Virgin olive oil volatile fingerprint and chemometrics: Towards an instrumental screening tool to grade the sensory quality

Sensory quality, assessed following a standardized method, is one of the parameters defining the commercial category of virgin olive oil. Considering the difficulties linked to the organoleptic evaluation, especially the high number of samples to be assessed, setting up instrumental methods to suppo...

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Published in:Food science & technology 2020-03, Vol.121, p.108936, Article 108936
Main Authors: Quintanilla-Casas, Beatriz, Bustamante, Julen, Guardiola, Francesc, García-González, Diego Luís, Barbieri, Sara, Bendini, Alessandra, Toschi, Tullia Gallina, Vichi, Stefania, Tres, Alba
Format: Article
Language:English
Subjects:
Fingerprint
HS-SPME-GC-MS
Olive oil
Sensory quality
Volatile compounds
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Summary:Sensory quality, assessed following a standardized method, is one of the parameters defining the commercial category of virgin olive oil. Considering the difficulties linked to the organoleptic evaluation, especially the high number of samples to be assessed, setting up instrumental methods to support sensory panels becomes a need for the olive oil sector. Volatile fingerprint by Headspace Solid Phase Microextraction-Gas Chromatography-Mass Spectrometry can be an excellent fit-for-purpose tool as the volatile fraction is responsible for virgin olive oil sensory attributes. A fingerprinting approach was applied to the volatile profile of 176 virgin olive oils previously graded by six official sensory panels. The classification strategy consisted in two sequential Partial Least Square-Discriminant Analysis models built with the aligned chromatograms: the first discriminated extra virgin and non-extra virgin samples; the second classified the latter into virgin or lampante categories. Results were satisfactory in the cross-validation by leave 10%-out (97% of correct classification). For external validation, an uncertainty range was set for the prediction models to detect boundary samples, which would be further assessed by the sensory panels. By doing this, a considerable decrease of the panel workload (around 80%) was achieved, while maintaining a highly reliable classification of samples (error rate
ISSN:0023-6438
1096-1127
DOI:10.1016/j.lwt.2019.108936