Study objective: European Union legislation requires large industrial and civil development projects to undergo environmental impact assessment. The study objective was to identify environmental health risk estimates for these developments from the epidemiological literature and to develop, and apply these within, a mathematical health impact assessment model.
Design and results: In the UK, good practice guidelines have set out environmental issues to be considered in development projects, but little attention is given to direct health effects. Broad quantifiable risks were identified for four—air, chemicals, noise, and road traffic—of 14 standard environmental effects. A mathematical model was constructed that is based on people moving between different health states over their lifetime. Age related hazard functions are applied to cause specific measures of mortality and morbidity. A hypothetical example for a development creating air and chemical pollutants is given.
Conclusions: A mathematical model applying epidemiological risks to an exposed population can provide quantification of environmental health effects. The approach may in future find application during project development, and by public health regulatory authorities for environmental health impact assessment.
- mathematical model, health impact assessment
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Economic developments, such as large industrial plant or civil construction, may have environmental and health consequences. Environmental impact assessment was developed in the United States in the 1970s to control industrial pollution. In European Union countries, through Directives 85/337/EEC1 and 97/11/EC,2 environmental impact assessment has been implemented as part of planning control. Health impact assessment, in contrast, has developed during the 1990s. While using approaches similar to environmental impact assessment, it is not regulated by law,3 and policies and other activities beyond the healthcare sector have been assessed, as well as economic developments. Health impact assessment is developing at international and national levels4,5 as well as more locally.6–8 Guidelines for health impact assessment have been produced in several countries.9,10
We have investigated how epidemiology can contribute to health impact assessment of environmental developments, using mathematical modelling. The work had three components: defining the relation of environmental assessment to health impact assessment; identifying epidemiological information that links environmental data to morbidity or mortality; and developing a mathematical model to predict the population health impacts.
METHODS AND RESULTS
In the United Kingdom, the Department of the Environment has described environmental impact assessment as a “technique and a process by which information about the environmental effects of a ‘project’ is collected, both by the developer and from other sources, and taken into account by the planning authority in forming their judgements on whether the development should go ahead”.11 The environmental impact assessment process includes screening, scoping, preparing an environmental statement, appraising the statement, negotiation, and risk management.3
The United Kingdom Environmental Impact Assessment Regulations12 require “specified information” within environmental statements including: “a description of the likely significant effects, direct and indirect, on the environment of the development, explained by reference to its possible impact on—human beings; flora; fauna; soil; water; air; climate; the landscape . . .” The environmental statement may also include “by way of explanation or amplification, further information including `an estimate, by type and quantity, of expected residues and emissions (water, air and soil pollution, noise, vibration, light, heat, radiation, etc) resulting from the operation of the proposed development”.
Both the United Kingdom government13 and industry14 have produced guidance on good practice. There is also a guide that helps local planning authority decision makers evaluate “environmental information” that is contained in an environmental statement.15 These guides require investigation of the effects on human beings, but do not indicate the possible impacts on health. Between July 1988 and April 1998, 3103 environmental impact assessments are known to have been submitted in the United Kingdom.16 The most frequent projects were waste disposal (21%), road building (14%), mining (14%), energy (13%), and urban/retail developments (13%).16 Environmental impact assessment is undertaken by commercial consultancies on behalf of the developers presenting their application to local planning authorities. However, there is considerable variation in professional practice, in the scope and detail of the review and in the degree of quantification.
The data for our model include epidemiological risk information, population structure and disease characteristics, and an estimate of the exposed population. We reviewed a wide range of literature, including: guidelines for health impact assessment,9,10 reviews of the health impact assessment literature,6,17 guides to environmental impact assessment,18 reviews of environmental health19 and the use epidemiological evidence for environmental health risk assessment,20,21 web sites,22,23 and grey literature reports.
Areas of environmental concern are usually set out in environmental statements within a standard structure. We identified 14 environmental factors/themes relevant to health from The Essex Guide to Environmental Impact Assessment,18 which described environmental topics that may be relevant to consider when carrying out an environmental assessment. Table 1 shows our assessment of environmental health effects for which quantitative risk estimates could be or have been derived for these areas. We included four in our model—outdoor air, chemicals, noise, and transport—where quantitative estimates were strongest. Literature for other health effects of other environmental factors, such as social dimensions or climate change, could not be adequately quantified from the literature search for our model.
Two reports provide quantitative estimates of the effects of air pollution on health. A national committee in the United Kingdom24 draws on time series studies that examine the relation between daily levels of air pollution and the risk of adverse health effects, on the same day or subsequent days. A World Health Organisation working group additionally linked evidence of long term effects of exposure to PM10 on total mortality and chronic bronchitis from cohort studies with population data from Austria, France, and Switzerland.25
For chemicals classed as carcinogens, dose related estimates of excess lifetime cancer risk have been produced by national bodies such as the United States Environmental Protection Agency,23 through a process of quantitative risk assessment.26 These risk assessments mostly rely on data from animal studies as there are less data from epidemiological studies. The lifetime excess cancer risk is an additional risk that the local population might face, and can be converted into a relative risk by calculating the background lifetime cancer risk using Office of National Statistics age specific annual incidence data.
Reviews27,28 indicate that there is some evidence to suggest that community noise may increase blood pressure (the clinical significance of which is unclear) or be a risk factor for coronary heart disease. Noise exposure during sleep may increase blood pressure and heart rate, and noise disturbance may differ across demographic groups of the population; older people, and possibly women may be more affected by noise during sleep.28 De Hollander et al7 estimated that noise contributed about a quarter of the health loss (as disability adjusted life years) associated with selected environmental exposures in the Netherlands.
Reviews29,30 and a report prepared for the WHO Ministerial Conference on Environment and Health in London 199931 indicate the wide range of potential effects of transport and health. One effect of transport, air pollution, has been considered earlier. Other important effects are injuries from collisions and potential cardiovascular benefits at all ages from walking and cycling. At present, only information on accidents is sufficiently quantified.
The population exposed will differ for each of these environmental factors. Air pollution is usually modelled geographically in the environmental statement. Chemicals may be assessed as air dispersion and also by water. Noise depends on proximity and frequency. Traffic is variable, and may affect both resident and working populations. The smallest geographical areas for these health data are larger than that available for the population from the census. Changes in area boundaries complicate the interpretation of area statistics. The accuracy of statistics at sub-national levels has been discussed.32
The model is based on people moving between different health states over their lifetime, as they develop or recover from various health conditions, or die. To describe baseline population health, data are included for the exposed population by age and sex. For the given population, the model calculates baseline age and sex related hazard functions, drawn from mortality and morbidity statistics. The expected effects of exposure (relative risks), of different levels of exposure, to the environmental changes are then incorporated, and the model recalculates estimates for the health status of the population in the presence of the development. The differences between the two sets of estimates are taken as the health impact of the development.
A diagram of the elements of the model is shown in figure 1. The four elements are:
Environmental factors can cause or exacerbate health problems. The health impact of the development will be largely influenced by the level and nature of the environmental changes, which are described in the environmental impact assessment. Population exposures are indicated, for example, in wind plume models or traffic densities.
A given environmental change will affect different populations in different ways. The age and gender profile of the local population is of particular importance to the overall effect of a set of environmental changes. For example, a pollutant that affects fertility will have a larger impact on a population with a large proportion of women of childbearing age compared with women beyond childbearing age.
Underlying age related disease and mortality rates influence the impact of environmental changes on the local population. Also, population dynamics within the local area will affect the amount of exposure to environmental changes faced by different sections of the population.
Timescale of project
The duration of the proposed development and hence the length of time that the local population are exposed to the attendant environmental changes will influence the level of health impact on the local population.
Hypothetical example of the model
A hypothetical example shows our approach. A major redevelopment of a chemical plant is planned. The environmental impact assessment of the proposal has predicted that the main environmental impacts will be the pollution of the local water supply with benzidine and a decrease in PM10 emissions. Forty per cent of the 50 000 local population will be exposed to benzidine at a level that increases the hazard for developing cancer by 1.04. All of the local population will be subject to PM10 levels that are 20 μg/m3 lower than previously. This change is estimated to reduce the hazard for developing bronchitis by 0.83. The redeveloped plant is expected to operate for 15 years.
Computer software has been written to implement the model. This has been used to estimate the excess mortality and morbidity due to this hypothetical development over the 15 years of its duration. A graphical display of the estimated changes in mortality and morbidity attributable to the proposed development are shown in figure 2.
The new public health interest in health impact assessment methodologies provides an opportunity for revisiting environmental impact assessment.3 The European Office of the World Health Organisation has provided advice on the use of epidemiological evidence for environmental health risk assessment20 and has established an office to promote health impact assessment. The United Kingdom Royal Commission on Environmental Pollution has suggested the need “to include explicit and formal requirements for assessment of the potential impacts of all developments on health”.33 Methods for environmental impact assessment have developed within a legal framework, receiving little direct input from public health practitioners.34 Nevertheless, local planning authorities place more weight on an environmental impact assessment that contains quantified analyses of environmental impact than on one that seems to be based only on qualitative analyses,35 and this may encourage quantification of health impacts.
The World Health Organisation has recommended that “study reports should describe as precisely as possible the exposure characteristics, shape of the exposure-response function, as well as distinguish between the acute and chronic effects of exposure”.20 However, at present few epidemiological studies provide useable population risk estimates for health impact assessment. We drew on literature reviews in four areas using different approaches.
Health effects are not routinely included in environmental impact assessment.
Some epidemiological estimates of risk can be applied to environmental data.
A new mathematical model that quantifies the effect on population health status of changes in exposure to environmental factors has been constructed.
Modelling can assist public health and environmental practice in health impact assessment.
In the relatively well researched field of air pollution, two recent studies of health impacts gave estimates of short and long term effects respectively.24,25 The risk of chemicals causing cancer has been assessed through both epidemiological and animal model studies.36 De Hollander et al 7 have considered the implications of aggregating risk estimates, and estimating their interactions, within a single model.
Guideline values, or criteria, for individual maximal exposure are generally used in environmental statements to assess the likelihood of health effects, but it is important to assess the cumulative risk for chronic diseases that develop over a lifetime. Our model is able to incorporate development of both morbidity and mortality. While the epidemiological literature mainly reports mortality and illness episodes, disability adjusted life years37 may provide useful approach in the future.
We have only identified adequate data for a minority of all areas included within environmental statements. Some of these are impacts on ecology rather than human populations: our approach is more applicable to urban developments. Although health may be affected by other factors included in environmental statements, for example, community severance or climate effects, epidemiological estimates in the literature are not sufficiently clear. We have also excluded effects during construction, on workers during production and the impact of hazardous incidents. These are more usually considered in the occupational health literatures. For epidemiological approaches to health impact assessment to develop further, more quantitative environmental information will be needed in environmental statements and more evidence of their health effects required.
Mathematical modelling has potential for improving the scientific quality of, and tools for, health impact assessment. Models have been developed in other public health fields, such as infectious diseases (for example, predicting development of vCJD38), screening (for example, cervical cancer39), and assessment of medical interventions (for example, cardiac surgery40). The PREVENT model developed by Gunning-Schepers 41 was designed to assess the impacts of health promotion policies on mortality, and has been used to evaluate the effects of increased exercise on population heart disease.42 In contrast, our model is closed, without migration or replacement by new births, and assumes that demographic trends and other risk factors are constant. The model can estimate impacts on both morbidity and mortality for populations of different sizes affected by the point source environmental pollution, and competing risks are taken into account.
A mathematical model for health impact assessment could facilitate assessment of different options and scenarios both during project development, and for planning control. For example, the duration of a proposed development, or different emission levels, could be modelled to assess cumulative health impact. Equally, it would be possible to assess the effects of alternative locations or technological adaptations. This process of review and modification already exists within environmental impact assessment. Further work is needed to learn how to present the results of models, including their different health estimates and statistical uncertainty, to decision makers.
Epidemiological data can be applied to environmental data to generate quantitative estimates of health impact. A mathematical model can be used to assess policy options. There is public interest in better data to inform decision making and planning processes. There needs to be closer collaboration between public health and environmental practice, in order to interpret environmental data better and to identify further epidemiological data needed.
APPENDIX BRIEF DESCRIPTION OF THE OPERATION OF THE MATHEMATICAL MODEL
The mathematical model has a generic structure such that the impact on many dimensions of the health of a population of a range of environmental changes may be estimated. The health of individuals within the population is represented in the model by a number of “states”, each representing a unique combination of features reflecting health status. For example, a state might be defined in terms of presence or absence of cancer, presence or absence of asthma, and alive or dead. There would be states corresponding to all combinations of these three factors. Such states can also be extended to reflect mortality by different causes, for example, reflecting the possibility of death resulting from a road traffic accident. The model is based on estimating age and gender related state probabilities, reflecting the proportions of the local population in each of the different health states. The model operates by evolving these state probabilities over some specified time frame, taking into account expected changes in exposure to environmental factors attributabler to a proposed project. Full details of the structure and workings of the model are available from the authors. Here we present how the model would operate for the hypothetical example given in this paper.
In the example given, individuals within the population are considered to be in one of seven health states, namely
1 Alive with neither cancer nor bronchitis
2 Alive with bronchitis but without cancer
3 Alive with cancer but without bronchitis
4 Alive with both cancer and bronchitis
5 Dead due to bronchitis
6 Dead due to cancer
7 Dead due to a cause other than cancer or bronchitis
For each section of the population, defined by age, sex and risk exposure, the health of that subgroup is separately modelled over sequential five year periods.
Consider the subgroup of the population composed of men aged 40–44 that are not exposed to any of the environmental changes associated with a project. Let pi(t) be the probability that an individual that is a member of this subgroup is in health state i at a time t into the modelled period, where the index variable i corresponds to the labels given to the states above.
The probabilities pi(t) are linked by the differential equations
Where αij is the hazard for a man of age 40–44 who is not exposed to the environmental changes of the proposed project, moving from health state i to health state j. Note that it is assumed that a set of constant hazards applies to a subgroup of the population over a five year period.
The mathematical model sets up and solves these differential equations for each subgroup of the population. The effect of exposure to environmental factors is modelled by adjusting the hazards that apply to the exposed sections of the population. For example, the equations that apply to men aged 40–44 exposed to both the benzidine pollution and lower PM10 emissions associated with the proposed project discussed in the text are:
In the example given, exposure to each of the two factors considered is viewed as all or nothing with no dose-response relationship. The generic structure of the model allows more complicated exposure effects with different sections of the population being exposed to differing levels of each environmental factor considered. This simply increases the number of subgroups within the population and hence the number of sets of differential equations that the model constructs and solves.
Funding: project grant from the Department of Health, UK.
Conflicts of interest: none.
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