基于近红外高光谱成像光谱和化学计量学的豌豆根瘤中血红蛋白含量的定量研究

Q3 Chemistry

Journal of Spectral Imaging Pub Date : 2018-06-14 DOI:10.1255/JSI.2018.A9

Damien Eylenbosch, B. Dumont, V. Baeten, B. Bodson, P. Delaplace, J. Pierna

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引用次数: 3

摘要

根瘤中的血红蛋白含量与豆类-根瘤共生体固定的氮含量密切相关。因此，通常测量它是为了评估生长促进参数（如施肥）对豆类共生固氮效率的影响。氰甲血红蛋白法是腿血红蛋白含量定量的一种参考方法，但该方法耗时，需要准确细致的技术操作，并且使用有毒试剂氰化物。作为一种更快、更简单、无损的替代方法，测试了一种基于近红外（NIR）高光谱成像的方法来量化干燥结节中的腿血红蛋白。评估了两种方法：（i）将偏最小二乘（PLS）方法应用于高光谱设备获取的全光谱；（ii）还通过预选最相关的波长和建立多元线性回归模型来测试多光谱成像的潜力。PLS方法在从含有几个结节的样本中获得的平均光谱上进行了测试，并从单个结节中单独获得。豌豆（Pisumsativum L.）是在温室里栽培的。在四个不同的日期采集结节，以获得腿血红蛋白含量的变化。用氰甲血红蛋白法在新鲜结节中测量的腿血红蛋白含量在1.4至4.2 mg腿血红蛋白g-1新鲜结节之间。PLS回归模型是在用参考方法测量的血红蛋白含量和用高光谱成像设备获得的干结节的平均近红外光谱上进行校准的。在验证数据集上，PLS模型很好地预测了结节样品中的腿血红蛋白含量（R2=0.90，预测的均方根误差=0.26）。多光谱方法显示出类似的性能。应用于单个结节，PLS模型强调了从同一植物收获的模块中腿血红蛋白含量的广泛可变性。这些结果表明，近红外高光谱成像可以作为一种快速、安全的方法来定量豌豆结节中的血红蛋白。

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Quantification of leghaemoglobin content in pea nodules based on near infrared hyperspectral imaging spectroscopy and chemometrics

Leghaemoglobin content in nodules is closely related to the amount of nitrogen fixed by the legume–rhizobium symbiosis. It is, therefore, commonly measured in order to assess the effect of growth-promoting parameters such as fertilisation on the symbiotic nitrogen fixation efficiency of legumes. The cyanmethaemoglobin method is a reference method in leghaemoglobin content quantification, but this method is time-consuming, requires accurate and careful technical operations and uses cyanide, a toxic reagent. As a quicker, simpler and non-destructive alternative, a method based on near infrared (NIR) hyperspectral imaging was tested to quantify leghaemoglobin in dried nodules. Two approaches were evaluated: (i) the partial least squares (PLS) approach was applied to the full spectrum acquired with the hyperspectral device and (ii) the potential of multispectral imaging was also tested through the preselection of the most relevant wavelengths and the building of a multiple linear regression model. The PLS approach was tested on mean spectra acquired from samples containing several nodules and acquired separately from individual nodules. Peas (Pisum sativum L.) were cultivated in a greenhouse. The nodules were harvested on four different dates in order to obtain variations in leghaemoglobin content. The leghaemoglobin content measured with the cyanmethaemoglobin method in fresh nodules ranged between 1.4 and 4.2 mg leghaemoglobin g–1 fresh nodule. A PLS regression model was calibrated on leghaemoglobin content measured with the reference method and mean NIR spectra of dried nodules acquired with a hyperspectral imaging device. On a validation dataset, the PLS model predicted the leghaemoglobin content in nodule samples well (R2 = 0.90, root mean square error of prediction = 0.26). The multispectral approach showed similar performance. Applied to individual nodules, the PLS model highlighted a wide variability of leghaemoglobin content in nodules harvested from the same plant. These results show that NIR hyperspectral imaging could be used as a rapid and safe method to quantify leghaemoglobin in pea nodules.

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来源期刊

Journal of Spectral Imaging Chemistry-Analytical Chemistry

CiteScore

3.90

自引率

0.00%

发文量

审稿时长

22 weeks

期刊介绍： JSI—Journal of Spectral Imaging is the first journal to bring together current research from the diverse research areas of spectral, hyperspectral and chemical imaging as well as related areas such as remote sensing, chemometrics, data mining and data handling for spectral image data. We believe all those working in Spectral Imaging can benefit from the knowledge of others even in widely different fields. We welcome original research papers, letters, review articles, tutorial papers, short communications and technical notes.