Abstract
FTIR spectroscopy is a promising method for quantification of edible oils. Three edible oils, namely, red fruit oil (RFO), corn oil (CO), and soybean oil (SO), in ternary mixture system were quantitatively analyzed using FTIR spectroscopy in combination with partial least square (PLS). FTIR spectra of edible oils in ternary mixture were subjected to several treatments including normal spectra and their derivative. Using PLS calibration, the first derivative FTIR spectra can be exploited for determination of RFO; meanwhile, the second derivative spectra were preferred for determination of CO and SO. The R2 values obtained for the relationship between actual and FTIR predicted values of RFO, CO, and SO were 0.9863, 0.9276, and 0.9693, respectively. The root mean square error of calibration (RMSEC) values obtained were 1.59, 1.72, and 1.60% (v/v) for RFO, CO, and SO, respectively. The result showed that FTIR spectroscopy offers accurate and reliable technique for quantitative analysis of RFO, CO, and SO simultaneously in ternary mixture systems. Besides, the developed method can be extended for analysis of CO and SO as adulterants in RFO.
Highlights
In the fats and oils industry, red fruit oil (RFO) has become an emerging functional oil, especially in Indonesia
We developed Fourier transform infrared (FTIR) spectroscopy in combination with partial least square (PLS) calibration for simultaneous analysis of RFO mixed with soybean oil (SO) and corn oil (CO) in ternary mixture system
Triglycerides are the main components of edible fats and oils; as a consequence, FTIR spectra of triglycerides dominate in FTIR spectra of fats and oils [20]
Summary
In the fats and oils industry, red fruit oil (RFO) has become an emerging functional oil, especially in Indonesia. RFO is obtained from the extraction of red fruit (Pandanus conoideus Lam.). The extract of red fruit has been reported to possess antioxidant activities [1]. Compared with common vegetable oils available in the market, such as corn and soybean oils, RFO is more expensive by 10–15 times. RFO can be faked with other cheaper oils like corn oil (CO) and soybean oil (SO) in order to get the maximum profits. The practice of adulteration can involve the dilution of RFOs with one or more oils. The detection and quantification of oil adulterants such as CO and SO in RFO are highly demanded
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