Zebrafish based assays for the assessment of cardiac, visual and gut function — potential safety screens for early drug discovery

Safety pharmacology is integral to the non-clinical safety assessment of new chemical entities prior to first administration to humans. The zebrafish is a well established model organism that has been shown to be relevant to the study of human diseases. The potential role of zebrafish in safety phar...

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Bibliographic Details
Published in:Journal of pharmacological and toxicological methods 2008-07, Vol.58 (1), p.59-68
Main Authors: Berghmans, Stéphane, Butler, Paul, Goldsmith, Paul, Waldron, Gareth, Gardner, Iain, Golder, Zoe, Richards, Frances M., Kimber, Gillian, Roach, Alan, Alderton, Wendy, Fleming, Angeleen
Format: Article
Language:English
Subjects:
Animals
Cardiac function assessment
Danio rerio
Drug Evaluation, Preclinical - methods
Drug safety assessment
Drug-Related Side Effects and Adverse Reactions
Freshwater
Gastrointestinal Tract - drug effects
Gastrointestinal Tract - physiology
Gut motility assessment
Heart - drug effects
Heart - physiology
Humans
Larva - drug effects
Larva - metabolism
Models, Animal
Pharmaceutical Preparations - metabolism
QT prolongation
Safety pharmacology
Species Specificity
Time Factors
Toxicity Tests - methods
Vision, Ocular - drug effects
Vision, Ocular - physiology
Visual function assessment
Zebrafish - physiology
Zebrafish methods
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Summary:Safety pharmacology is integral to the non-clinical safety assessment of new chemical entities prior to first administration to humans. The zebrafish is a well established model organism that has been shown to be relevant to the study of human diseases. The potential role of zebrafish in safety pharmacology was evaluated using reference compounds in three models assessing cardiac, visual and intestinal function. Methods: Compound toxicity was first established in zebrafish to determine the non toxic concentration of a blinded set of 16 compounds. In the cardiac assay, zebrafish larvae at 3 days post fertilisation (d.p.f.) were exposed to compounds for 3 h before measurement of the atrial and ventricular rates. To investigate visual function, the optomotor response was assessed in 8 d.p.f. larvae following a 5 day compound exposure. In the intestinal function assay, the number of gut contractions was measured in 7 d.p.f. larvae after a 1 h compound exposure. Finally, compound uptake was determined for 9 of the 16 compounds to measure the concentration of compound absorbed by the zebrafish larvae. Results: Seven compounds out of nine produced an expected effect that was statistically significant in the cardiac and visual functions assays. In the gut contraction assay, six out of ten compounds showed a statistically significant effect that was also the expected result whilst two displayed anticipated but non-significant effects. The compound uptake method was used to determine larval tissue concentrations and allowed the identification of false negatives when compound was poorly absorbed into the zebrafish. Discussion: Overall, results generated in three zebrafish larvae assays demonstrated a good correlation between the effects of compounds in zebrafish and the data available from other in vivo models or known clinical adverse effects. These results suggest that for the cardiac, intestinal and visual function, zebrafish assays have the potential to predict adverse drug effects and supports their possible role in early safety assessment of novel compounds.
ISSN:1056-8719
1873-488X
DOI:10.1016/j.vascn.2008.05.130