Early Discrimination and Prediction of -Infected Sweetpotatoes During the Asymptomatic Period Using Electronic Nose

Overview

Journal Foods

Specialty Biotechnology

Date 2022 Jul 9

PMID 35804741

Authors

Jiawen Wu

Linjiang Pang

Xiaoqiong Zhang

Xinghua Lu

Liqing Yin

Guoquan Lu

Jiyu Cheng

Affiliations

Soon will be listed here.

Abstract

Sweetpotato is prone to disease caused by without obvious lesions on the surface in the early period of infection. Therefore, it is necessary to explore the possibility of developing an efficient early disease detection method for sweetpotatoes that can be used before symptoms are observed. In this study, sweetpotatoes were inoculated with and stored for different lengths of time. The total colony count was detected every 8 h; HS-SPME/GC-MS and E-nose were used simultaneously to detect volatile compounds. The results indicated that the growth of entered the exponential phase at 48 h, resulting in significant differences in concentrations of volatile compounds in infected sweetpotatoes at different times, especially toxic ipomeamarone in ketones. The contents of volatile compounds were related to the responses of the sensors. E-nose was combined with multiple chemometrics methods to discriminate and predict infected sweetpotatoes at 0 h, 48 h, 64 h, and 72 h. Among the methods used, linear discriminant analysis (LDA) had the best discriminant effect, with sensitivity, specificity, precision, and accuracy scores of 100%. E-nose combined with K-nearest neighbours (KNN) achieved the best predictions for ipomeamarone contents and total colony counts. This study illustrates that E-nose is a feasible and promising technology for the early detection of infection in sweetpotatoes during the asymptomatic period.

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