植物科学中的实验室微探针X射线荧光：新兴应用与案例研究

Laboratory Microprobe X-Ray Fluorescence in Plant Science: Emerging Applications and Case Studies.

作者信息

Rodrigues Eduardo S, Gomes Marcos H F, Duran Nádia M, Cassanji João G B, da Cruz Tatiana N M, Sant'Anna Neto Analder, Savassa Susilaine M, de Almeida Eduardo, Carvalho Hudson W P

机构信息

Nuclear Instrumentation Laboratory, Center for Nuclear Energy in Agriculture, University of São Paulo, Piracicaba, Brazil.

Physiology of Trees Laboratory, Department of Forest Science, College of Agriculture Luiz de Queiroz, University of São Paulo, Piracicaba, Brazil.

出版信息

Front Plant Sci. 2018 Nov 14;9:1588. doi: 10.3389/fpls.2018.01588. eCollection 2018.

DOI:10.3389/fpls.2018.01588

PMID:30487802

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6246888/

Abstract

and micro chemical analytical methods have the potential to improve our understanding of plant metabolism and development. Benchtop microprobe X-ray fluorescence spectroscopy (μ-XRF) presents a huge potential for facing this challenge. Excitation beams of 30 μm and 1 mm in diameter were employed to address questions in seed technology, phytopathology, plant physiology, and bioremediation. Different elements were analyzed in several situations of agronomic interest: (i) Examples of μ-XRF yielding quantitative maps that reveal the spatial distribution of zinc in common beans () primed seeds. (ii) Chemical images daily recorded at a soybean leaf () infected by anthracnose showed that phosphorus, sulfur, and calcium trended to concentrate in the disease spot. (iii) measurements at the stem of showed that under root exposure, manganese is absorbed and transported nearly 10-fold faster than iron. (iv) Quantitative maps showed that the lead distribution in a leaf of hybrid was not homogenous, this element accumulated mainly in the leaf border and midrib, the lead hotspots reached up to 13,400 mg lead kg fresh tissue weight. These case studies highlight the ability of μ-XRF in performing qualitative and quantitative elemental analysis of fresh and living plant tissues. Thus, it can probe dynamic biological phenomena non-destructively and in real time.

摘要

而微量化学分析方法有潜力增进我们对植物代谢和发育的理解。台式微探针X射线荧光光谱法（μ-XRF）在应对这一挑战方面具有巨大潜力。使用直径为30μm和1mm的激发光束来解决种子技术、植物病理学、植物生理学和生物修复方面的问题。在几种具有农学意义的情况下分析了不同元素：（i）μ-XRF产生定量图谱的例子，揭示了普通菜豆（）引发种子中锌的空间分布。（ii）每天在受炭疽病感染的大豆叶片（）上记录的化学图像显示，磷、硫和钙倾向于在病斑中集中。（iii）在的茎上进行的测量表明，在根部暴露的情况下，锰的吸收和运输速度比铁快近10倍。（iv）定量图谱显示，杂交种叶片中的铅分布不均匀，该元素主要积累在叶边缘和叶脉中，铅热点高达13400mg铅/千克鲜组织重量。这些案例研究突出了μ-XRF对新鲜和活植物组织进行定性和定量元素分析的能力。因此，它可以无损且实时地探测动态生物现象。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e082/6246888/94e25c8e2e55/fpls-09-01588-g001.jpg

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植物科学中的实验室微探针X射线荧光：新兴应用与案例研究

Laboratory Microprobe X-Ray Fluorescence in Plant Science: Emerging Applications and Case Studies.

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