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Chem Res Toxicol


Title:"On the generation and outcome of 3-(N-phenylamino)propane-1,2-diol derivatives in deodorized model oils related to toxic oil syndrome"
Author(s):Morato A; Escabros J; Manich A; Reig N; Castano Y; Abian J; Messeguer A;
Address:"Department of Biological Organic Chemistry and Process Modeling Unit, Department of Ecotechnology, Institut d'Investigacions Quimiques i Ambientals de Barcelona, CSIC, Barcelona, Spain"
Journal Title:Chem Res Toxicol
Year:2005
Volume:18
Issue:4
Page Number:665 - 674
DOI: 10.1021/tx0497595
ISSN/ISBN:0893-228X (Print) 0893-228X (Linking)
Abstract:"Toxic Oil Syndrome (TOS) was a massive food-born intoxication that occurred in Spain in 1981 and affected more than 20,000 people. TOS was attributed to the ingestion of rapeseed oil that had been adulterated with aniline, illegally refined, and delivered for human consumption. Two chemical species derived from aniline have been identified in oil batches: fatty acid anilides, qualified as biomarkers of the adulterated oil, and fatty acid esters of 3-(N-phenylamino)propane-1,2-diol (PAP), considered toxic oil biomarkers. These esters were generated by chemical processes during oil refining, specifically in the deodorization step, which involves treatment of the oil at high temperatures under vacuum to remove volatile contaminants. Since PAP derivatives are strongly associated with TOS, their formation and putative interconversion in a toxic oil model has been studied. The main results obtained are (i) only triglycerides and aniline are required to produce PAP esters, thus eliminating the possibility that unknown activators present in the deodorization tank were required for toxification of the oil; (ii) PAP and PAP mono- and diesters are chemically interrelated, as are anilides and PAP esters to an even higher degree. In addition to the reaction of aniline with triglycerides, anilides can be also formed via attack of PAP esters by aniline. However, the most important source of anilides during deodorization seems to be the thermal decomposition of PAP esters. Overall, these results suggest that the generation and outcome of PAP derivatives during deodorization is a complex scenario whereby PAP esters are not only generated from different reactions but decompose to produce anilides, among other compounds. In addition to providing a rapeseed oil model that reproduces the composition of case oils with respect to anilides and PAP derivatives, the results presented herein further support the hypothesis imputing PAP diesters or their metabolites for the intoxication episode"
Keywords:"Anilides/metabolism Fatty Acids, Monounsaturated Food Contamination Humans Plant Oils/*poisoning Poisoning/metabolism Propylene Glycols/*metabolism Rapeseed Oil Research Design Syndrome;"
Notes:"MedlineMorato, Anna Escabros, Jordi Manich, Albert Reig, Natalia Castano, Yolanda Abian, Joaquin Messeguer, Angel eng Research Support, Non-U.S. Gov't 2005/04/19 Chem Res Toxicol. 2005 Apr; 18(4):665-74. doi: 10.1021/tx0497595"

 
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