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A rapid, automated method for the determination of cis and trans content of fats and oils by fourier transform infrared spectroscopy
Author(s) -
de Voort F. R.,
Ismail A. A.,
Sedman J.
Publication year - 1995
Publication title -
journal of the american oil chemists' society
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.512
H-Index - 117
eISSN - 1558-9331
pISSN - 0003-021X
DOI - 10.1007/bf02542063
Subject(s) - fourier transform infrared spectroscopy , partial least squares regression , analytical chemistry (journal) , iodine value , infrared spectroscopy , fourier transform , sample preparation , chemistry , fourier transform spectroscopy , spectroscopy , mathematics , chromatography , organic chemistry , statistics , optics , physics , mathematical analysis , quantum mechanics
Abstract A rapid Fourier transform infrared (FTIR) method was developed to simultaneously determine percent cis and trans content of edible fats and oils. A generalized, industrial sample‐handling platform/accessory was designed for handling both fats and oils and was incorporated into an FTIR spectrometer. The system was calibrated to predict the cis and trans content of edible oils by using pure triglycerides as standards and partial least squares as the chemometric approach. The efficacy of the calibration was assessed by triglyceride standard addition, by mixing of oils with varying cis/trans contents, and by analyzing fats and oils of known iodine value. Each of the approaches verified that the FTIR method measured the cis and trans content in a reproducible (±0.7%) manner, with the measured accuracies being 1.5% for standard addition and 2.5% for the chemically analyzed samples. Comparisons also were made to the conventional American Oil Chemists’ Society (AOCS) method for the determination of trans isomers by IR spectroscopy. The FTIR‐partial least squares approach worked well over a wide range of trans contents, including those between 0 and 15%. The sample‐handling accessory designed for this application is robust, flexible, and easy to use, being particularly suited for quality‐control applications. In addition, the analysis was automated by programming the spectrometer in Visual Basic (Windows), to provide a simple, prompt‐based user interface and to allow an operator to carry out cis/trans analyses without any knowledge of FTIR spectroscopy. A typical analysis requires less than two minutes per sample. The derived calibration is transferable between instruments, eliminating the need for recalibration. The integrated analytical system provides a sound basis for the implementation of FTIR methods in place of a variety of AOCS wet chemical methods when analytical speed, cost, and environmental concerns are issues.