Guidance and methods for indicator selection and specification
This is a guidance document for selecting and specifying indicators as a part of applying the Intarese method.
KTL/MNP (E. Kunseler, L. van Bree, M. van der Hoek, M. Pohjola, J. Tuomisto)
Introduction
Integrated risk assessment, as applied in the Intarese project, can be defined as the assessment of risks to human health from environmental stressors based on a ‘whole system’ approach. It thus endeavours to take account of all the main factors, links, effects and impacts relating to a defined issue or problem, and is deliberately more inclusive (less reductionist) than most traditional risk assessment procedures. (D. Briggs, 16.5.06))
Key characteristics of integrated assessment are:
- It is designed to assess complex policy-related issues and problems, in a more comprehensive and inclusive manner than that usually adopted by traditional risk assessment methods.
- It takes a ‘full-chain’ approach – i.e. it explicitly attempts to define and assess all the important links between source and impact, in order to allow the determinants and consequences of risk to be tracked in either direction through the system (from source to impact, or from impact back to source).
- It takes account of the additive, interactive and synergistic effects within this chain and uses assessment methods that allow these to be represented in a consistent and coherent way (i.e. without double-counting or exclusion of significant effects).
- It presents results of the assessment as a linked set of policy-relevant ‘outcome indicators’.
- It makes the best possible use of the available data and knowledge, whilst recognising the gaps and uncertainties that exist; it presents information on these uncertainties at all points in the chain. (D. Briggs, 16.5.06)
The Intarese approach emphasizes on creation of causal linkages between the determinants and consequences in the integrated assessment process. For this purpose, a full chain diagram should be constructed in which variables are the leading components. This full chain development represents the source-impact chain, which is based on different frameworks developed from the pressure-state-response (PSR) concept originally proposed by the US-EPA (e.g. DPSIR, DPSEEA) and the source-receptor models widely used to represent the fate of pollutants in the environment. (D. Briggs, 16.5.06)
This is a guidance document for developing policy-relevant indicators within the Intarese approach to integrated risk assessment, taking into account both the emphasis on causality in the full-chain approach and the applicability of the indicators in relation to policy needs.
What are indicators?
Indicator selection provides the bridge between the issue framework and the assessment process. It involves specifying the outcome measures to be used as a basis for risk characterisation. Indicators should ideally represent all the main nodes and links that make up the source-impact chain, and should be internally coherent – i.e. they should have clear and definable relationships within the context of this chain. (D. Briggs, 16.5.06)
More generally indicators can be defined as variables which are of specific interest. The specific interest can be defined by identifying the use purpose and the users of the assessment, which further leads to identifying which are the variables of specific interest in each assessment. The full-chain description consists of variables. The main nodes and links that make up the source-impact chain are variables of specific interest and are referred to as indicators.
The idea behind the indicator selection, specification and use is to highlight the most important and/or significant parts of the source-impact chain which has been/is to be assessed. Indicators are also helpful in communicating about the assessment and in using the assessment product. Indicators may also be useful in enhancing coherence between different assessments.
Types of indicators
Indicators can take very different forms. Detailed categorisation of different types of indicator is fraught with difficulty, and is unlikely to be helpful. In terms of environmental health, a distinction has sometimes been made, however, between exposure-side indicators and health-side indicators. This distinction is useful in relation to INTARESE, because it discriminates between the forward looking indicators of exposure (i.e. those that presage, and need to be linked to, a potential health effect) and the backward looking indicators of outcome or effect (i.e. those that imply, and need to be attributed to, an exposure or source). (D. Briggs, 16.5.06)
Exposure-side indicators are clearly relevant for policy, since they often provide the first indications of the potential for health risk, and the first evidence of the effects of intervention (since many policies are focused on the upper links in the source-impact chain). To be meaningful in the context of health risks, however, they must relate to factors with definable (or at least strongly plausible) links to health outcome. (D. Briggs, 16.5.06)
Health-side (or outcome) indicators represent the consequences of exposures in terms of health effect (e.g. mortality, morbidity, DALYs) or its further societal impacts (e.g. economic costs, quality of life). Again, to be meaningful in the context of the full-chain approach, they need to have an explicit link back to causal environmental exposures and risk factors. (D. Briggs, 16.5.06)
In each case, the indicators may be expressed in different ways, depending on:
- Whether they are static (state, condition) or dynamic (process, flux) indicators;
- Whether they are expressed in quantitative (‘objective’) or qualitative (perception) measures;
- Whether or not they relate to a formal (and internal) reference level or target (performance indicators).(D. Briggs, 16.5.06)
Indicators in the full-chain approach
Based on the developments onIntarese assessment framework and the Intarese general method, two approaches for selecting and specifying indicators applying the full-chain approach can be identified and distinguished. The distinction is made based on the point in development where causal linkages between variables are defined and how strictly the causality throughout the full-chain description is emphasized. The two views are described briefly below.
File:Causal links defined with variables.PNG
Figure 1: Variables and their causal relations are specified simultaneously
The first approach described in figure 1 starts from the issue framing by translating it into a set of variables (circles) and their causal relations (connecting arrows), representing the outline of the system to be assessed. The result of this is a (draft) causal chain description of the phenomena to be assessed, on a relatively high level of abstraction, representing the determinants across the chain as variables. At this point the variables do not necessarily need to be specified into any more detail than to have a name and to have some draft specification of its scope. Also the causal relations at this point need not be any more detailed than to just imply that a causal relation between certain variables exists.
The causal chain description can naturally be further improved as seen necessary by combining (too detailed level) variables into more general variables, dividing (too general level) variables into more detailed ones, adding needed variables to the chain, removing variables that turn out irrelevant, changing the causal links etc.
When the causal chain has been described, the indicators, the variables of specific interest, can be chosen among the set of variables. (If necessary, new indicator variables can be added to the description. This may be the case for example if a desired indicator is e.g. a ratio of two variable's result values, but this indicator is not relevant in estimating the endpoint variables downstream in the causal chain.)
Then the variables used in the assessment process should also be defined and described. This also helps in ensuring that all the terms used in the assessment are consistent and explicit. Descriptions should cover the scope of each variable, methods/models used to compute or derive the variable, and the data (and associated data sources) on which these are based. Variables in this context may take different forms and serve different roles (often simultaneously). They may represent inputs to models (derived variables), interim steps in the calculation process (derived variables) and outputs for reporting (indicators).
The first approach described above could be referred to as developing indicators as a continuous process. The variable specifications including their result value estimates and causal relation descriptions are iteratively improved throughout the course of the assessment process as the knowledge and understanding increases. The causal relation descriptions of variables influence the estimation of the result value eith the aid of data, measurements and models and vice versa.
File:Causal links defined after variables.PNG
Figure 2: Variables are defined as individual objects and subsequently linked
The second approach desribed in Figure 2 starts from the issue framing by choosing the indicators first. The main emphasis is on identifying and defining of a set of variables of specific interest, whilst the causal linkages between them are established and defined at a later stage. Naturally, already in the issue framing, the relationship between the variables are considerd, since they are in some way positioned in relation to each other. Applying this approach creates indicators that are individual components in the overall assessment. It also allows computation methods and models as well as data to be separately defined for each variable. Although maybe being a more conmfortable approach, this also leaves more possibilities for inconsistencies between the indicators and may risk the transparency and reliability of the enspoint variable/indicator specifications and estimates.
This second approach could be referred to as developing indicators as individual objects. This approach is applied e.g. by WHO in their indicator development. The indicator specifications are intended more as an instruction how to come up with the result value estimate, which is then applied to the particular indicator. Indicator result value estimates are then compiled across the full-chain description to produce the result value estimates for the endpoint indicators.
Selecting indicators
As mentioned above, the variables of specific interest can be chosen in relation to the use purpose of the assessment and the needs of the intended users. In principle, any variable could be chosen as an indicator and the set of indicators could be composed of any types (referring to the steps in the full-chain description) of indicators. In practice, the generally relevant types of indicators can be somewhat predefined and even some particular indicators of general indicators can be defined in relation to commonly existing use purposes and user needs. This kind of generality is also helpful in bringing coherence between the assessments and their uses.
In the Intarese assessment framework following groups of relevant indicators have been identified (E. Lebret, A.Knol, L. van Bree):
- Policy deficit indicators
- Health impact indicators
- Economic consequence indicators
- Risk perception indicators
- rationale for choosing indicators in different situations?
- example (sets) of indicators for a particular purpose
Specifying indicators
We suggest a method for policy-relevant outcome indicator development, including characteristics from both approaches towards indicator development as explained in the previous section.
We suggest that all variables, and thus also all indicators, are specified using a fixed set of attributes. The reasoning behind is to secure coherence between variable/indicator specifications and to enhance efficiency of assessment work and re-usability of the outputs of assessment work.
Below is a suggested list of variable/indicator attributes. The list has been developed based on the several principles including, but not limited to, the following:
- Variables are the basic building blocks of risk assessments
- Risk assessments are causal-chain descriptions of (a chosen part) of reality
- All variables in a causal-chain description must be causally linked
- Everything in risk assessments are describes as variables
- Also the causal links are described within the variable specifications (definition:causality)
- In a diagram representation arrows only state the existence of a causal relation, it does not specify the causality
- Also the causal links are described within the variable specifications (definition:causality)
- The risk assessment process proceeds iteratively through specifications and re-specifications of variables (and their causal relations)
Suggested Intarese variable/indicator attributes
- Name
- Scope
- Description
- Scale
- Averaging period
- References
- Unit
- Definition
- Causality
- Data
- Formula
- Variations and alternatives
- Result
- Discussion
Appendix: comparison of different approaches to specifying variables
Table. A comparison of attributes used in Intarese (suggestions), ENHIS indicators, pyrkilo method, and David's earlier version.
Suggested Intarese attributes | WHO indicator attributes | Pyrkilo variable attributes | David's variable attributes |
---|---|---|---|
Name | Name | Name | Name |
Scope | Issue | Scope | Detailed definition |
Description | Definition and description | Description (part of) | - |
Description (part of) | Interpretation | Description (part of) | - |
Description / Scale | Scale | Scope or Description | Geographical scale |
Description / Averaging period | - | Scope or description | Averaging period |
Description / Variations and alternatives | - | Description | Variations and alternatives |
Description (part of) | Linkage to other indicators | Description (part of) | - R↻ |
Unit | Units | Unit | Units of measurement |
Definition / Causality | Not relevant | Definition / Causality | Links to other variables |
Definition / Data R↻ | Data sources or Related data | Definition / Data | Data sources, availability and quality |
Definition / Formula | Computation | Definition / Formula | Computation algorithm/model |
Result (a very first draft of it) R↻ | Not a specific attribute | Result (a very first draft of it) | Worked example |
Discussion | - | - | - |
Done by using categories | - | Done by using categories | Type |
Done by links to glossary | - | Done by links to glossary | Terms and concepts |
Done by argumentation on the Discussion area | Specification of data needed | Done by argumentation on the Discussion page | Data needs |
The postition in a causal diagram justifies the existense | Justification | The postition in a causal diagram justifies the existense | - |
Not relevant | Policy context | Not relevant | Not relevant |
Not relevant | Reporting obligations | Not relevant | Not relevant |