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一种利用新兴光学技术和人工智能的方法带来了评估花生种子质量的新指标。

An Approach Using Emerging Optical Technologies and Artificial Intelligence Brings New Markers to Evaluate Peanut Seed Quality.

作者信息

Fonseca de Oliveira Gustavo Roberto, Mastrangelo Clíssia Barboza, Hirai Welinton Yoshio, Batista Thiago Barbosa, Sudki Julia Marconato, Petronilio Ana Carolina Picinini, Crusciol Carlos Alexandre Costa, Amaral da Silva Edvaldo Aparecido

机构信息

Department of Crop Science, College of Agricultural Sciences, São Paulo State University, Botucatu, Brazil.

Laboratory of Radiobiology and Environment, Center for Nuclear Energy in Agriculture, University of São Paulo, Piracicaba, Brazil.

出版信息

Front Plant Sci. 2022 Apr 14;13:849986. doi: 10.3389/fpls.2022.849986. eCollection 2022.

DOI:10.3389/fpls.2022.849986
PMID:35498679
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9048030/
Abstract

Seeds of high physiological quality are defined by their superior germination capacity and uniform seedling establishment. Here, it was investigated whether multispectral images combined with machine learning models can efficiently categorize the quality of peanut seedlots. The seed quality from seven lots was assessed traditionally (seed weight, water content, germination, and vigor) and by multispectral images (area, length, width, brightness, chlorophyll fluorescence, anthocyanin, and reflectance: 365 to 970 nm). Seedlings from the seeds of each lot were evaluated for their photosynthetic capacity (fluorescence and chlorophyll index, F, F, and F/F) and stress indices (anthocyanin and NDVI). Artificial intelligence features (QDA method) applied to the data extracted from the seed images categorized lots with high and low quality. Higher levels of anthocyanin were found in the leaves of seedlings from low quality seeds. Therefore, this information is promising since the initial behavior of the seedlings reflected the quality of the seeds. The existence of new markers that effectively screen peanut seed quality was confirmed. The combination of physical properties (area, length, width, and coat brightness), pigments (chlorophyll fluorescence and anthocyanin), and light reflectance (660, 690, and 780 nm), is highly efficient to identify peanut seedlots with superior quality (98% accuracy).

摘要

高生理质量的种子由其卓越的发芽能力和均匀的幼苗建立来定义。在此,研究了多光谱图像与机器学习模型相结合是否能有效地对花生种子批次的质量进行分类。通过传统方法(种子重量、含水量、发芽率和活力)以及多光谱图像(面积、长度、宽度、亮度、叶绿素荧光、花青素和反射率:365至970纳米)对七个批次的种子质量进行了评估。对每个批次种子的幼苗进行了光合能力(荧光和叶绿素指数,F、F以及F/F)和胁迫指数(花青素和归一化植被指数)的评估。应用于从种子图像中提取的数据的人工智能特征(QDA方法)对高质量和低质量的批次进行了分类。在低质量种子的幼苗叶片中发现了较高水平的花青素。因此,由于幼苗的初始行为反映了种子的质量,这一信息很有前景。证实了存在能有效筛选花生种子质量的新标记。物理特性(面积、长度、宽度和种皮亮度)、色素(叶绿素荧光和花青素)和光反射率(660、690和780纳米)的组合,在识别优质花生种子批次方面效率很高(准确率98%)。

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