A Rapid Evaluation Method for Unsaturation of Camellia Oil Based on Raman Spectroscopy Technology

被引：0

作者：

Ma J. ^{[1
]}

Tian C. ^{[1
]}

Chen J. ^{[2
]}

Li J. ^{[2
]}

Zhang Y. ^{[3
]}

Hou R. ^{[1
]}

Jin L. ^{[2
]}

机构：

[1] School of Tea and Food Science and Technology, Anhui Agricultural University, Hefei

[2] Qiaqia Food Co., Ltd., Hefei

[3] Mount Huangshan Forestry Research Institute, Huangshan

来源：

Science and Technology of Food Industry | 2024年 / 45卷 / 11期

关键词：

Camellia oil; iodine value; oil unsaturation; quantitative prediction model; Raman spectroscopy;

D O I：

10.13386/j.issn1002-0306.2023060306

中图分类号：

学科分类号：

摘要：

To evaluate the degree of unsaturation of different varieties of Camellia oil, it was necessary to establish a rapid evaluation method with a narrow iodine value range (iodine value difference less than 10). In this study, a rapid quantitative prediction model for iodine value of oil in high-resolution Raman spectroscopy based on linear regression and gradient descent method was established. The Raman signals (785 nm) about 39 group of Camellia oil samples and 10 group of commercially oils were firstly collected. Then, the intensity ratio of peaks of 1656 cm−1 and 1440 cm−1 (I1656/1440) were selected through smoothing algorithm least squares smoothing filter (Savitzky-Golay), polynomial fitting and deconvolution algorithm Lorentzian. A credible model was obtained through correlation analysis with the iodine value of corresponding oil samples. The coefficient of determination (R2) of the test set of the constructed quantitative model was >0.82, the mean square error (MSE) was <0.73 and the root mean square error (RMSE) was <0.85. This quantitative model of edible oil iodine value can accurately and efficiently predict the unsaturation degree of Camellia oil, etc. © The Author(s) 2024.

引用

页码：205 / 212

页数：7

共 35 条

[1] TU W C L., Plantation quality assessment of Camellia oleifera in mid-subtropical China[J], Soil & Tillage Research, 186, pp. 249-258, (2019)
[2] CHEN P, HU C, GU J, Et al., Pyrolysis characteristics of tea oil Camellia (Camellia oleifera Abel.) shells and their chemically pretreated residues:Kinetics, mechanisms, product evaluation and joint optimization[J], Journal of Analytical & Applied Pyrolysis, (2022)
[3] YANG C, LIU X, CHEN Z, Et al., Comparison of oil content and fatty acid profile of ten new Camellia oleifera cultivars[J], Journal of Lipids, 2016, 2, (2016)
[4] ZHENG H L., Chemical constituents of olive oil and from Camellia oleifera seed oil[J], Journal of the Chinese Cereals and Oils Association, 23, (2008)
[5] YUAN J, WANG C, CHEN H, Et al., Prediction of fatty acid composition in Camellia oleifera oil by near infrared transmittance spectroscopy (NITS)[J], Food Chem, 138, pp. 1657-1662, (2013)
[6] LI C, YAO Y, ZHAO G, Et al., Comparison and analysis of fatty acids, sterols, and tocopherols in eight vegetable oils[J], Journal of Agricultural & Food Chemistry, 59, 23, pp. 12493-12498, (2011)
[7] ZEB A., Triacylglycerols composition, oxidation and oxidation compounds in Camellia oil using liquid chromatography–mass spectrometry[J], Chemistry & Physics of Lipids, 165, 5, (2012)
[8] HAN J, SUN R, ZENG X, Et al., Rapid classification and quantification of Camellia (Camellia oleifera Abel.) oil blended with rapeseed oil using FTIR-ATR spectroscopy[J], Molecules, 25, 9, (2020)
[9] YANG K M, HSU F L, CHEN C W, Et al., Quality characterization and oxidative stability of Camellia seed oils produced with different roasting temperatures[J], Journal of Oleo Science, 67, 4, (2018)
[10] WIKTOROWSKA-OWCZAREK A, MALGORZATA B, NOWAK J Z., PUFAs:Structures, metabolism and functions[J], Advances in Clinical and Experimental Medicine, 24, 6, pp. 931-941, (2015)

← 1 2 3 4 →