Uptake and Effects of the Beta‐Adrenergic Agonist Salbutamol in Fish: Supporting Evidence for the Fish Plasma Model

The fish plasma model (FPM) predicts the fish blood plasma concentration of a pharmaceutical from the water concentration to which the fish is exposed and compares it with the human therapeutic plasma concentration (HtherPC) with the postulate that no adverse toxic effects occur below the HtherPC. T...

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Veröffentlicht in:	Environmental toxicology and chemistry 2019-11, Vol.38 (11), p.2509-2519
Hauptverfasser:	Weil, Mirco, Falkenhain, Anna‐Maria, Scheurer, Marco, Ryan, Jim J., Coors, Anja
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Sprache:	eng
Schlagworte:	Acute toxicity Adrenergic beta-Agonists - blood Adrenergic beta-Agonists - chemistry Albuterol - blood Albuterol - chemistry Animals Bioconcentration Biomass Blood levels Blood plasma Environmental Monitoring Environmental risk assessment Exposure Fish Fish early life stages Fish plasma model Fishes - blood Heart Heart Rate Models, Biological Plasma Salbutamol Sympathomimetics Toxicity Triglycerides
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creator	Weil, Mirco Falkenhain, Anna‐Maria Scheurer, Marco Ryan, Jim J. Coors, Anja
description	The fish plasma model (FPM) predicts the fish blood plasma concentration of a pharmaceutical from the water concentration to which the fish is exposed and compares it with the human therapeutic plasma concentration (HtherPC) with the postulate that no adverse toxic effects occur below the HtherPC. The present study provides several lines of evidence supporting the FPM for the beta‐adrenergic agonist salbutamol, a small cationic molecule at ambient pH. Salbutamol exhibited very low acute toxicity to early and adult life stages of fish. Biomass reduction in fish early life stages was the most sensitive apical endpoint, with no‐observed‐effect concentrations (NOECs) in the low mg/L range after continuous exposure for up to 120 d. Given that predicted and measured environmental concentrations are at least 1000‐fold lower, the risk of salbutamol in freshwater is deemed very low. Increase in heart beat rate and decrease in total triglyceride content in fish also occurred at the low mg/L range and resembled effects known from humans. This finding supports the FPM assumption of conserved targets in fish with similar functionality. Plasma concentrations measured in adult and juvenile fish exposed to water concentrations at approximately the NOECs exceeded HtherPC and even approached plasma concentrations toxic to humans. This result confirms for salbutamol the FPM hypothesis that no adverse (i.e., population‐relevant) toxic effects occur in fish below the HtherPC. Environ Toxicol Chem 2019;38:2509–2519. © 2019 SETAC
doi_str_mv	10.1002/etc.4543
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The present study provides several lines of evidence supporting the FPM for the beta‐adrenergic agonist salbutamol, a small cationic molecule at ambient pH. Salbutamol exhibited very low acute toxicity to early and adult life stages of fish. Biomass reduction in fish early life stages was the most sensitive apical endpoint, with no‐observed‐effect concentrations (NOECs) in the low mg/L range after continuous exposure for up to 120 d. Given that predicted and measured environmental concentrations are at least 1000‐fold lower, the risk of salbutamol in freshwater is deemed very low. Increase in heart beat rate and decrease in total triglyceride content in fish also occurred at the low mg/L range and resembled effects known from humans. This finding supports the FPM assumption of conserved targets in fish with similar functionality. Plasma concentrations measured in adult and juvenile fish exposed to water concentrations at approximately the NOECs exceeded HtherPC and even approached plasma concentrations toxic to humans. This result confirms for salbutamol the FPM hypothesis that no adverse (i.e., population‐relevant) toxic effects occur in fish below the HtherPC. 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The present study provides several lines of evidence supporting the FPM for the beta‐adrenergic agonist salbutamol, a small cationic molecule at ambient pH. Salbutamol exhibited very low acute toxicity to early and adult life stages of fish. Biomass reduction in fish early life stages was the most sensitive apical endpoint, with no‐observed‐effect concentrations (NOECs) in the low mg/L range after continuous exposure for up to 120 d. Given that predicted and measured environmental concentrations are at least 1000‐fold lower, the risk of salbutamol in freshwater is deemed very low. Increase in heart beat rate and decrease in total triglyceride content in fish also occurred at the low mg/L range and resembled effects known from humans. This finding supports the FPM assumption of conserved targets in fish with similar functionality. 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subjects	Acute toxicity Adrenergic beta-Agonists - blood Adrenergic beta-Agonists - chemistry Albuterol - blood Albuterol - chemistry Animals Bioconcentration Biomass Blood levels Blood plasma Environmental Monitoring Environmental risk assessment Exposure Fish Fish early life stages Fish plasma model Fishes - blood Heart Heart Rate Models, Biological Plasma Salbutamol Sympathomimetics Toxicity Triglycerides
title	Uptake and Effects of the Beta‐Adrenergic Agonist Salbutamol in Fish: Supporting Evidence for the Fish Plasma Model
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