Generalized dose-response function: Difference between revisions
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{{Variable|Exposure-response functions}} | {{Variable|Exposure-response functions}} | ||
== | ==Question== | ||
'''Generalized dose-response function''' (GDR) describes general properties of the shape of the relationship between the dose of a chemical and a particular response in mammals. Often the focus is on the probability of a particular level of response. This is called generalised dose--response-probability function (GDRP). The primary source of information is pharmacology, toxicology, and epidemiology. This knowledge is then transformed into a mathematical form. | '''Generalized dose-response function''' (GDR) describes general properties of the shape of the relationship between the dose of a chemical and a particular response in mammals. Often the focus is on the probability of a particular level of response. This is called generalised dose--response-probability function (GDRP). The primary source of information is pharmacology, toxicology, and epidemiology. This knowledge is then transformed into a mathematical form. | ||
== | ==Answer== | ||
==Rationale== | |||
=== Causality === | === Causality === | ||
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*GDRP: probability of the response | *GDRP: probability of the response | ||
== | ==See also== | ||
==References== | |||
<references/> | |||
Latest revision as of 08:15, 13 October 2012
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Question
Generalized dose-response function (GDR) describes general properties of the shape of the relationship between the dose of a chemical and a particular response in mammals. Often the focus is on the probability of a particular level of response. This is called generalised dose--response-probability function (GDRP). The primary source of information is pharmacology, toxicology, and epidemiology. This knowledge is then transformed into a mathematical form.
Answer
Rationale
Causality
Causally upstream variables have not been defined.
Data
There are several issues that may affect the shape of the dose-response function of a particular chemical. However, the GDR should be described in such a flexible and detailed way that it reflects any of the shapes determined by these factors.
- Mode of action
- Mutagenicity
- Enzyme induction
- Depletion of an essential chemical in the body
- Disruption of homeostasis
- Block of a metabolic pathway
- Time course of the effect
This is a preliminary list of issues that are known (or suspected) about dose-response-probabilities.
- Usually there is a background risk >0 (probability of observing the response in absence of the chemical).
- The response is usually monotonically increasing. However, there are two important exceptions:
- At large doses, other (toxic) mechanisms might activate and overrule the mechanism that is causing the response of interest.
- At low doses, some defence mechanisms may activate thus preventing the (adverse) effect or even reversing it. When this occurs, the impact of this hormesis effect is typically ca. 10 % of the maximum response at high doses. How this reflects into the response probabilities needs to be discussed.
- The DRP curves are usually rather smooth. However, there might be threshold mechanisms working, resulting in no impact until the threshold is exceeded, and then there may be a rapid increase in response. Although this may be true in the individual level, usually interindividual variation about the threshold smooths the population-level observations. It is rare to have two different thresholds working in the same individual in such a way that it would be of biological interest. Therefore, a single threshold assumption is enough. (Should this be discussed?)
Formula
The multistage model is used as the first placeholder for a generalised DRP.
P(Response|Dose)= background +(1-background)*(1-exp(-q1*Dose -q2*Dose^2 -q3*Dose^3...))
Unit
- GDR: depends on the response
- GDRP: probability of the response