COVID-19 mortality in two waves of the pandemic in Cali, Colombia, before and during vaccination roll-out

Reina, Carlos; Roa, Pablo; Garcés, Anthony; Valencia, Andrés; Torres, Miyerlandi; Concha-Eastman, Alberto

doi:10.26633/rpsp.2023.76

ABSTRACT

Objective.

To describe the variation in COVID-19 mortality among residents of Cali, Colombia, in the second wave of the pandemic, before vaccines, and in the fourth wave, with vaccination roll-out in process, taking into account variables of sex, age group, comorbidities, and interval between onset of symptoms and death, and to estimate the number of deaths averted by vaccination.

Methods.

A cross-sectional study of second wave and fourth wave deaths and vaccination coverage. The frequencies of attributes of deceased population in the two waves were compared, including comorbidities. Machado’s method was used to calculate an estimate of the number of deaths averted in the fourth wave.

Results.

There were 1 133 deaths in the second wave and 754 deaths in the fourth wave. It was calculated that approximately 3 763 deaths were averted in the fourth wave in Cali in the context of vaccination roll-out.

Conclusions.

The decline in COVID-19-associated mortality observed supports the continuation of the vaccination program. Given the lack of data to explain other possible reasons for this decline, such as on the severity of novel viral variants, the limitations of the study are discussed.

Keywords
COVID-19; COVID-19 vaccines; mortality; Colombia

RESUMEN

Objetivo.

Describir la variación en la mortalidad por COVID-19 en los residentes de Cali, Colombia, en la segunda ola de la pandemia (antes de las vacunas) y en la cuarta ola (durante el despliegue de las vacunas). Se tomaron en cuenta las variables referidas al sexo, grupo de edad, comorbilidades e intervalo entre el inicio de los síntomas y la muerte y se estimó el número de muertes evitadas por la vacunación.

Métodos.

Estudio transversal sobre las muertes en la segunda y cuarta olas de la pandemia de COVID-19 y la cobertura de vacunación. Se compararon las frecuencias de los atributos correspondientes a la población fallecida durante las dos olas, incluidas las comorbilidades. Se utilizó el método de Machado para estimar el número de muertes evitadas en la cuarta ola.

Resultados.

Se registraron 1 133 muertes en la segunda ola y 754 en la cuarta. Se calculó que, en el contexto del despliegue de las vacunas, en la cuarta ola se evitaron aproximadamente 3 763 muertes en Cali.

Conclusiones.

La disminución observada en la mortalidad asociada a la COVID-19 respalda la continuación del programa de vacunación. Dada la falta de datos para explicar otras posibles causas de esta disminución, como puede ser la gravedad causada por las nuevas variantes virales, se analizan las limitaciones del estudio.

Palabras clave
COVID-19; vacunas contra la COVID-19; mortalidad; Colombia

RESUMO

Objetivo.

Descrever a variação da mortalidade por COVID-19 entre residentes de Cali, Colômbia, na segunda onda da pandemia (antes das vacinas) e na quarta onda (com a implantação da vacinação já em andamento), considerando as variáveis sexo, faixa etária, comorbidades e intervalo entre início dos sintomas e óbito, bem como estimar o número de óbitos evitados pela vacinação.

Métodos.

Estudo transversal de mortes e cobertura vacinal na segunda e quarta ondas da pandemia. Foram comparadas as frequências dos atributos da população que foi a óbito durante as duas ondas, incluindo comorbidades. Foi utilizado o método de Machado para estimar o número de mortes evitadas na quarta onda.

Resultados.

Houve 1.133 mortes na segunda onda e 754 mortes na quarta onda. Calcula-se que cerca de 3.763 mortes foram evitadas na quarta onda em Cali, no contexto da disponibilização das vacinas.

Conclusões.

A queda observada na mortalidade associada à COVID-19 apoia a continuidade do programa de vacinação. Considerando a falta de dados para explicar outros possíveis motivos para esta queda, como a gravidade das novas variantes do vírus, discutem-se as limitações do estudo.

Palavras-chave
COVID-19; vacinas contra COVID-19; mortalidade; Colômbia

The COVID-19 epidemic emerged in China in December 2019 and spread globally, faster than countries could contain it. The first reports from China and Europe showed a significant number of deaths from previously unseen sequelae. Although the initial case fatality rate was between 3% and 5%, the sheer number of infected people considerably increased the possibility of dying, especially in high-risk populations such as people over 60 and those with preexisting comorbidities (¹1. Wu Z, McGoogan JM. Characteristics of and Important Lessons From the Coronavirus Disease 2019 (COVID-19) Outbreak in China: Summary of a Report of 72 314 Cases From the Chinese Center for Disease Control and Prevention. JAMA. 2020 Apr 7;323(13):1239–42. https://doi.org/10.1001/jama.2020.2648.
https://doi.org/10.1001/jama.2020.2648... ).

In China, the case fatality rate was 14.8% among adults over 80 and 8% among those aged 70–79. In European countries, nearly 95% of COVID-19 fatalities were over 60 (²2. Kluge HHP. Older people are at the highest risk from COVID-19, but all must act to prevent community spread. Copenhagen: World Health Organization; 2020 April 3. Available from: https://www.who.int/europe/news/item/03-04-2020-statement-older-people-are-at-highest-risk-from-covid-19-but-all-must-act-to-prevent-community-spread.
https://www.who.int/europe/news/item/03-... ). In Latin America, studies show that the highest mortality rate during the first year of the outbreak was in Ecuador (19.5 per 100 000 population), followed by Brazil (13.3) and Peru (12.2) (³3. Muñoz N. COVID-19 in Latin America: A first glance to the mortality. Colomb Med (Cali) [Internet]. 2020;51(2):e-4366. https://doi.org/10.25100/cm.v51i2.4366.
https://doi.org/10.25100/cm.v51i2.4366... ). In Colombia, 6 092 403 cases and 139 796 fatalities were reported for the year 2021 (⁴4. CDC COVID-19 Response Team. Severe Outcomes Among Patients with Coronavirus Disease 2019 (COVID-19) — United States, February 12–March 16, 2020. MMWR Morb Mortal Wkly Rep. 2020 Mar 27;69(12):343–6. https://doi.org/10.15585%2Fmmwr.mm6912e2.
https://doi.org/10.15585%2Fmmwr.mm6912e2... ).

In the absence of an effective and early treatment, health authorities, academics, and the pharmaceutical industry began testing vaccines that could induce immunity in the general population. The World Health Organization (WHO) established the Strategic Advisory Group of Experts on Immunization (SAGE) to review vaccines under investigation, support their usage, and set COVID-19 vaccination priorities (⁵5. World Health Organization. Hoja de ruta del SAGE de la OMS para el establecimiento de prioridades en el uso de vacunas contra la COVID-19 en un contexto de suministros limitados. Geneva: WHO; 2020. Available from: https://www.who.int/es/publications/m/item/who-sage-roadmap-for-prioritizing-uses-of-covid-19-vaccines-in-the-context-of-limited-supply.
https://www.who.int/es/publications/m/it... ). Subsequently, SAGE authorized mass vaccine deployment as an emergency measure, and WHO outlined and approved a risk-based immunization procedure. The Government of Colombia purchased vaccines for free administration to the entire population, in accordance with the phases and stages outlined in the National COVID-19 Vaccination Plan (NVP) (⁶6. Ministry of Health and Social Protection of Colombia. Plan de Vacunación Contra el COVID-19 [Internet]. Bogotá: Ministry of Health and Social Protection; 2021. Available from: https://www.mineducacion.gov.co/portal/micrositios-institucionales/Plan-de-Vacunacion-Contra-el-COVID-19/.
https://www.mineducacion.gov.co/portal/m... ).

In Cali, Colombia’s third-largest city, the “We Vaccinate for Life” initiative led by the Public Health Secretariat (Secretaría de Salud Pública de Cali—SSP), with the participation of academia, the municipal administration, and the community, reduced morbidity and death in this city (⁴4. CDC COVID-19 Response Team. Severe Outcomes Among Patients with Coronavirus Disease 2019 (COVID-19) — United States, February 12–March 16, 2020. MMWR Morb Mortal Wkly Rep. 2020 Mar 27;69(12):343–6. https://doi.org/10.15585%2Fmmwr.mm6912e2.
https://doi.org/10.15585%2Fmmwr.mm6912e2... ). SSP has monitored vaccination coverage under the PAICOVID platform since the NVP began, focusing on cases and mortality. At the end of the fourth wave, at least 80% of people had received one vaccine dose and the case fatality rate was 0.85%, compared to 3.03% in the first wave, 2.53% in the second, and 1.35% in the third (⁷7. Alcaldía de Santiago de Cali, Secretaría de Salud Pública. Boletín Vacunación Covid-19, No. 334, 31-01-2022 [Internet]. Cali: Secretaría de Salud Pública; 2022. Available from: https://www.cali.gov.co/salud/publicaciones/159073/boletines-vacunacion-covid/genPagdoc4156=21.
https://www.cali.gov.co/salud/publicacio... , ⁸8. Alcaldía de Santiago de Cali, Secretaría de Salud Pública. Boletines epidemiológicos COVID-19, No. 693, 31-01-2022 [Internet]. Cali: Secretaría de Salud Pública; 2022. Available from: https://www.cali.gov.co/salud/publicaciones/152840/boletines-epidemiologicos/genPagdoc5106=23.
https://www.cali.gov.co/salud/publicacio... ). This suggests that the NVP may have reduced risk-factor-related deaths.

An ecological longitudinal study by the Colombian Ministry of Health and Social Protection (MSPS) estimated 22 000 deaths averted by mass vaccination of adults over 60 in the first year of the NVP (⁹9. Rojas-Botero ML, Fernández-Niño JA, Arregocés-Castillo L, Ruiz-Gómez F. Estimated number of deaths directly avoided because of COVID-19 vaccination among older adults in Colombia in 2021: an ecological, longitudinal observational study. F1000Research [Internet]. 2022;11:198. https://doi.org/10.12688/f1000research.109331.3.
https://doi.org/10.12688/f1000research.1... ). COVID-19 deaths could be prevented by any effective therapeutic approach, but even more so by vaccine-generated personal immunity preventing infection progression to death—the most significant expected effect of vaccination.

The objective of this study was to describe COVID-19 mortality among residents of Cali in the second wave of infections (13 December 2020 to 3 February 2021) before vaccines and in the fourth wave (28 December 2021 to 31 January 2022) with vaccination roll-out in progress, and to estimate the number of deaths averted.

MATERIALS AND METHODS

SSP records on vaccination coverage and deaths in the second and fourth waves of the COVID-19 pandemic in Cali were examined using a cross-sectional study design. The frequency of attributes of the deceased population were described for the second and fourth waves of infections. The Instituto Nacional de Salud (INS) defines positive and deceased cases (¹⁰10. Instituto Nacional de Salud de Colombia. Anexo. Instructivo para la vigilancia en salud pública intensificada de infección respiratoria aguda y la enfermedad asociada al nuevo coronavirus 2019 (COVID-19). Versión 13. Fecha de actualización: 16 de diciembre 2020 [Internet]. Bogotá: INS; 2020. Available from: https://www.ins.gov.co/Direcciones/Vigilancia/Paginas/Lineamientos-y-documentos.aspx.
https://www.ins.gov.co/Direcciones/Vigil... ).

The second wave in Cali lasted 52 days, with 54 862 positive cases and 1 133 deaths. The fourth wave lasted 35 days, with 90 085 positive cases and 754 deaths. These durations were estimated using the method described by Bortman (¹¹11. Bortman M. [Establishing endemic levels or ranges with computer spreadsheets]. Rev Panam Salud Publica. 1999;5(1):1–8. https://doi.org/10.1590/s1020-49891999000100001.
https://doi.org/10.1590/s1020-4989199900... ), reducing the follow-up period from years to weeks of positive cases when COVID-19 increased in the city. The two-wave sample had 1 887 deaths and 144 947 positive COVID-19 cases; thus, all positive cases and deaths in these two periods were considered.

Inclusion criteria were any resident of Cali vaccinated with one or two doses and booster doses, any resident unvaccinated when the fourth wave was recorded, and any resident reported positive for SARS-CoV-2 infection, vaccinated or unvaccinated. Non-residents of Cali, under-18s, and records with inconsistent vaccination data were excluded. The covariates were sex, age, comorbidities (cancer, diabetes, chronic kidney disease, heart disease, HIV infection, chronic obstructive pulmonary disease [COPD]), nationality, and days between onset of symptoms and death.

The deaths in the second and fourth waves were identified using SSP COVID-19 vaccination databases and RT-PCR or antigen test positive cases. The date of application of any NVP vaccine was used to determine if the individual tested positive 14 days after vaccination with the complete scheme. This study does not contain any individual personal data, and no intervention was performed on any person.

The analysis compares the frequencies of attributes of deceased population in the two waves studied. The chi-squared test for categorical variables and Student’s t-test for numerical variables were used to estimate differences between groups.

The Z-test proportion comparison test (Equation 1) (¹²12. Oleckno WA. Epidemiology: Concepts and Methods. Long Grove, IL: Waveland Press; 2008.) was used to estimate differences between the case fatality rate in the fourth wave and in the second wave.

z=pA+pBpq/nA+pq/nB

In Equation 1, p_A is the observed proportion of deaths with positive cases of wave 2 (n_A), p_B is the observed proportion of deaths with positive cases of wave 4 (n_B), and pq is the global proportion.

Deaths averted were calculated with the method described by Machado used in the MSPS Colombia study (⁹9. Rojas-Botero ML, Fernández-Niño JA, Arregocés-Castillo L, Ruiz-Gómez F. Estimated number of deaths directly avoided because of COVID-19 vaccination among older adults in Colombia in 2021: an ecological, longitudinal observational study. F1000Research [Internet]. 2022;11:198. https://doi.org/10.12688/f1000research.109331.3.
https://doi.org/10.12688/f1000research.1... ), which is based on the effectiveness of vaccines in preventing negative health outcomes, population coverage, and the change in frequency of these outcomes after applying the vaccination intervention (¹³13. Machado A, Mazagatos C, Dijkstra F, Kislaya I, Gherasim A, McDonald SA, et al. Impact of influenza vaccination programmes among the elderly population on primary care, Portugal, Spain and the Netherlands: 2015/16 to 2017/18 influenza seasons. Eurosurveillance [Internet]. 2019 Nov 7;24(45):1900268. https://doi.org/10.2807/1560-7917.ES.2019.24.45.1900268.
https://doi.org/10.2807/1560-7917.ES.201... ). For this calculation, an estimated 81% overall effectiveness (VE_j) of vaccines to prevent death (¹⁴14. Reina C, Torres M, Muñoz E, Grillo Ardila EK, Guerrero R, Bravo LE. Mortality due to COVID-19 during the vaccination plan against the SARS-CoV-2 virus in Cali, Colombia. Colomb Med (Cali) [Internet]. 2021;52(4):e7005047. https://doi.org/10.25100/cm.v52i4.5047.
https://doi.org/10.25100/cm.v52i4.5047... ) was used in the following equation:

Da=∑ijDoij×FVi-2j×VEj1-(FVi-2j×VEj

In Equation 2, D_oij is the deaths observed in week i of the fourth wave in age group j, FV_i-2j is full vaccine coverage two weeks before week i of the fourth wave for age group j, and VE_j is the effectiveness of vaccination in age group j.

Based on the number of deaths observed, vaccination coverage with a complete scheme after a two-week interval, and vaccine effectiveness measured in Cali, an estimate is made of the deaths that could have occurred if COVID-19 vaccination were not available in Cali during the fourth wave.

R software (version 4.2.1, R Foundation for Statistical Computing, Vienna, Austria) was used for all the above methods (¹⁵15. RStudio Team. RStudio, Open source & professional software for data science teams [Internet]. Vienna: RStudio Inc.; 2022. Available from: https://www.rstudio.com/.
https://www.rstudio.com/... ).

RESULTS

Table 1 shows the attributes of the variables used in the analysis. In the second wave, 1 133 people died, of whom 426 (37.6%) were women and 707 (62.4%) men. In the fourth wave, 754 people died, of whom 317 (42.0%) were women and 437 (58.0%) men. There were no statistically significant differences between women and men between the two waves (p > 0.05). Mortality decreased by 270 cases (38.2%) in men and 109 cases (25.5%) in women in the fourth wave. The average age of the deceased was 72.6 years in the second wave and 77.9 years in the fourth wave (p = 0.2). In the fourth wave, there was a statistically significant increase in the proportion of deceased over 80 years of age (p = 1.4e–12) and a decrease in those aged 60 to 79 years (p = 3.03e–3), 50 to 59 years (p = 8.03e–3), 40 to 49 years (p = 0.01), and 30 to 39 years (p = 0.01), with no statistical difference for those aged 18 to 29 years (p = 0.8).

The average interval between onset of symptoms and death was 20 days in the second wave and 14 days in the fourth wave. In terms of associated comorbidities, diabetes cases decreased from 228 (20.1%) in the second wave to 76 (10.1%) in the fourth wave (p < 6.1e–6), kidney disease decreased from 75 (6.6%) to 21 (2.8%) (p = 0.0002), and heart disease decreased from 96 (8.5%) to 36 (4.8%) (p = 0.002). Age, sex, nationality, and other comorbidities (cancer, COPD, HIV) did not differ between waves. In general, comorbidity rates and percentage weights decreased, but not all decreases were significant.

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TABLE 1.
Frequency of attributes of the deceased by COVID-19 wave, Cali

Figure 1 shows that the frequency of daily deaths in the fourth wave is similar to that of the second wave during the first 38 days registered, a trend which from that point onwards is differentiated by the lower number of deaths registered in the fourth wave, measured until day 53, when the second wave ends, 15 days longer than the fourth wave. Given the higher number of infected people in the fourth wave (Table 1), COVID-19 deaths were lower in the fourth wave compared to the second.

Table 2 presents the attributes of the deceased in the fourth wave of COVID-19 according to vaccination status using the same statistical methods as Table 1. The unvaccinated variable represents people who did not have any vaccine dose against SARS-CoV-2, and the vaccinated variable represents people who completed the vaccination schedule. In the fourth wave, 465 unvaccinated people died, 56.8% of whom were men and 43.2% women, while 289 fully vaccinated people died, 59.9% of whom were men and 40.1% women, showing no statistical differences between the two groups. The fourth wave saw 33.4% fewer COVID-19 deaths than the second wave.

The unvaccinated deceased averaged 76.3 years of age, while the vaccinated averaged 80.6 years (p = 1.41e–12). When categorized by age, only those over 80 years show statistically significant differences, with 52 fewer deaths among the vaccinated (176) than the unvaccinated (228) (p = 0.001). Deaths are concentrated in the 60–79 and 80+ years groups. The unvaccinated died on average 13.8 days after symptom onset, compared to 15.7 days for the vaccinated (p = 0.0005).

In the fourth wave, 9.2% of the unvaccinated deceased had diabetes, accounting for 5.7% of the total number of deaths. Of the deceased vaccinated with a complete scheme, 30.1% had any comorbidity, and 11.4% had diabetes, accounting for 4.4% of all fourth-wave deaths. Some 61.6% of fourth-wave deceased were unvaccinated. The second and fourth waves had different case fatality rates, with the fourth wave having a higher proportion of positive cases and a lower death rate. Thus, the Z-test proportion comparison test (Equation 1) estimates statistically significant differences between the case fatality rate of 0.8% in the fourth wave and 2.5% in the second wave (Table 3).

Table 4 shows the possible deaths during the fourth wave if second wave case fatality rates were maintained based on the number of fourth wave COVID-19 cases: 2 004 deaths would be expected in people over 18, concentrated in the 60–79 age group and then in the over 80 group.

Deaths averted were calculated with the method described by Machado used in the MSPS Colombia study (⁹9. Rojas-Botero ML, Fernández-Niño JA, Arregocés-Castillo L, Ruiz-Gómez F. Estimated number of deaths directly avoided because of COVID-19 vaccination among older adults in Colombia in 2021: an ecological, longitudinal observational study. F1000Research [Internet]. 2022;11:198. https://doi.org/10.12688/f1000research.109331.3.
https://doi.org/10.12688/f1000research.1... ). Associated with the effect of vaccination, approximately 3 763 deaths were averted in the fourth wave in Cali (Table 5).

DISCUSSION

Based on the deaths when vaccination was unavailable (second wave), this study indicated that an expected 3 763 deaths were prevented in Cali’s fourth wave, especially among high-risk age groups (over 80 and 60–79 years). Between December 2020 and November 2021, more than 33 European countries averted 469 186 deaths among over-60s. Israel, Malta, and the United Kingdom had lower anticipated mortality, notably in persons over 80 (¹⁶16. Haas EJ, Angulo FJ, McLaughlin JM, Anis E, Singer SR, Khan F, et al. Impact and effectiveness of mRNA BNT162b2 vaccine against SARS-CoV-2 infections and COVID-19 cases, hospitalisations, and deaths following a nationwide vaccination campaign in Israel: an observational study using national surveillance data. Lancet. 2021 May 15;397(10287):1819–29. https://doi.org/10.1016/s0140-6736(21)00947-8.
https://doi.org/10.1016/s0140-6736(21)00... ). In Colombia, MSPS conducted an ecological analysis that predicted 22 000 deaths averted in people over 60, or 32.4% of expected deaths in 2021 (⁹9. Rojas-Botero ML, Fernández-Niño JA, Arregocés-Castillo L, Ruiz-Gómez F. Estimated number of deaths directly avoided because of COVID-19 vaccination among older adults in Colombia in 2021: an ecological, longitudinal observational study. F1000Research [Internet]. 2022;11:198. https://doi.org/10.12688/f1000research.109331.3.
https://doi.org/10.12688/f1000research.1... ).

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FIGURE 1.
Cumulative COVID-19 deaths, second and fourth waves, Cali

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TABLE 2.
Frequency of attributes of the deceased in the fourth wave of COVID-19 infections by vaccination status, Cali

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TABLE 3.
Comparison of case fatality rate between the second and fourth waves of COVID-19, Cali

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TABLE 4.
Expected deaths in the fourth wave of COVID-19 based on the case fatality rate of the second wave, Cali

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TABLE 5.
Number of deaths averted during the fourth wave of COVID-19, population aged 18 years and older, Cali

Whereas 2 004 people could have been expected to die in the fourth wave, the fourth wave had fewer fatalities than the second, possibly due to vaccination. Public health and epidemiological strategies like vaccination, confinement, and early case detection reduced deaths during outbreaks in Colombia (¹⁷17. Chaves Castro ÁH. Análisis sobre la evolución del COVID-19 en Colombia: ¿se alcanzará el pico de contagio? Tiempo y Economía [Internet]. 2021 Jan 1;8(1):123–60. https://doi.org/10.21789/24222704.1672.
https://doi.org/10.21789/24222704.1672... ). In the fourth wave, the Omicron variant was predominant, which WHO characterized as highly transmissible but with a lower rate of severe disease and deaths (¹⁸18. World Health Organization. Status of COVID-19 Vaccines within WHO EUL/PQ evaluation process [Internet]. Geneva: WHO; 2021. Available from: https://extranet.who.int/pqweb/sites/default/files/documents/Status_COVID_VAX_12January2023.pdf.
https://extranet.who.int/pqweb/sites/def... ).

This study found that 60% of the deceased during the fourth wave were unvaccinated, and a higher proportion were among people at higher risk due to older age and comorbidities. This result is consistent with a review of data from China, Italy, and the United States of America, in which Ejaz et al. (¹⁹19. Ejaz H, Alsrhani A, Zafar A, Javed H, Junaid K, Abdalla AE, et al. COVID-19 and comorbidities: Deleterious impact on infected patients. J Infect Public Health. 2020;13(12):1833–9. https://doi.org/10.1016/j.jiph.2020.07.014.
https://doi.org/10.1016/j.jiph.2020.07.0... ) state that “underlying diseases, such as hypertension, CVD [cardiovascular disease], diabetes, malignancy, COPD, and asthma, have been reported as risk factors for severe disease and also increased the mortality rate.” In China, 23% of hypertensive cases with COVID-19 were reported with a 6% case fatality rate, and in diabetic patients a COVID-19 fatality rate of 8% was reported (¹⁹19. Ejaz H, Alsrhani A, Zafar A, Javed H, Junaid K, Abdalla AE, et al. COVID-19 and comorbidities: Deleterious impact on infected patients. J Infect Public Health. 2020;13(12):1833–9. https://doi.org/10.1016/j.jiph.2020.07.014.
https://doi.org/10.1016/j.jiph.2020.07.0... ).

In addition, mean age of the deceased differed between waves, at 72.6 years in the second wave and 77.9 in the fourth, which may be directly linked to the effect of different viral genomic variants on mortality in older patients, especially in the unvaccinated population. Other studies estimate a higher risk of disease progression associated with advanced age (²2. Kluge HHP. Older people are at the highest risk from COVID-19, but all must act to prevent community spread. Copenhagen: World Health Organization; 2020 April 3. Available from: https://www.who.int/europe/news/item/03-04-2020-statement-older-people-are-at-highest-risk-from-covid-19-but-all-must-act-to-prevent-community-spread.
https://www.who.int/europe/news/item/03-... ).

The mean interval between onset of symptoms and death was 20.2 days in the second wave and 14.5 days in the fourth. However, the available literature does not specify a cause for the change in the interval between onset of symptoms and death as outcome between waves. Hypotheses include differences in the viral variants, age groups, late presentation at health services for timely care, and comorbidities that are linked to age (²⁰20. Manta B, Sarkisian AG, García-Fontana B, Pereira-Prado V, Manta B, Sarkisian AG, et al. Fisiopatología de la enfermedad COVID-19. Odontoestomatología [Internet]. 2022 Apr 1;24(39):e312. https://doi.org/10.22592/ode2022n39e312.
https://doi.org/10.22592/ode2022n39e312... ).

This study has limitations. The study is observational, and proving causation requires different methodology. It did not include immunological and antibody response data to determine if vaccination and transmissibility of circulating viral variants explain the age group differences in mortality between the two waves (²¹21. Kamat D, Kamat A, Mathur A. Immune Responses in Patients with COVID-19: An Overview. Pediatr Ann. 2021 May 1;50(5):e222–e226. https://doi.org/10.3928/19382359-20210421-02.
https://doi.org/10.3928/19382359-2021042... ). In addition, availability of testing data was limited due to the prioritization of sampling in the INS guidelines and the depletion of resources to conduct testing (¹⁰10. Instituto Nacional de Salud de Colombia. Anexo. Instructivo para la vigilancia en salud pública intensificada de infección respiratoria aguda y la enfermedad asociada al nuevo coronavirus 2019 (COVID-19). Versión 13. Fecha de actualización: 16 de diciembre 2020 [Internet]. Bogotá: INS; 2020. Available from: https://www.ins.gov.co/Direcciones/Vigilancia/Paginas/Lineamientos-y-documentos.aspx.
https://www.ins.gov.co/Direcciones/Vigil... ). The number of people with comorbidities who could have died before the fourth wave is a limitation in the analysis of the decrease in mortality.

The strengths of the study include that it has the advantage of a large sample size, and it describes and analyzes information from the two waves and the number of deaths possibly averted by vaccination coverage, as used in exploratory COVID-19 studies (²²22. Alali WQ, Ali LA, Alseaidan M, Al-Rashidi M. Effectiveness of BNT162b2 and ChAdOx1 vaccines against symptomatic COVID-19 among healthcare workers in Kuwait: A retrospective cohort study. Healthcare (Basel) [Internet]. 2021 Dec 7;9(12):1692. https://doi.org/10.3390/healthcare9121692.
https://doi.org/10.3390/healthcare912169... –²³23. Pletz MW, Trommer S, Kolanos S, Rose N, Kinne V, Spott R, et al. Group Vaccination Five Days before a COVID-19 Outbreak in a Long-Term Care Facility. Vaccines (Basel) [Internet]. 2021 Dec 1;9(12):1450. https://doi.org/10.3390/vaccines9121450.
https://doi.org/10.3390/vaccines9121450... ).

The findings of this study support prioritizing vaccination of risk groups to prevent fatalities. To better understand this pandemic and future ones, epidemiological surveillance and communication with MSPS and international agencies must be strengthened. Continued observation and analysis of COVID-19 variables and widespread vaccine use are essential.

In conclusion, this study allowed us to estimate the deaths that were possibly averted, based on the prevalence of COVID-19 positive cases, the case fatality rates for each of the two waves, and estimating a reduction in mortality in the fourth wave compared to the second. These possible deaths averted were in the context of vaccination coverage for older age groups in the city of Cali.

Disclaimer.

Authors hold sole responsibility for the views expressed in the manuscript, which may not necessarily reflect the opinion or policy of the RPSP/PAJPH and/or those of the Pan American Health Organization.

Acknowledgment.

The authors would like to thank the COVID-19 epidemiological surveillance team, the Public Health Secretariat of Cali, and all the public and private hospitals in the city that allowed the data to be collected.

Author contributions.
CR and PR contributed to the topic, study design, data analysis, interpretation, and discussion. AG contributed to the data analysis and interpretation. AV and MT contributed to the interpretation and discussion. ACE contributed to the topic, study design, interpretation, and discussion. All authors reviewed and approved the final version.
Conflict of interest.
None declared.

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Publication Dates

Publication in this collection
29 May 2023
Date of issue
2023

History

Received
03 Oct 2022
Accepted
20 Jan 2023

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[1] Author contributions.
CR and PR contributed to the topic, study design, data analysis, interpretation, and discussion. AG contributed to the data analysis and interpretation. AV and MT contributed to the interpretation and discussion. ACE contributed to the topic, study design, interpretation, and discussion. All authors reviewed and approved the final version.

[2] Conflict of interest.
None declared.

Variable	Category	Wave 2 (n = 1 133)	Wave 4 (n = 754)	P value
Sex	Female	426 (37.6%)	317 (42.0%)	0.05
Sex	Male	707 (62.4%)	437 (58.0%)	0.05
Mean age (SD)		72.6 (13.5)	77.9 (14.3)	0.2
Age group	>80	397 (35.0%)	404 (53.6%)	1.4e–12
	60–79	561 (49.5%)	291 (38.6%)	3.03e–3
	50–59	111 (9.8%)	32 (4.2%)	8.03e–3
	40–49	34 (3.0%)	10 (1.3%)	0.01
	30–39	21 (1.9%)	4 (0.5%)	0.01
	18–29	8 (0.7%)	6 (0.8%)	0.8
Mean days between onset of symptoms and date of death (SD)		20.2 (19.3)	14.5 (7.57)	2.2e–16
Nationality	Colombian	1 128 (99.6%)	749 (99.3%)	0.5
Nationality	Foreign	5 (0.4%)	5 (0.7%)	0.5
Cancer	Yes	43 (3.8%)	24 (3.2%)	0.4
Cancer	No	1 090 (96.2%)	730 (96.8%)	0.4
Diabetes	Yes	228 (20.1%)	76 (10.1%)	6.1e–6
Diabetes	No	905 (79.9%)	678 (89.9%)	6.1e–6
Kidney disease	Yes	75 (6.6%)	21 (2.8%)	0.0002
Kidney disease	No	1 058 (93.4%)	733 (97.2%)	0.0002
Heart disease	Yes	96 (8.5%)	36 (4.8%)	0.002
Heart disease	No	1 037 (91.5%)	718 (95.2%)	0.002
Human immunodeficiency virus (HIV)	Yes	7 (0.6%)	1 (0.1%)	0.1
Human immunodeficiency virus (HIV)	No	1 126 (99.4%)	753 (99.9%)	0.1
Chronic obstructive pulmonary disease (COPD)	Yes	98 (8.6%)	52 (6.9%)	0.2
Chronic obstructive pulmonary disease (COPD)	No	1 035 (91.4%)	702 (93.1%)	0.2

Variable	Category	Unvaccinated (n = 465)	Vaccinated (n = 289)	P value
Sex	Female	264 (56.8%)	173 (59.9%)	0.4
Sex	Male	201 (43.2%)	116 (40.1%)	0.4
Mean age (SD)		76.3 (15.8)	80.6 (11.0)	1.41e–12
Mean days between onset of symptoms and date of death (SD)		13.8 (7.34)	15.7 (7.79)	0.0005
Age group	>80	228 (49.0%)	176 (60.9%)	0.001
	60–79	190 (40.9%)	101 (34.9%)	0.1
	50–59	23 (4.9%)	9 (3.1%)	0.2
	40–49	9 (1.9%)	1 (0.3%)	0.06
	30–39	4 (0.9%)	0 (0%)	0.1
	18–29	4 (0.9%)	2 (0.7%)	0.8
Nationality	Colombian	462 (99.4%)	287 (99.3%)	0.9
Nationality	Foreign	3 (0.6%)	2 (0.7%)	0.9
Cancer	Yes	13 (2.8%)	11 (3.8%)	0.4
Cancer	No	452 (97.2%)	278 (96.2%)	0.4
Diabetes	Yes	43 (9.2%)	33 (11.4%)	0.3
Diabetes	No	422 (90.8%)	256 (88.6%)	0.3
Kidney disease	Yes	13 (2.8%)	8 (2.8%)	0.9
Kidney disease	No	452 (97.2%)	281 (97.2%)	0.9
Heart disease	Yes	19 (4.1%)	17 (5.9%)	0.2
Heart disease	No	446 (95.9%)	272 (94.1%)	0.2
Human immunodeficiency virus (HIV)	Yes	0 (0%)	1 (0.3%)	0.2
Human immunodeficiency virus (HIV)	No	465 (100%)	288 (99.7%)	0.2
Chronic obstructive pulmonary disease (COPD)	Yes	33 (7.1%)	19 (6.6%)	0.7
Chronic obstructive pulmonary disease (COPD)	No	432 (92.9%)	270 (93.4%)	0.7

Waves	Chi squared	DF	P value	Relative frequency	Case fatality rate
Wave 2	94 991	1	2.2e–16	0.02	2.5%
Wave 4	94 991	1	2.2e–16	0.008	0.8%

Age group	Number of cases (Wave 4)	Case fatality rate (Wave 2)	Expected deaths (Wave 4)
>80	2 826	26.3%	743
60–79	11 888	7.9%	950
50–59	11 923	1.6%	194
40–49	16 074	0.5%	78
30–39	20 884	0.1%	27
18–29	21 255	0.05%	11
Total			2 004

Age group	Population size	Vaccinated people	Unvaccinated people	Case fatality rate Wave 2	Vaccination coverage Wave 4	Deaths observed Wave 4	Deaths averted Wave 4
>80	62 078	61 916	162	15.0%	100%	404	2 732
60–79	318 565	285 591	32 974	2.4%	90%	291	865
50–59	268 541	252 854	15 687	0.3%	95%	32	135
40–49	281 172	220 374	60 798	0.08%	80%	10	20
30–39	325 186	204 976	120 210	0.04%	65%	4	5
18–29	363 557	202 986	160 571	0.02%	58%	6	5
Total	1 619 099	1 228 697	390 402	1.1%	81%	747	3 763

Saúde Pública

Saúde Pública

COVID-19 mortality in two waves of the pandemic in Cali, Colombia, before and during vaccination roll-out

Mortalidad por COVID-19 en dos olas de la pandemia en Cali, Colombia, antes y durante el despliegue de las vacunas

Mortalidade por COVID-19 em duas ondas da pandemia em Cali, Colômbia, antes e durante a disponibilização das vacinas

ABSTRACT

Objective.

Methods.

Results.

Conclusions.

RESUMEN

Objetivo.

Métodos.

Resultados.

Conclusiones.

RESUMO

Objetivo.

Métodos.

Resultados.

Conclusões.

MATERIALS AND METHODS

RESULTS

DISCUSSION

Disclaimer.

Acknowledgment.

REFERENCES

Publication Dates

History