Mortality transition over a quarter century in rural South Africa: findings from population surveillance in Agincourt 1993-2018

Global Health Action, Volume 14, No. sup1, Year 2021

Interpretation

Background: Mortality burden in South Africa since the mid-1990s has been characterized by a quadruple disease burden: HIV/AIDS and tuberculosis (TB); other communicable diseases (excluding HIV/AIDS and TB), maternal causes, perinatal conditions and nutritional deficiencies; non-communicable diseases (NCDs); and injuries. Causes from these broad groupings have persistently constituted the top 10 causes of death. However, proportions and rankings have varied over time, alongside overall mortality levels. Objective: To provide evidence on the contributions of age and cause-of-death to changes in mortality levels in a rural South African population over a quarter century (1993–2018). Methods: Using mortality and cause-of-death data from the Agincourt Health and Socio-Demographic Surveillance System (HDSS), we derive estimates of the distribution of deaths by cause, and hazards of death by age, sex, and time period, 1993–2018. We derive estimates of life expectancies at birth and years of life expectancy gained at age 15 if most common causes of death were deleted. We compare mortality indicators and cause-of-death trends from the Agincourt HDSS with South African national indicators generated from publicly available datasets. Results: Mortality and cause-of-death transition reveals that overall mortality levels have returned to pre-HIV epidemic levels. In recent years, the concentration of mortality has shifted towards older ages, and the mortality burden from cardiovascular diseases and other chronic NCDs are more prominent as people living with HIV/AIDS access ART and live longer. Changes in life expectancy at birth, distribution of deaths by age, and major cause-of-death categories in the Agincourt population follow a similar pattern to the South African population. Conclusion: The Agincourt HDSS provides critical information about general mortality, cause-of-death, and age patterns in rural South Africa. Realigning and strengthening the South African public health and healthcare systems is needed to concurrently cater for the prevention, control, and treatment of multiple disease conditions. We used mortality and cause of death data collected from 1993 to 2018 as part of annual updates of vital events of the population of the Agincourt Health and Socio-Demographic Surveillance System (HDSS) in rural northeast South Africa [27,28]. Similar to earlier studies conducted in Agincourt [17,29–31], a person-year file was constructed containing one record for each year lived by each individual in the study population during the period 1993–2018. Attributes contained in each record consisted of Individual ID, sex, date of birth, date of death, age, calendar year, if the person died within the year, and the most probable cause-of-death. The most probable cause-of-death was generated using the InterVA-5 probabilistic model (version 5.1) [32]. For each death, the InterVA-5 model assigns up to three likely causes of death with associated likelihoods based on information on signs and symptoms of the illness or injury prior to death collected through verbal autopsy (VA) interviews. The VA interviews were conducted with caregivers of individuals identified as having died between annual surveillance update rounds using a locally validated VA instrument until 2011 and WHO VA instruments from 2012 onwards [28,33]. The timing of the interviews ranged from 1 to 11 months after death. An indeterminate cause was assigned when the VA information was inadequate for the model to arrive at any cause of death. While causes of death derived by the InterVA model have been found to not substantially differ from those generated by physician coding [34,35], the InterVA model also offers the benefit of assigning causes of death in a standardized, automated manner that is much quicker and more consistent compared to physicians. This feature is particularly desirable for assessing changes over time and across settings. Using the person-year file, we estimated the hazards of death by age, sex and time-period using logistic regression models [36–40]. Thereafter, we used the estimated hazards of death to construct standard life tables and cause-deleted life tables to, respectively, derive estimates of life expectancies at birth and to assess potential gains in life expectancy (PGLE) at age 15 if selected insignificant. Third, the InterVAcauses of death were eliminated. The PGLE provides a hypothetical estimate of the impact of a particular disease on life expectancy by highlighting the loss of life expectancy caused by a certain disease and provides a numerical indicator of survival if the disease is eliminated [41]. We follow methods that have been used in several other settings to assess the impact on life expectancy of various diseases, including cardiovascular diseases, neoplasms, HIV/AIDS and accidents using PGLE [41–44]. We split the calendar years into the following time periods: 1993–1997, 1998–2000, 2001–2003, 2004–2007, 2008–2010, 2011–2013, 2014–2016 and 2017–2018 to contextualize the dynamics of the HIV epidemic and the rollout of prevention of mother-to-child transmission (PMTCT) and antiretroviral treatment (ART) services. Where possible, we compared the indicators of mortality and cause-of-death trends from Agincourt with South African national indicators generated from publicly available datasets as a way of assessing the generalizability of our findings. We compared estimates of life expectancy at birth from the Agincourt HDSS with estimates of life expectancy at birth for South Africa obtained from the World Bank data archive [45]. We also compared the percentage distribution of deaths due to communicable diseases (Group I), non-communicable diseases (Group II) and external causes (Group III) by year of death from the Agincourt HDSS population with those in South Africa compiled by Statistics South Africa and archived in the DataFirst online microdata library [46]. Even though deaths due to HIV/AIDS and TB dominated by far deaths due to communicable diseases during periods of increased mortality [17], we did not separate HIV/AIDS and TB from communicable diseases in making the comparison due to known misattribution of HIV/AIDS deaths to infectious conditions, such as diarrhoea, tuberculosis and pneumonia in the South African national cause of death data [47–49]. Different time periods were used to compare the indicators of mortality and cause-of-death trends from Agincourt with South African national indicators due to the availability of publicly accessible national data.

AI Digest

Study Justification:

– The study aims to provide evidence on the changes in mortality levels in a rural South African population over a quarter century (1993-2018).
– It focuses on understanding the contributions of age and cause-of-death to these changes.
– The study is important because it helps identify the major causes of death in the population and how they have evolved over time.
– It provides critical information about general mortality, cause-of-death, and age patterns in rural South Africa.

Study Highlights:

– Overall mortality levels have returned to pre-HIV epidemic levels.
– The concentration of mortality has shifted towards older ages.
– The mortality burden from cardiovascular diseases and other chronic non-communicable diseases (NCDs) has become more prominent.
– Changes in life expectancy at birth, distribution of deaths by age, and major cause-of-death categories follow a similar pattern to the South African population.

Study Recommendations:

– Realign and strengthen the South African public health and healthcare systems to cater for the prevention, control, and treatment of multiple disease conditions.
– Focus on addressing the increasing burden of cardiovascular diseases and other chronic NCDs.
– Develop strategies to support the aging population and address their specific healthcare needs.

Key Role Players:

– Public health officials and policymakers
– Healthcare providers and professionals
– Community leaders and organizations
– Researchers and academics
– Non-governmental organizations (NGOs) working in healthcare

Cost Items for Planning Recommendations:

– Healthcare infrastructure development and maintenance
– Training and capacity building for healthcare professionals
– Implementation of prevention and control programs for cardiovascular diseases and chronic NCDs
– Research and data collection on mortality and cause-of-death trends
– Community outreach and education programs
– Provision of healthcare services for the aging population

Strength of Evidence

The strength of evidence for this abstract is 8 out of 10.
The evidence in the abstract is strong and supported by data collected over a quarter century. However, there are some steps that can be taken to improve it. Firstly, providing specific statistics or numbers related to mortality levels and cause-of-death trends would enhance the evidence. Additionally, including information about the sample size and representativeness of the Agincourt HDSS population would strengthen the findings. Lastly, referencing the sources of the publicly available datasets used for comparison would add credibility to the study.

Abstract

We used mortality and cause of death data collected from 1993 to 2018 as part of annual updates of vital events of the population of the Agincourt Health and Socio-Demographic Surveillance System (HDSS) in rural northeast South Africa [27,28]. Similar to earlier studies conducted in Agincourt [17,29–31], a person-year file was constructed containing one record for each year lived by each individual in the study population during the period 1993–2018. Attributes contained in each record consisted of Individual ID, sex, date of birth, date of death, age, calendar year, if the person died within the year, and the most probable cause-of-death. The most probable cause-of-death was generated using the InterVA-5 probabilistic model (version 5.1) [32]. For each death, the InterVA-5 model assigns up to three likely causes of death with associated likelihoods based on information on signs and symptoms of the illness or injury prior to death collected through verbal autopsy (VA) interviews. The VA interviews were conducted with caregivers of individuals identified as having died between annual surveillance update rounds using a locally validated VA instrument until 2011 and WHO VA instruments from 2012 onwards [28,33]. The timing of the interviews ranged from 1 to 11 months after death. An indeterminate cause was assigned when the VA information was inadequate for the model to arrive at any cause of death. While causes of death derived by the InterVA model have been found to not substantially differ from those generated by physician coding [34,35], the InterVA model also offers the benefit of assigning causes of death in a standardized, automated manner that is much quicker and more consistent compared to physicians. This feature is particularly desirable for assessing changes over time and across settings. Using the person-year file, we estimated the hazards of death by age, sex and time-period using logistic regression models [36–40]. Thereafter, we used the estimated hazards of death to construct standard life tables and cause-deleted life tables to, respectively, derive estimates of life expectancies at birth and to assess potential gains in life expectancy (PGLE) at age 15 if selected insignificant. Third, the InterVAcauses of death were eliminated. The PGLE provides a hypothetical estimate of the impact of a particular disease on life expectancy by highlighting the loss of life expectancy caused by a certain disease and provides a numerical indicator of survival if the disease is eliminated [41]. We follow methods that have been used in several other settings to assess the impact on life expectancy of various diseases, including cardiovascular diseases, neoplasms, HIV/AIDS and accidents using PGLE [41–44]. We split the calendar years into the following time periods: 1993–1997, 1998–2000, 2001–2003, 2004–2007, 2008–2010, 2011–2013, 2014–2016 and 2017–2018 to contextualize the dynamics of the HIV epidemic and the rollout of prevention of mother-to-child transmission (PMTCT) and antiretroviral treatment (ART) services. Where possible, we compared the indicators of mortality and cause-of-death trends from Agincourt with South African national indicators generated from publicly available datasets as a way of assessing the generalizability of our findings. We compared estimates of life expectancy at birth from the Agincourt HDSS with estimates of life expectancy at birth for South Africa obtained from the World Bank data archive [45]. We also compared the percentage distribution of deaths due to communicable diseases (Group I), non-communicable diseases (Group II) and external causes (Group III) by year of death from the Agincourt HDSS population with those in South Africa compiled by Statistics South Africa and archived in the DataFirst online microdata library [46]. Even though deaths due to HIV/AIDS and TB dominated by far deaths due to communicable diseases during periods of increased mortality [17], we did not separate HIV/AIDS and TB from communicable diseases in making the comparison due to known misattribution of HIV/AIDS deaths to infectious conditions, such as diarrhoea, tuberculosis and pneumonia in the South African national cause of death data [47–49]. Different time periods were used to compare the indicators of mortality and cause-of-death trends from Agincourt with South African national indicators due to the availability of publicly accessible national data.

Materials

N/A

Innovations

Based on the provided information, here are some potential innovations that could improve access to maternal health:

1. Telemedicine: Implementing telemedicine services can provide remote access to healthcare professionals for prenatal and postnatal care, allowing pregnant women in rural areas to receive medical advice and consultations without the need for travel.

2. Mobile health (mHealth) applications: Developing mobile applications that provide educational resources, appointment reminders, and personalized health information can empower pregnant women to take control of their own health and access important maternal health services.

3. Community health workers: Training and deploying community health workers who can provide basic maternal health services, such as prenatal check-ups and health education, in remote areas can improve access to care for pregnant women who may have limited access to healthcare facilities.

4. Transportation solutions: Implementing transportation solutions, such as mobile clinics or ambulance services, can help overcome geographical barriers and ensure that pregnant women can reach healthcare facilities in a timely manner for prenatal care, delivery, and postnatal care.

5. Maternal health clinics: Establishing dedicated maternal health clinics in rural areas can provide comprehensive care for pregnant women, including prenatal check-ups, delivery services, and postnatal care, reducing the need for long-distance travel to access these services.

6. Maternal health education programs: Developing and implementing educational programs that focus on maternal health and childbirth can empower women with knowledge and skills to make informed decisions about their own health and seek appropriate care during pregnancy and childbirth.

It is important to note that the specific implementation of these innovations would require further research, planning, and collaboration with local healthcare providers and communities to ensure their effectiveness and sustainability in improving access to maternal health in rural areas.

AI Innovations Description

Based on the information provided, here is a recommendation that can be developed into an innovation to improve access to maternal health:

1. Strengthening and expanding healthcare systems: Realigning and strengthening the South African public health and healthcare systems is crucial to cater for the prevention, control, and treatment of multiple disease conditions, including maternal causes. This can involve increasing the number of healthcare facilities, improving infrastructure and equipment, and ensuring an adequate supply of skilled healthcare professionals.

2. Enhancing prevention and early detection: Implementing comprehensive maternal health programs that focus on prevention and early detection of complications can significantly improve access to maternal healthcare. This can include regular antenatal care visits, providing education and support for pregnant women, promoting healthy behaviors, and ensuring access to essential maternal health services such as prenatal screenings and vaccinations.

3. Improving transportation and logistics: Addressing transportation barriers is essential to ensure that pregnant women can access healthcare facilities in a timely manner. This can involve providing transportation services or subsidies for pregnant women, establishing referral systems between healthcare facilities, and improving road infrastructure in rural areas.

4. Increasing community engagement and awareness: Engaging communities and raising awareness about the importance of maternal health can help overcome cultural and social barriers that may prevent women from seeking care. This can involve community outreach programs, health education campaigns, and involving community leaders and influencers in promoting maternal health.

5. Leveraging technology and innovation: Embracing technological advancements can greatly improve access to maternal health services. This can include telemedicine solutions for remote consultations, mobile health applications for tracking pregnancy progress and receiving health information, and utilizing data analytics to identify high-risk areas and target interventions effectively.

By implementing these recommendations, it is possible to develop innovative solutions that address the challenges in accessing maternal health services, ultimately improving maternal health outcomes in South Africa.

AI Innovations Methodology

Based on the provided information, here are some potential recommendations to improve access to maternal health:

1. Strengthening healthcare infrastructure: Investing in the development and improvement of healthcare facilities, particularly in rural areas, can help ensure that pregnant women have access to quality maternal healthcare services.

2. Enhancing transportation services: Improving transportation networks and providing reliable transportation options can help overcome geographical barriers and enable pregnant women to reach healthcare facilities in a timely manner.

3. Increasing community awareness and education: Conducting awareness campaigns and educational programs can help empower communities with knowledge about the importance of maternal health and the available healthcare services. This can encourage early and regular prenatal care visits.

4. Implementing telemedicine solutions: Utilizing telemedicine technologies can enable remote consultations, monitoring, and support for pregnant women in areas with limited access to healthcare facilities. This can help bridge the gap between healthcare providers and pregnant women.

To simulate the impact of these recommendations on improving access to maternal health, a methodology could include the following steps:

1. Define the baseline: Gather data on the current state of maternal health access, including factors such as healthcare facility availability, transportation infrastructure, community awareness, and education levels.

2. Establish indicators: Identify key indicators that reflect access to maternal health, such as the number of healthcare facilities per population, average travel time to the nearest facility, percentage of pregnant women receiving prenatal care, and maternal mortality rates.

3. Model the recommendations: Develop a simulation model that incorporates the potential impact of each recommendation on the identified indicators. This could involve assigning values or weights to each recommendation based on expert opinions or existing research.

4. Run simulations: Use the simulation model to project the potential changes in the identified indicators based on the implementation of the recommendations. This could involve running multiple scenarios to assess the individual and combined effects of the recommendations.

5. Analyze results: Evaluate the simulation results to determine the potential impact of the recommendations on improving access to maternal health. This could include comparing the projected indicators with the baseline data and identifying any significant improvements or areas that require further attention.

6. Refine and iterate: Based on the analysis, refine the simulation model and repeat the process to explore different scenarios or adjust the recommendations as needed. This iterative approach can help optimize the strategies for improving access to maternal health.

It is important to note that the methodology described above is a general framework and may require customization based on the specific context and available data. Additionally, involving relevant stakeholders, such as healthcare professionals, policymakers, and community representatives, in the simulation process can help ensure the accuracy and relevance of the results.

Author

Dima Health

Statistics:

Citations: 1

Identifiers:

DOI: 10.1080/16549716.2021.1990507

Research Areas:

Community Interventions, Health System and Policy, Infectious Diseases, Maternal Access, Maternal and Child Health, Noncommunicable Diseases, Quality of Care, Social Determinants, Violence and Injury

Study Countries:

South Africa

Study Design:

Cross Sectional Study