Novel, Rapid Identification, and Quantification of Adulterants in Extra Virgin Olive Oil Using Near‐Infrared Spectroscopy and Chemometrics

Azizian, Hormoz; Mossoba, Magdi M.; Fardin‐Kia, Ali Reza; Delmonte, Pierluigi; Karunathilaka, Sanjeewa R.; Kramer, J. K. G.

doi:10.1007/s11745-015-4038-4

Cited by 57 publications

(122 citation statements)

References 28 publications

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“…The comparison of FT‐NIR spectra for authentic EVOO and adulterant oils in the 5150 to 5350 cm −1 range revealed the presence of significant spectral differences (Figure ), as was first reported by Azizian and others (). In particular, significant intensity variation was observed for the weak feature near 5280 cm −1 attributed to the second overtone of the C═O stretching vibration.…”

Section: Resultssupporting

confidence: 77%

“…No 25 Global Method for the detection of extraneous oils in olive oils (IOC ). In addition, all the reference EVOO products used in the present study were found to be authentic based on our published FT‐NIR and PLS procedure (Azizian and others ). The CI analysis and the SIMCA classification model were validated using 3 sample sets consisted of the following: (1) 10 Adulterant oils consisting of 9 vegetable oils obtained from local grocery stores, and a palm olein sample that was purchased from a local store in Indonesia, (2) 20 Test mixtures prepared with one of the authentic EVOO, namely California sample S9, that was spiked with 10% and 20% (w/w) of each of the 10 adulterants, and (3) an additional set of 7 randomly selected authentic EVOO samples acquired from California.…”

Section: Methodsmentioning

confidence: 80%

“…However, for commercial EVOO products where the identity of a potential adulterant is unknown, the authors proposed that calibration models would have to be developed for each pair of olive oil and suspected adulterant oil (Christy and others ). Recently, a novel FT‐NIR and partial least squares (PLS) methodology was proposed for the rapid prediction of the identity and concentration of a refined olive oil or an adulterant oil (such as an oil high in oleic acid or linoleic acid, or consisting of palm olein) mixed with an EVOO (Azizian and others ).…”

Section: Introductionmentioning

confidence: 99%

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Nontargeted, Rapid Screening of Extra Virgin Olive Oil Products for Authenticity Using Near‐Infrared Spectroscopy in Combination with Conformity Index and Multivariate Statistical Analyses

Karunathilaka

Kia

Srigley

et al. 2016

Journal of Food Science

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A rapid tool for evaluating authenticity was developed and applied to the screening of extra virgin olive oil (EVOO) retail products by using Fourier-transform near infrared (FT-NIR) spectroscopy in combination with univariate and multivariate data analysis methods. Using disposable glass tubes, spectra for 62 reference EVOO, 10 edible oil adulterants, 20 blends consisting of EVOO spiked with adulterants, 88 retail EVOO products and other test samples were rapidly measured in the transmission mode without any sample preparation. The univariate conformity index (CI) and the multivariate supervised soft independent modeling of class analogy (SIMCA) classification tool were used to analyze the various olive oil products which were tested for authenticity against a library of reference EVOO. Better discrimination between the authentic EVOO and some commercial EVOO products was observed with SIMCA than with CI analysis. Approximately 61% of all EVOO commercial products were flagged by SIMCA analysis, suggesting that further analysis be performed to identify quality issues and/or potential adulterants. Due to its simplicity and speed, FT-NIR spectroscopy in combination with multivariate data analysis can be used as a complementary tool to conventional official methods of analysis to rapidly flag EVOO products that may not belong to the class of authentic EVOO.

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Section: Resultssupporting

confidence: 77%

Section: Methodsmentioning

confidence: 80%

Section: Introductionmentioning

confidence: 99%

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Nontargeted, Rapid Screening of Extra Virgin Olive Oil Products for Authenticity Using Near‐Infrared Spectroscopy in Combination with Conformity Index and Multivariate Statistical Analyses

Karunathilaka

Kia

Srigley

et al. 2016

Journal of Food Science

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“…However, due to it was local specialty, few reports about the detection of camellia oil adulteration by NIR were found. Some adulteration detection for olive oil could be treated as references, [19][20][21] as the similarities of camellia oil with olive oil in physical and chemical constants.…”

Section: Introductionmentioning

confidence: 99%

Identifying camellia oil adulteration with selected vegetable oils by characteristic near-infrared spectral regions

Chu

Wang

et al. 2018

J. Innov. Opt. Health Sci.

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In this paper, a methodology based on characteristic spectral bands of near infrared spectroscopy (1000-2500 nm) and multivariate analysis was proposed to identify camellia oil adulteration with vegetable oils. Sun°ower, peanut and corn oils were selected to conduct the test. Pure camellia oil and that adulterated with varying concentrations (1-10% with the gradient of 1%, 10-40% with the gradient of 5%, 40-100% with the gradient of 10%) of each type of the three vegetable oils were prepared, respectively. For each type of adulterated oil, full-spectrum partial least squares partial least squares (PLS) models and synergy interval partial least squares (SI-PLS) models were developed. Parameters of these models were optimized simultaneously by cross-validation. The SI-PLS models were proved to be better than the full-spectrum PLS models. In SI-PLS models, the correlation coe±cients of predition set (Rp) were 0.9992, 0.9998 and 0.9999 for adulteration with sun°ower oil, peanut oil and corn oil seperately; the corresponding root mean square errors of prediction set (RMSEP) were 1.23, 0.66 and 0.37. Furthermore, a new generic PLS model was built based on the characteristic spectral regions selected from the intervals of the three SI-PLS models to identify the oil adulterants, regardless of the adultrated oil types. The model achieved with Rp¼ 0.9988 and RMSEP ¼ 1.52. These results indicated that the characteristic near infrared spectral regions could determine the level of adulteration in the camellia oil.

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“…Raman spectroscopy and near-infrared spectroscopy (NIR) are two promising analytical techniques being investigated as screening tools to identify EMA in food products (Baeten et al 2005; Kasemsumran et al 2007; Cheng et al 2010; Moore et al 2012b; Azizian et al 2015). Common benefits of these two methods, compared with other technologies such as LC-MS/MS (MacMahon et al 2012), ELISA (Moatsou & Anifantakis 2003) and GC-MS/MS (Hong et al 2009), include simplicity, limited need for sample pre-treatment, rapid measurements, rugged instrumentation, portable systems availability and high-throughput analysis.…”

Section: Introductionmentioning

confidence: 99%

Characterising variances of milk powder and instrumentation for the development of a non-targeted, Raman spectroscopy and chemometrics detection method for the evaluation of authenticity

Karunathilaka

Farris

Mossoba

et al. 2016

Food Additives & Contaminants: Part A

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There is a need to develop rapid tools to screen milk products for economically motivated adulteration. An understanding of the physiochemical variability within skim milk powder (SMP) and non-fat dry milk (NFDM) is the key to establishing the natural differences of these commodities prior to the development of non-targeted detection methods. This study explored the sources of variance in 71 commercial SMP and NFDM samples using Raman spectroscopy and principal component analysis (PCA) and characterised the largest number of commercial milk powders acquired from a broad number of international manufacturers. Spectral pre-processing using a gap-segment derivative transformation (gap size = 5, segment width = 9, fourth derivative) in combination with sample normalisation was necessary to reduce the fluorescence background of the milk powder samples. PC scores plots revealed no clear trends for various parameters, including day of analysis, powder type, supplier and processing temperatures, while the largest variance was due to irreproducibility in sample positioning. Significant chemical sources of variances were explained by using the spectral features in the PC loadings plots where four samples from the same manufacturer were determined to likely contain an additional component or lactose anomers, and one additional sample was identified as an outlier and likely containing an adulterant or differing quality components. The variance study discussed herein with this large, diverse set of milk powders holds promise for future use as a non-targeted screening method that could be applied to commercial milk powders.

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Novel, Rapid Identification, and Quantification of Adulterants in Extra Virgin Olive Oil Using Near‐Infrared Spectroscopy and Chemometrics

Cited by 57 publications

References 28 publications

Nontargeted, Rapid Screening of Extra Virgin Olive Oil Products for Authenticity Using Near‐Infrared Spectroscopy in Combination with Conformity Index and Multivariate Statistical Analyses

Nontargeted, Rapid Screening of Extra Virgin Olive Oil Products for Authenticity Using Near‐Infrared Spectroscopy in Combination with Conformity Index and Multivariate Statistical Analyses

Identifying camellia oil adulteration with selected vegetable oils by characteristic near-infrared spectral regions

Characterising variances of milk powder and instrumentation for the development of a non-targeted, Raman spectroscopy and chemometrics detection method for the evaluation of authenticity

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