Making visible the invisible : Health risks from environmental exposures among socially deprived populations of Nairobi, Kenya

Egondi, Thaddaeus Wandera

January 2015

Background: Most countries of sub-Saharan Africa (SSA) are experiencing a high rate of ur­banization accompanied with unplanned development resulting into sprawl of slums. The weath­er patterns and air pollution sources in most urban areas are changing with significant effects on health. Studies have established a link between environmental exposures, such as weather variation and air pollution, and adverse health outcomes. However, little is known about this relationship in urban populations of SSA where more than half the population reside in slums, or slum like conditions. A major reason for this is the lack of systematic collection of data on exposure and health outcomes. High quality prospective data collection and census registers still remain a great challenge. However, within small and spatially defined areas, dynamic cohorts have been established with continuous monitoring of health outcomes. Collection of environmental exposure data can complement cohort studies to investigate health effects in relation to environmental exposures. The objective of this research was to study the health effects of selected environmental exposure among the urban poor population in Nairobi, Kenya. Methods: We used the platform of the Nairobi Urban Health and Demographic Surveillance System (NUHDSS), including two nested research studies, to provide data on mortality and mor­bidity. The NUHDSS was established in two areas of Nairobi, Korogocho and Viwandani, in 2003 and provides a unique opportunity for access to longitudinal population data. In addition, we conducted real-time measurements of particulate matter (PM2.5) in the areas from February to October in 2013. We obtained meteorological measurements from the Moi Air Base and Nairobi airport weather stations for the study period. We also conducted a cross-sectional survey to estab­lish the communities’ perceptions about air pollution and its related health risks. Time series re­gression models with a distributed lag approach were used to model the relationship between weather and mortality. A semi-ecological study with group level exposure assignment to individuals was used to assess the relationship between child health (morbidity and mortality) and the extent of PM2.5 exposure. Results: There was a significant association between daily mean temperature and all-cause mor­tality with minimum mortality temperature (MMT) in the range of 18 to 20 °C. Both mortality risk and years of life lost analysis showed risk increases in relation to cold temperatures, with pronounced effect among children under-five. Overall, mortality risks were found to be high during cold periods of the year, rising with lower temperature from MMT to about 40% in the 0–4 age group, and by about v 20% among all ages. The results from air pollution assessment showed high levels of PM2.5 concentration exceeding World Health Organization (WHO) guideline limits in the two study ar­eas. The air pollution concentration showed similar seasonal and diurnal variation in the two slums. The majority of community residents reported to be exposed to air pollution at work, with 66% reporting to be exposed to different sources of air pollution. Despite the observed high level of exposure, residents had poor perception of air pollution levels and associated health risks. Children in the high-pollution areas (PM2.5≥ 25 μg⁄m3) were at significantly higher risk for morbidity (OR = 1.30, 95% CI: 1.13-1.48) and cough as the only form of morbidity (OR = 1.33, 95% CI: 1.15-1.53) compared to those in low-pollution areas. In addition, exposure to high levels of pollution was associated with high child mortality from all-causes (IRR=1.15, 95% CI: 1.03-1.28), and indicated a positive association to respiratory related mortality (IRR=1.10, 95% CI: 0.91-1.33). Conclusion: The study findings extend our knowledge on health impacts related to environmental exposure by providing novel evidence on the risks in disadvantaged urban populations in Af­rica. More specifically, the study illustrates the invisible health burden that the urban poor population are facing in relation to weather and air pollution exposures. The effect of cold on population is preventable. This is manifested by the effective adaptation to cold conditions in high-latitude Nordic countries by housing standards and clothing, as well as a well-functioning health system. Further, awareness and knowledge of consequences, and reductions in exposure to air pollution, are necessary to improve public health in the slum areas. In conclusion, adverse health impacts caused by environmental stressors are critical to assess further in disadvantaged populations, and should be followed by development of mitigation measures leading to improved health and well being in SSA.

air pollution

urban health

temperature-related mortality

particulate matter

exposure assessment

child health

Climate Change Impacts: Heat-Related Mortality Projections and Population Adaptive Responses in United States

Kusi, Joseph, Li, Ying

09 April 2015

We miss summer time during winter especially when it snows heavily resulting in cancelation of classes but we turn to ignore high temperature and its associated health impacts during summer. Several studies have shown that high temperatures during summer are associated with morbidity and mortality in many cities in the United States over the past decade. Gradual increase in temperature over the past years raises public health concerns about the impacts of heat on human health in future and the role of adaptation. Our study aimed at assessing future heat-related mortality due to climate change in the United States. We hypothesized that incidence of premature death will increase with future temperature rise and population adaptation will reduce the mortality rate. We reviewed research articles on temperature-related premature death. The literature search was limited to studies conducted in United States and seven studies which demonstrated positive association between temperature and premature death were selected for this study. We predicted future high temperature-related mortality using BenMap benefit model designed to estimate 2015 Appalachian Student Research Forum Page 111 air pollution impacts on public health. Based on the selected studies, BenMap model projected 2020-2050 temperature scenario using modeled daily mean apparent temperature to estimate future heat-related mortality. Our results showed that high temperatures would cause an increase in heat-related mortality and adaptation would minimize the effects of climate change as people get used to high temperatures. The outcome of our study confirms the positive association between high temperature and mortality which emphasizes the need for policy makers to take appropriate actions such as greenhouse gas emission reduction to protect public health.

morbidity

health impacts

mortality

public health concerns

adaptation

climate change

united states

air polution

temperature

temperature-related mortality

Environmental Health

Environmental Health and Protection

Environmental Monitoring

Environmental Policy

Environmental Public Health

Environmental Studies

Epidemiology