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Flupenthixol and cefotiam: effects on vitamin A metabolism in rats

Published online by Cambridge University Press:  09 March 2007

Rainer Schindler*
Affiliation:
Department of Human Nutrition and Food Science, Christian-Albrechts-University zu Kiel, D-24105, Germany
Tanja Fielenbach
Affiliation:
Department of Human Nutrition and Food Science, Christian-Albrechts-University zu Kiel, D-24105, Germany
Gerhard Rave
Affiliation:
Institute for Variationsstatistik, Christian-Albrechts-University zu Kiel, D-24105, Germany
*
*Corresponding author: Dr Rainer Schindler, fax +49 431 880 5679, email rschindler@nutrfoodsc.uni-kiel.de
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Abstract

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We examined the alterations in vitamin A metabolism as a result of flupenthixol or cefotiam administration. The impact of these drugs on indices of vitamin A status was evaluated in Brown Norway and Long–Evans rats. Intramuscular drug administration for 28 d resulted in a decline in systemic retinol. Changes in circulating retinol with time for chronic dosing showed drug treatment (P<0·001) and time (P<0·03) to be significant factors, but rat strain (P=0·33) was not a significant factor. Flupenthixol was the most active retinol-lowering compound (P<0·005). At the end of the 28 d period, hepatic retinyl ester hydrolase activity was greater in drug-treated rats than in controls (P<0·05). With regard to effects on liver reserves: (1) flupenthixol treatment resulted in vitamin A depletion (P<0·05); (2) cefotiam treatment stimulated vitamin A accumulation; (3) distinctive patterns of retinol and its esters were seen in response to treatment. It is reasonable to assume that the drugs interfere with vitamin A in at least two ways: (1) lowering of plasma retinol, an early event in the interaction, may be caused by inhibition of hepatic holo-retinol-binding protein secretion or stimulation of clearance, or both; (2) when plasma retinol levels are persistently low, and as the hepatic deposits of the xenobiotics build up, there are changes in the vitamin A pool size and composition of the liver. Candidate enzymes are retinyl ester hydrolase and cytochrome P450. The relationship between these two events will be studied in further detail.

Type
Research Article
Copyright
Copyright © The Nutrition Society 2004

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