Structural diversity of crustacean exoskeletons and its implications for biomimetics

IF 3.6 3区 生物学 Q1 BIOLOGY
Miloš Vittori
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引用次数: 0

Abstract

The crustacean cuticle is a biological composite material consisting of chitin–protein fibres in a mineralized matrix. Recent research has revealed a surprising range of fibre architectures and mineral compositions of crustacean skeletal structures adapted to various mechanical demands. It is becoming increasingly clear that the organic fibres in the cuticle may be organized in patterns differing from the standard twisted plywood model. Observed fibre architectures in protruding skeletal structures include longitudinal and circular parallel fibre arrays. Skeletal minerals often include calcium phosphates in addition to calcium carbonates. Furthermore, skeletal properties are affected by protein cross-linking, which replaces mineralization as a stiffening mechanism in some structures. Several common structural motifs, such as the stiffening of the outer skeletal layers, the incorporation of non-mineralized cuticle in exposed structures, and interchanging layers of parallel fibres and the twisted plywood structure, can be identified in skeletal elements with similar functions. These evolutionary solutions have the potential for biomimetic applications, particularly as manufacturing technologies advance. To make use of this potential, we need to understand the processes behind the formation of the crustacean exoskeleton and determine which features are truly adaptive and worth mimicking.

甲壳动物外骨骼的结构多样性及其对生物仿生学的影响
甲壳类动物的角质层是一种生物复合材料,由矿化基质中的几丁质-蛋白质纤维组成。最近的研究发现,甲壳动物骨骼结构的纤维结构和矿物质成分适应各种机械要求,其范围之广令人惊讶。越来越清楚的是,角质层中有机纤维的组织模式可能不同于标准的扭曲胶合板模式。在突出的骨骼结构中观察到的纤维结构包括纵向和环形平行纤维阵列。骨骼矿物质除碳酸钙外,通常还包括磷酸钙。此外,骨骼特性还受到蛋白质交联的影响,在某些结构中,蛋白质交联取代了矿化作用,成为一种加固机制。在具有类似功能的骨骼元素中,可以发现几种常见的结构模式,如骨骼外层的加固、裸露结构中加入非矿化角质层、平行纤维层和扭曲胶合板结构的互换。这些进化解决方案具有生物仿生应用的潜力,特别是随着制造技术的进步。要利用这一潜力,我们需要了解甲壳动物外骨骼形成背后的过程,并确定哪些特征真正具有适应性,值得模仿。
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来源期刊
Interface Focus
Interface Focus BIOLOGY-
CiteScore
9.20
自引率
0.00%
发文量
44
审稿时长
6-12 weeks
期刊介绍: Each Interface Focus themed issue is devoted to a particular subject at the interface of the physical and life sciences. Formed of high-quality articles, they aim to facilitate cross-disciplinary research across this traditional divide by acting as a forum accessible to all. Topics may be newly emerging areas of research or dynamic aspects of more established fields. Organisers of each Interface Focus are strongly encouraged to contextualise the journal within their chosen subject.
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