in Wuhan, China. Allergy Eur J Allergy Clin Immunol 75: 1730-1741.
  17. Yang X, Yu Y, Xu J, et al. (2020) Clinical course and outcomes of critically ill patients with SARS-CoV-2 pneumonia in Wuhan, China: A single-centered, retrospective, observational study. Lancet Respir Med 8: 475-481.
  18. Chen H, Guo J, Wang C, et al. (2020) Clinical characteristics and intrauterine vertical transmission potential of COVID-19 infection in nine pregnant women: A retrospective review of medical records. Lancet 395: 809-815.
  19. Cai H (2020) Sex difference and smoking predisposition in patients with COVID-19. The Lancet Respiratory Medicine 8: e20.
  20. (2020) Labor force, female (% of total labor force). The World Bank.
  21. Bäcker A (2020) The less women get sick from COVID-19, The more they die from it if they do: Islamic countries have lower relative female COVID-19 morbidities and higher relative female COVID-19 fatality rates. SSRN.
  22. Jang S, Han SH, Rhee JY (2020) Cluster of Coronavirus disease associated with fitness dance classes, South Korea. Emerg Infect Dis 26: 1917-1920.
  23. Shim E, Tariq A, Choi W, et al. (2020) Transmission potential and severity of COVID-19 in South Korea. Int J Infect Dis 93: 339-344.
  24. Aponte MS, Aiello C, Gordillo J, et al. (2020) A once-in-a-century pandemic.
  25. Bradbury-Jones C, Isham L (2020) The pandemic paradox: The consequences of COVID-19 on domestic violence. J Clin Nurs 29: 2047-2049.
  26. Daniela Del Boca, Noemi Oggero, Paola Profeta, et al. (2020) Women’s work, housework and childcare, before and during Covid-19. SSRN.
  27. Purkayastha S, Salvatore M, Mukherjee B (2020) Are women leaders significantly better at controlling the contagion during the COVID-19 pandemic? J Heal Soc Sci 5: 231-240.

Abstract


Background

The unprecedented outbreak of a contagious respiratory disease similar to pneumonia caused by a novel coronavirus termed as COVID-19 has led to a pandemic claiming millions of lives worldwide. Potential vaccine candidates are underdevelopment to contain and mitigate the spread of global cases and deaths. Preliminary reports suggest that males and females are affected in cases and deaths differentially.

Objective

To study the statistical significance of sex and gender bias in COVID-19 infection and deaths across 75 selected countries in the world, specifically for the United States.

To summarize, the prevalence and incidence rates of this infectious disease globally segmented by developed, developing, and transitioning countries.

Methods

Data on sex are collected from the sex-disaggregated data tracker Global Health 50/50, University College London until September 21, 2020, UN COVID-19 and gender monitor, and CDC COVID data tracker. The hypothesis was tested using the binomial proportion test to be 50% within males and females for infection rate and mortality. Prevalence and Incidence rates by sex are illustrated graphically.

Results

Females in countries with transitioning and developed economies have a higher number of cases and deaths than males, but in developing countries, males have high mortality due to coronavirus. Also, men are at greater risk of worse outcomes if infected with the SARS-Cov-2 virus, including mortality. The differential effect of gender in death counts in the US is statistically significant, with reported p-values < 0.05. In the oldest US population (85+ years), female's death rate is higher due to the virus. Monthly deaths in the US was at its peak during March - April 2020 for both sexes.

Conclusion

Clinical researchers, health insurance planners can follow the suggested approach outlined here to target a specific population for inaugural vaccination and immunization. Although everyone should follow the CDC guidelines of prevention, it is recommended that the females strictly follow the CDC guidelines due to a higher rate of Covid-19 infection. Also, the effect of age is delineated to help vaccine administration priority.

References

  1. Huang C, Wang Y, Li X, et al. (2020) Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. Lancet 395: 497-506.
  2. (2020) COVID-19 Map - Johns Hopkins Coronavirus Resource Center.
  3. Scully EP, Haverfield J, Ursin RL, et al. (2020) Considering how biological sex impacts immune responses and COVID-19 outcomes. Nat Rev Immunol 20: 442-447.
  4. Regitz-Zagrosek V (2012) Sex and gender differences in health. Science & society series on sex and science. EMBO Rep 13: 596-603.
  5. Federman DD (2006) The biology of human sex differences. N Engl J Med 354: 1507-1514.
  6. Alzamora MC, Paredes T, Caceres D, et al. (2020) Severe COVID-19 during pregnancy and possible vertical transmission. Am J Perinatol 37: 861-865.
  7. Zaigham M, Andersson O (2020) Maternal and perinatal outcomes with COVID-19: A systematic review of 108 pregnancies. Acta Obstet Gynecol Scand 99: 823-829.
  8. Chen L, Li Q, Zheng D, et al. (2020) Clinical characteristics of pregnant women with Covid-19 in Wuhan, China. N Engl J Med 382: e100.
  9. Karimi-Zarchi M, Neamatzadeh H, Dastgheib SA, et al. (2020) Vertical transmission of coronavirus disease 19 (COVID-19) from infected pregnant mothers to neonates: A review. Fetal and Pediatric Pathology 39: 246-250.
  10. (2020) World Economic Situation and Prospects as of mid-2020. Department of Economic and Social Affairs.
  11. Li L quan, Huang T, Wang Y qing, et al. (2020) COVID-19 patients’ clinical characteristics, discharge rate, and fatality rate of meta-analysis. J Med Virol 92: 577-583.
  12. Jin J-M, Bai P, He W, et al. (2020) Gender differences in patients with COVID-19: Focus on severity and mortality. Front Public Heal 8: 152.
  13. Zheng YY, Ma YT, Zhang JY, et al. (2020) COVID-19 and the cardiovascular system. nature reviews cardiology 17: 259-260.
  14. White A, Kirby M (2020) COVID-19: Biological factors in men’s vulnerability. Trends Urol Men’s Heal 11: 7-9a.
  15. Zhao Y, Zhao Z, Wang Y, et al. (2020) Single-cell RNA expression profiling of ACE2, the putative receptor of Wuhan 2019-nCov. bioRxiv.
  16. Zhang J jin, Dong X, Cao Y yuan, et al. (2020) Clinical characteristics of 140 patients infected with SARS-CoV-2 in Wuhan, China. Allergy Eur J Allergy Clin Immunol 75: 1730-1741.
  17. Yang X, Yu Y, Xu J, et al. (2020) Clinical course and outcomes of critically ill patients with SARS-CoV-2 pneumonia in Wuhan, China: A single-centered, retrospective, observational study. Lancet Respir Med 8: 475-481.
  18. Chen H, Guo J, Wang C, et al. (2020) Clinical characteristics and intrauterine vertical transmission potential of COVID-19 infection in nine pregnant women: A retrospective review of medical records. Lancet 395: 809-815.
  19. Cai H (2020) Sex difference and smoking predisposition in patients with COVID-19. The Lancet Respiratory Medicine 8: e20.
  20. (2020) Labor force, female (% of total labor force). The World Bank.
  21. Bäcker A (2020) The less women get sick from COVID-19, The more they die from it if they do: Islamic countries have lower relative female COVID-19 morbidities and higher relative female COVID-19 fatality rates. SSRN.
  22. Jang S, Han SH, Rhee JY (2020) Cluster of Coronavirus disease associated with fitness dance classes, South Korea. Emerg Infect Dis 26: 1917-1920.
  23. Shim E, Tariq A, Choi W, et al. (2020) Transmission potential and severity of COVID-19 in South Korea. Int J Infect Dis 93: 339-344.
  24. Aponte MS, Aiello C, Gordillo J, et al. (2020) A once-in-a-century pandemic.
  25. Bradbury-Jones C, Isham L (2020) The pandemic paradox: The consequences of COVID-19 on domestic violence. J Clin Nurs 29: 2047-2049.
  26. Daniela Del Boca, Noemi Oggero, Paola Profeta, et al. (2020) Women’s work, housework and childcare, before and during Covid-19. SSRN.
  27. Purkayastha S, Salvatore M, Mukherjee B (2020) Are women leaders significantly better at controlling the contagion during the COVID-19 pandemic? J Heal Soc Sci 5: 231-240.