Non-Destructive Assessment of Microbial Spoilage of Broiler Breast Meat Using Structured Illumination Reflectance Imaging with Machine Learning

IF 2.6 3区 农林科学 Q2 FOOD SCIENCE & TECHNOLOGY
Ebenezer O. Olaniyi, Yuzhen Lu, Xin Zhang, Anuraj T. Sukumaran, Hudson T. Thames, Diksha Pokhrel
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引用次数: 0

Abstract

Meat quality has gained ample attention owing to increased consumer awareness and competition among poultry processors to deliver premium quality products. Nevertheless, chicken breast meat is susceptible to microbial spoilage resulting in economic and product losses. Conventional approaches such as organoleptic, aerobic plate count (APC), and molecular methods have been employed for assessing the microbiological quality of meat products but suffer various shortcomings. This study was a proof-of-concept evaluation of emerging structured illumination reflectance imaging (SIRI) as a non-destructive, objective means to evaluate microbial spoilage in chicken breast meat. The experimental chicken breast samples were kept on a retail tray for 1–13 days at 3-day intervals and subjected to image acquisition by broadband SIRI at varied spatial frequencies of sinusoidally-modulated structured illumination (0.05–0.40 cycles mm−1). The chicken samples were categorized into fresh and spoiled classes using the APC threshold of 5 log10 CFU g−1. Acquired pattern images were demodulated into amplitude component (AC) and direct component (DC) images (corresponding to uniform illumination). Three pre-trained deep learning models, including VGG16, EfficientNetB6, and ResNeXt101, were employed to extract the features from the demodulated images, followed by principal component analysis (PCA) to reduce feature redundancy. The selected PCs were used to build classification models using linear discriminant analysis (LDA) and support vector machine (SVM) separately to distinguish between fresh and spoiled samples. AC images consistently outperformed DC images in the resultant classification performance. When the LDA classifier was used, AC images yielded maximum accuracy improvements of 3.6%–6%, depending on feature type and spatial frequency; with the SVM classifier, AC images achieved maximum improvements of 4.4% to 6.4%. The SVM model with the features extracted by ResNeXt101 from AC images at 0.25 cycles mm−1 achieved the best overall classification accuracy of 76% in differentiating fresh and spoiled samples. This study shows that the SIRI technique is effective for enhanced assessment of microbial spoilage in broiler breast meat, but more dedicated efforts are needed to improve both hardware and software for practical application.

Abstract Image

Abstract Image

利用机器学习的结构光反射成像技术对肉鸡胸脯肉的微生物腐败进行非破坏性评估
由于消费者意识的提高以及家禽加工商之间为提供优质产品而展开的竞争,肉类质量受到了广泛关注。然而,鸡胸肉很容易受到微生物腐败的影响,从而造成经济和产品损失。人们采用感官、需氧平板计数(APC)和分子方法等传统方法来评估肉制品的微生物质量,但这些方法存在各种缺陷。本研究对新兴的结构光反射成像(SIRI)进行了概念验证评估,将其作为一种非破坏性的客观方法来评估鸡胸肉中的微生物腐败情况。实验用的鸡胸肉样品在零售托盘上放置 1-13 天,每隔 3 天进行一次检测,并通过宽带 SIRI 在不同空间频率的正弦调制结构光(0.05-0.40 周期 mm-1)下进行图像采集。使用 5 log10 CFU g-1 的 APC 阈值将鸡肉样品分为新鲜和变质两类。获取的模式图像被解调为振幅分量(AC)和直接分量(DC)图像(对应于均匀照明)。采用三种预先训练好的深度学习模型(包括 VGG16、EfficientNetB6 和 ResNeXt101)从解调图像中提取特征,然后进行主成分分析(PCA)以减少特征冗余。利用选定的主成分,分别使用线性判别分析(LDA)和支持向量机(SVM)建立分类模型,以区分新鲜和变质样品。在结果分类性能方面,AC 图像始终优于 DC 图像。使用 LDA 分类器时,AC 图像的最大准确率提高了 3.6%-6%,具体取决于特征类型和空间频率;使用 SVM 分类器时,AC 图像的最大准确率提高了 4.4%-6.4%。使用 ResNeXt101 从 0.25 周期 mm-1 的 AC 图像中提取的特征的 SVM 模型在区分新鲜和变质样品方面取得了 76% 的最佳总体分类准确率。这项研究表明,SIRI 技术能有效地增强肉鸡胸脯肉微生物腐败的评估,但还需要更多的努力来改进硬件和软件,以便实际应用。
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来源期刊
Food Analytical Methods
Food Analytical Methods 农林科学-食品科技
CiteScore
6.00
自引率
3.40%
发文量
244
审稿时长
3.1 months
期刊介绍: Food Analytical Methods publishes original articles, review articles, and notes on novel and/or state-of-the-art analytical methods or issues to be solved, as well as significant improvements or interesting applications to existing methods. These include analytical technology and methodology for food microbial contaminants, food chemistry and toxicology, food quality, food authenticity and food traceability. The journal covers fundamental and specific aspects of the development, optimization, and practical implementation in routine laboratories, and validation of food analytical methods for the monitoring of food safety and quality.
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