3D-CNN detection of systemic symptoms induced by different Potexvirus infections in four Nicotiana benthamiana genotypes using leaf hyperspectral imaging.

IF 4.7 2区生物学 Q1 BIOCHEMICAL RESEARCH METHODS

Plant Methods Pub Date : 2025-02-10 DOI:10.1186/s13007-025-01337-0

Rizos-Theodoros Chadoulis, Ioannis Livieratos, Ioannis Manakos, Theodore Spanos, Zeinab Marouni, Christos Kalogeropoulos, Constantine Kotropoulos

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Abstract

Purpose: Hyperspectral imaging combined with machine learning offers a promising, cost-effective alternative to invasive chemical analysis for early plant disease detection. In this study, the use of 3D Convolutional Neural Networks (3D-CNNs) was explored to detect presymptomatic viral infections in the model plant Nicotiana benthamiana L. and assess the generalization of these models across different plant genotypes.

Methods: Four genotypes of Nicotiana benthamiana L. (wild-type, DCL2/4, AGO2, and NahG) were inoculated with different potexviruses (PepMV mild or severe strain, PVX, BaMV). Viral infection was verified via northern blot analysis at 5 and 10 days post inoculation (DPI). Hyperspectral images were captured over 10 days following inoculation, focusing on the top 3 leaves where symptoms typically appear. The dataset was carefully processed to remove errors, and raster masks were generated to isolate only the leaf pixels. The Extremely Randomized Trees algorithm was used for Effective Wavelength selection, and a novel 3D-CNN architecture was developed to classify $16 \times 16 \times 16$ nonoverlapping cubes extracted from the unmasked leaf surfaces. The aim was to classify each cube into healthy or diseased for each of the four viruses at different time points.

Results: Accuracies of $0.78$ - $0.87$ were achieved for AGO2 mutants at the cube level, and overall plant-level accuracies of $0.68$ - $0.89$ . The model's generalization capabilities were tested across other genotypes, yielding accuracies of up to $0.75$ for DCL2/4, $0.83$ for NahG, and $0.78$ for the wild-type. The timing of disease detection was also assessed, finding that accuracies approached 0.8 as early as $6$ - $8$ DPI depending on the virus. The results were validated against northern blot analyses and benchmarked against another state-of-the-art methodology for Nicotiana benthamiana viral infections, achieving superior overall classification accuracies.

Conclusion: The proposed patch-based method demonstrated key advantages: (a) exploiting both spectral and textural information, (b) deriving a large training dataset from few hyperspectral images, (c) providing localized classification explainability within leaf regions, and (d) achieving high accuracy for early detection of viral infections.

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利用叶片高光谱成像3D-CNN检测四种本烟基因型中不同Potexvirus感染引起的全身症状

目的：高光谱成像与机器学习相结合，为早期植物病害检测提供了一种有前途的、具有成本效益的替代侵入性化学分析方法。在这项研究中，利用3D卷积神经网络（3D- cnn）来检测模式植物烟叶（Nicotiana benthamiana L.）症状前病毒感染，并评估这些模型在不同植物基因型中的泛化性。方法：将4种基因型（野生型、DCL2/4型、AGO2型和NahG型）接种不同的痘病毒（PepMV轻、重度株、PVX、BaMV）。接种后5和10天（DPI）通过northern blot分析证实病毒感染。接种后10天拍摄高光谱图像，集中在症状通常出现的前3片叶子上。对数据集进行仔细处理以消除错误，并生成栅格掩码以仅隔离叶子像素。采用极端随机树算法进行有效波长选择，并开发了一种新的3D-CNN架构，对从未遮挡的叶子表面提取的16 × 16 × 16个非重叠立方体进行分类。目的是在不同的时间点将每个立方体分为健康或患病的四种病毒。结果：AGO2突变体在立方体水平上的准确度为0.78 ~ 0.87，整体植株水平的准确度为0.68 ~ 0.89。该模型的泛化能力在其他基因型中进行了测试，DCL2/4的准确率高达0.75，NahG的准确率为0.83，野生型的准确率为0.78。还对疾病检测时间进行了评估，发现根据病毒的不同，早在6 - 8 DPI时，准确率就接近0.8。结果通过northern blot分析验证，并与另一种最先进的benthamiana病毒感染方法进行基准测试，实现了卓越的总体分类准确性。结论：提出的基于斑块的方法具有以下几个关键优势：(a)利用光谱和纹理信息；(b)从少量高光谱图像中获得大型训练数据集；(c)在叶片区域内提供局部分类的可解释性；(d)在病毒感染的早期检测中实现高精度。

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来源期刊

Plant Methods 生物-植物科学

CiteScore

9.20

自引率

3.90%

发文量

121

审稿时长

2 months

期刊介绍： Plant Methods is an open access, peer-reviewed, online journal for the plant research community that encompasses all aspects of technological innovation in the plant sciences. There is no doubt that we have entered an exciting new era in plant biology. The completion of the Arabidopsis genome sequence, and the rapid progress being made in other plant genomics projects are providing unparalleled opportunities for progress in all areas of plant science. Nevertheless, enormous challenges lie ahead if we are to understand the function of every gene in the genome, and how the individual parts work together to make the whole organism. Achieving these goals will require an unprecedented collaborative effort, combining high-throughput, system-wide technologies with more focused approaches that integrate traditional disciplines such as cell biology, biochemistry and molecular genetics. Technological innovation is probably the most important catalyst for progress in any scientific discipline. Plant Methods’ goal is to stimulate the development and adoption of new and improved techniques and research tools and, where appropriate, to promote consistency of methodologies for better integration of data from different laboratories.