Advancing hyperspectral imaging techniques for root systems: a new pipeline for macro- and microscale image acquisition and classification.

IF 4.7 2区生物学 Q1 BIOCHEMICAL RESEARCH METHODS

Plant Methods Pub Date : 2024-11-11 DOI:10.1186/s13007-024-01297-x

Corine Faehn, Grzegorz Konert, Markku Keinänen, Katja Karppinen, Kirsten Krause

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引用次数: 0

Abstract

Background: Understanding the environmental impacts on root growth and root health is essential for effective agricultural and environmental management. Hyperspectral imaging (HSI) technology provides a non-destructive method for detailed analysis and monitoring of plant tissues and organ development, but unfortunately examples for its application to root systems and the root-soil interface are very scarce. There is also a notable lack of standardized guidelines for image acquisition and data analysis pipelines.

Methods: This study investigated HSI techniques for analyzing rhizobox-grown root systems across various imaging configurations, from the macro- to micro-scale, using the imec VNIR SNAPSCAN camera. Focusing on three graminoid species with different root architectures allowed us to evaluate the influence of key image acquisition parameters and data processing techniques on the differentiation of root, soil, and root-soil interface/rhizosheath spectral signatures. We compared two image classification methods, Spectral Angle Mapper (SAM) and K-Means clustering, and two machine learning approaches, Random Forest (RF) and Support Vector Machine (SVM), to assess their efficiency in automating root system image classification.

Results: Our study demonstrated that training a RF model using SAM classifications, coupled with wavelength reduction using the second derivative spectra with Savitzky-Golay (SG) smoothing, provided reliable classification between root, soil, and the root-soil interface, achieving 88-91% accuracy across all configurations and scales. Although the root-soil interface was not clearly resolved, it helped to improve the distinction between root and soil classes. This approach effectively highlighted spectral differences resulting from the different configurations, image acquisition settings, and among the three species. Utilizing this classification method can facilitate the monitoring of root biomass and future work investigating root adaptations to harsh environmental conditions.

Conclusions: Our study addressed the key challenges in HSI acquisition and data processing for root system analysis and lays the groundwork for further exploration of VNIR HSI application across various scales of root system studies. This work provides a full data analysis pipeline that can be utilized as an online Python-based tool for the semi-automated analysis of root-soil HSI data.

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推进根系的高光谱成像技术：宏观和微观图像采集与分类的新管道。

背景：了解环境对根系生长和根系健康的影响对于有效的农业和环境管理至关重要。高光谱成像（HSI）技术为植物组织和器官发育的详细分析和监测提供了一种非破坏性方法，但遗憾的是，将其应用于根系和根-土界面的实例非常少。在图像采集和数据分析管道方面也明显缺乏标准化指南：本研究使用 imec VNIR SNAPSCAN 相机，通过从宏观到微观的各种成像配置，研究了用于分析根瘤生长根系的恒星成像技术。我们以具有不同根系结构的三种禾本科植物为重点，评估了关键图像采集参数和数据处理技术对区分根系、土壤和根-土界面/根鞘光谱特征的影响。我们比较了两种图像分类方法--光谱角度绘图仪（SAM）和 K-Means 聚类，以及两种机器学习方法--随机森林（RF）和支持向量机（SVM），以评估它们在自动进行根系图像分类方面的效率：我们的研究表明，使用 SAM 分类训练 RF 模型，再加上使用萨维茨基-戈莱（SG）平滑的二阶导光谱进行波长缩减，可以对根、土壤和根-土壤界面进行可靠的分类，在所有配置和尺度下的准确率达到 88-91%。虽然根-土壤界面没有得到清晰的分辨，但它有助于改进根与土壤类别之间的区分。这种方法有效地突出了不同配置、图像采集设置以及三个物种之间的光谱差异。利用这种分类方法可以促进对根部生物量的监测，以及未来研究根部对恶劣环境条件适应性的工作：我们的研究解决了根系分析中 HSI 采集和数据处理的关键难题，为进一步探索 VNIR HSI 在不同规模根系研究中的应用奠定了基础。这项工作提供了一个完整的数据分析管道，可用作基于 Python 的在线工具，对根系-土壤 HSI 数据进行半自动化分析。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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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.