Derivation of occupational exposure limits based on target blood concentrations in humans

An approach for deriving occupational exposure limits (OEL) for pharmaceutical compounds is the application of safety factors to the most appropriate pre-clinical toxicity endpoint or the lowest therapeutic dose (LTD) in humans. Use of this methodology can be limited when there are inadequate pre-cl...

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Veröffentlicht in:	Regulatory toxicology and pharmacology 2003-02, Vol.37 (1), p.66-72
Hauptverfasser:	Pastino, G.M., Kousba, A.A., Sultatos, L.G., Flynn, E.J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Anti-Arrhythmia Agents - blood Anti-Arrhythmia Agents - pharmacokinetics Anti-Arrhythmia Agents - toxicity Area Under Curve Humans Inhalation Exposure Linear Models Models, Biological Monte Carlo Method Occupational Exposure - adverse effects Occupational exposure limits Pharmaceuticals Pharmacokinetics Quinidine - blood Quinidine - pharmacokinetics Quinidine - toxicity Safety factors Species Specificity Time Factors Toxicokinetics Uncertainty factors Variability
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description	An approach for deriving occupational exposure limits (OEL) for pharmaceutical compounds is the application of safety factors to the most appropriate pre-clinical toxicity endpoint or the lowest therapeutic dose (LTD) in humans. Use of this methodology can be limited when there are inadequate pre-clinical toxicity data or lack of a well-defined therapeutic dose, and does not include pharmacokinetic considerations. Although some methods have been developed that incorporate pharmacokinetics, these methods do not take into consideration variability in response. The purpose of this study was to investigate how application of compartmental pharmacokinetic modeling could be used to assist in the derivation of OELs based on target blood concentrations in humans. Quinidine was used as the sample compound for the development of this methodology though the intent was not to set an OEL for quinidine but rather to develop an alternative approach for the determination of OELs. The parameters for the model include body weight, breathing rate, and chemical-specific pharmacokinetic constants in humans, data typically available for pharmaceutical agents prior to large scale manufacturing. The model is used to simulate exposure concentrations that would result in levels below those that may result in any undesirable pharmacological effect, taking into account the variability in parameters through incorporation of Monte Carlo sampling. Application of this methodology may decrease some uncertainty that is inherent in default approaches by eliminating the use of safety factors and extrapolation from animals to humans. This methodology provides a biologically based approach by taking into consideration the pharmacokinetics in humans and reported therapeutic or toxic blood concentrations to guide in the selection of the internal dose-metric.
doi_str_mv	10.1016/S0273-2300(02)00028-4
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Use of this methodology can be limited when there are inadequate pre-clinical toxicity data or lack of a well-defined therapeutic dose, and does not include pharmacokinetic considerations. Although some methods have been developed that incorporate pharmacokinetics, these methods do not take into consideration variability in response. The purpose of this study was to investigate how application of compartmental pharmacokinetic modeling could be used to assist in the derivation of OELs based on target blood concentrations in humans. Quinidine was used as the sample compound for the development of this methodology though the intent was not to set an OEL for quinidine but rather to develop an alternative approach for the determination of OELs. The parameters for the model include body weight, breathing rate, and chemical-specific pharmacokinetic constants in humans, data typically available for pharmaceutical agents prior to large scale manufacturing. The model is used to simulate exposure concentrations that would result in levels below those that may result in any undesirable pharmacological effect, taking into account the variability in parameters through incorporation of Monte Carlo sampling. Application of this methodology may decrease some uncertainty that is inherent in default approaches by eliminating the use of safety factors and extrapolation from animals to humans. 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The model is used to simulate exposure concentrations that would result in levels below those that may result in any undesirable pharmacological effect, taking into account the variability in parameters through incorporation of Monte Carlo sampling. Application of this methodology may decrease some uncertainty that is inherent in default approaches by eliminating the use of safety factors and extrapolation from animals to humans. 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subjects	Anti-Arrhythmia Agents - blood Anti-Arrhythmia Agents - pharmacokinetics Anti-Arrhythmia Agents - toxicity Area Under Curve Humans Inhalation Exposure Linear Models Models, Biological Monte Carlo Method Occupational Exposure - adverse effects Occupational exposure limits Pharmaceuticals Pharmacokinetics Quinidine - blood Quinidine - pharmacokinetics Quinidine - toxicity Safety factors Species Specificity Time Factors Toxicokinetics Uncertainty factors Variability
title	Derivation of occupational exposure limits based on target blood concentrations in humans
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