结合两种藤本植物的 X 射线显微 CT 和显微镜图像,推导结构、机械和功能关系

IF 1.5 3区 生物学 Q4 EVOLUTIONARY BIOLOGY Plant Systematics and Evolution Pub Date : 2024-02-20 DOI:10.1007/s00606-024-01889-z
Claudine Karlen, Pascal Turberg, Alexandre Buttler, Océane Martin, Fritz Schweingruber, Anastasios P. Vassilopoulos
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引用次数: 0

摘要

本文介绍了对铁线莲和葡萄两种藤本植物茎的生物力学研究,调查了这两种藤本植物的机械性能,并试图加深对结构-功能关系的理解。调查包括对整个植物茎部进行机械测试,并辅以 X 射线微型计算机断层扫描(X 射线计算机断层扫描,体素尺寸为微米)成像和植物茎部染色横截面的二维显微图像,以推导出具有生物启发复合材料应用潜力的结构功能关系。显微 CT 图像与染色横截面显微图像进行了比较,以显示 X 射线显微 CT 方法与传统方法相比的优势和潜在缺点。利用微 CT 的高分辨率三维成像能力来解释机械测试得出的结构功能。根据显微 CT 图像得出的植物拓扑结构,建立了一个简单的有限元模型,并证明该模型足以精确地模拟植物的机械行为,并评估其结构差异的影响。这两种植物因其共同的生长形式而表现出不同的物理和机械特性(密度、强度和刚度)。解剖横截面观察和 X 射线显微 CT 可提供互补信息。第一种方法可以识别这些结构中木质化的部分,据说这些部分具有更强的机械抵抗力,而第二种方法则提供了一个完整的三维结构模型,虽然不够详细,但提供了密度对比的空间分布,据说这对植物的机械特性非常重要。所提出的方法为更好地理解植物复杂结构的机械行为以及从中汲取结构工程灵感开辟了新的视角。
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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Combining X-ray micro-CT and microscopy-based images of two lianas species to derive structural, mechanical and functional relationships

This paper presents a biomechanical study of stems of two liana species, Clematis vitalba and Vitis vinifera, investigates the mechanical performance of these two liana species and attempts to enhance the understanding of structure–function relationships. The investigation involved mechanical testing of whole plant stems, supplemented by X-ray micro-CT (X-ray computed tomography at micron voxel size) imaging and 2D microscopic images of stained cross sections of the plant stems, to derive structure–function relationships with potential for application in bioinspired composite materials. The micro-CT images were compared to the microscopic images of stained cross sections, in order to show benefits and potential drawbacks of the X-ray micro-CT method with respect to traditional methods. The high-resolution 3D imaging capacity of micro-CT is exploited to explain the structural functionality derived from the mechanical testing. A simple finite element model is developed based on the plant topology derived by the micro-CT images and proved accurate enough to model the plant’s mechanical behaviour and assess the influence of their structural differences. The two plants exhibit different to each other physical and mechanical properties (density, strength and stiffness) due to their common growth form. Anatomical cross-sectional observation and X-ray micro-CT provide complementary information. The first method allows the identification of the lignified parts, supposedly more resistant mechanically, of these structures, while the second one provides a full 3D model of the structure, admittedly less detailed but providing the spatial distribution of density contrasts supposed to be important in the mechanical properties of the plant. The proposed methodological approach opens new perspectives to better understand the mechanical behaviour of the complex structure of plants and to draw inspiration from it in structural engineering.

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来源期刊
Plant Systematics and Evolution
Plant Systematics and Evolution 生物-进化生物学
CiteScore
3.60
自引率
15.80%
发文量
37
审稿时长
1 months
期刊介绍: Plant Systematics and Evolution is an international journal dedicated to publication of peer-reviewed original papers and reviews on plant systematics in the broadest sense. The journal aims to bridge the specific subject areas in plant systematics and evolution, encompassing evolutionary, phylogenetic, genomic and biogeographical studies at the population and higher taxonomic levels. Taxonomic emphasis is on all land plant groups in a wide sense, including fungi and lichens.
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