Division of Safety Analysis, Experiment & Research Institute, National Agricultural Products Quality Management Service, Gimcheon 39660, Republic of Korea.
Environmental Microbial and Food Safety Laboratory, Agricultural Research Service, U.S. Department of Agriculture, Powder Mill Rd., Building 303 BARC-East, Beltsville, MD 20705, USA.
Toxins (Basel). 2023 Jul 22;15(7):472. doi: 10.3390/toxins15070472.
Aflatoxins and fumonisins, commonly found in maize and maize-derived products, frequently co-occur and can cause dangerous illness in humans and animals if ingested in large amounts. Efforts are being made to develop suitable analytical methods for screening that can rapidly detect mycotoxins in order to prevent illness through early detection. A method for classifying contaminated maize by applying hyperspectral imaging techniques including reflectance in the visible and near-infrared (VNIR) and short-wave infrared (SWIR) regions, and fluorescence was investigated. Machine learning classification models in combination with different preprocessing methods were applied to screen ground maize samples for naturally occurring aflatoxin and fumonisin as single contaminants and as co-contaminants. Partial least squares-discriminant analysis (PLS-DA) and support vector machine (SVM) with the radial basis function (RBF) kernel were employed as classification models using cut-off values of each mycotoxin. The classification performance of the SVM was better than that of PLS-DA, and the highest classification accuracies for fluorescence, VNIR, and SWIR were 89.1%, 71.7%, and 95.7%, respectively. SWIR imaging with the SVM model resulted in higher classification accuracies compared to the fluorescence and VNIR models, suggesting that as an alternative to conventional wet chemical methods, the hyperspectral SWIR imaging detection model may be the more effective and efficient analytical tool for mycotoxin analysis compared to fluorescence or VNIR imaging models. These methods represent a food safety screening tool capable of rapidly detecting mycotoxins in maize or other food ingredients consumed by animals or humans.
黄曲霉毒素和伏马菌素通常存在于玉米及其衍生产品中,如果大量摄入,会对人类和动物造成危险疾病。目前正在努力开发合适的分析方法,以筛选出能够快速检测真菌毒素的方法,从而通过早期检测来预防疾病。本研究应用可见近红外(VNIR)和短波近红外(SWIR)反射光谱以及荧光光谱的高光谱成像技术,研究了对受污染玉米进行分类的方法。采用不同的预处理方法结合机器学习分类模型,对地面玉米样本中的天然存在的黄曲霉毒素和伏马菌素单污染物以及共污染物进行了筛选。采用偏最小二乘判别分析(PLS-DA)和支持向量机(SVM)与径向基函数(RBF)核,作为分类模型,使用每种真菌毒素的截止值。SVM 的分类性能优于 PLS-DA,荧光、VNIR 和 SWIR 的最高分类准确率分别为 89.1%、71.7%和 95.7%。与荧光和 VNIR 模型相比,SWIR 成像与 SVM 模型相结合的分类准确率更高,这表明与传统的湿化学方法相比,高光谱 SWIR 成像检测模型可能是一种更有效的真菌毒素分析工具,比荧光或 VNIR 成像模型更高效。这些方法代表了一种食品安全筛选工具,能够快速检测玉米或其他动物或人类食用的食品成分中的真菌毒素。
