霍普利亚甲虫的微流体和光学特性之间的复杂相互作用

IF 2.6 2区生物学 Q1 ZOOLOGY

Frontiers in Zoology Pub Date : 2024-11-14 DOI:10.1186/s12983-024-00552-0

Danica Pavlović, Branislav Salatić, Srećko Ćurčić, Petar Milovanović, Dejan V. Pantelić

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引用次数: 0

摘要

所有生物都生存在一个受多种外部影响（尤其是水和光）的世界中。某些昆虫体内的光子纳米结构随着时间的推移不断进化，以适应不同的环境条件，促进物种内部和物种之间的交流、伪装、体温调节、水合等。迄今为止，仅发现少数昆虫物种的鞘翅会因水分（或其蒸气）透过角质层而改变颜色。在这里，我们报告了一种猩红甲虫 Hoplia argentea，它在接触水时能从绿色变为棕红色，显示了可逆变化的显著能力。在这里，我们展示了鞘翅和鳞片形成了一个复杂而高效的微/纳米光流体系统。水被导入鳃裂，然后在内部被输送到鳞片的花瓣，在每个鳞片内部被吸湿，将夹带的空气挤出。吸水过程非常快，只需几秒钟。这一原理的优势在于毛细力产生的极高压力（约 15 巴），从而加快了空气的渗透。我们介绍了解释着色背后物理机制的光学模型，详细说明了超亲水性如何影响光学行为。霍普利亚属（Hoplia）中的物种表现出多种多样的着色策略，这可能与其特定的生态位有关。这些生物进化出了复杂的光学和微流体系统，促进了身体颜色的快速改变，可能用于环境伪装和体温调节等目的。研究鳃甲的微流体和光学特性不仅能加深我们对颜色变化背后的生物目的的理解，还能启发我们设计人工仿生装置。本文所描述的动态流体流动模式是相当恒定和独特的，可作为所谓的物理不可克隆函数（PUF）用于安全应用。更广泛地说，这种微流体系统可用于控制药物释放、传感、液压和气动泵送。

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Complex interplay between the microfluidic and optical properties of Hoplia sp. beetles

All living organisms exist in a world affected by many external influences, especially water and light. Photonic nanostructures present in certain insects, have evolved over time in response to diverse environmental conditions, facilitating communication within and between species, camouflage, thermoregulation, hydration, and more. Up to now, only a few insect species have been discovered whose elytron changes its color due to permeation of water (or its vapor) through cuticle. Here we report on a scarabaeid beetle Hoplia argentea remarkable in its ability to shift from green to brownish-red when exposed to water, demonstrating reversible changes. Here we show that elytron and scales form a complex and efficient micro/nano-optofluidic system. Water is channeled into the elytral lacunae, then transported internally to the petals of the scales, where it is wicked inside each scale, pushing the entrapped air out. Wicking is a very fast process, occurring during a few seconds. The advantage of this principle is in extremely high pressure (approximately 15 bar) produced by capillary forces, which expediates permeation of air. We present optical models that explain the physical mechanisms behind the coloration, detailing how superhydrophilic properties influence optical behavior. Species within the genus Hoplia exhibit diverse coloration strategies, likely linked to their specific ecological niches. These organisms have evolved intricate optical and microfluidic systems that facilitate rapid alterations in body coloration, potentially serving purposes such as environmental camouflage and thermoregulation. Studying microfluidic and optical properties of the elytra will not only enhance our understanding of the biological purposes behind color change but also inspires design of artificial biomimetic devices. Dynamic fluid flow patterns, described in this paper, are fairly constant and unique and can be used in security applications as a, so called, physically unclonable functions (PUF). More broadly, this kind of microfluidic system can be used for controlled drug release, sensing, hydraulic and pneumatic pumping.

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来源期刊

Frontiers in Zoology ZOOLOGY-

CiteScore

4.90

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Frontiers in Zoology is an open access, peer-reviewed online journal publishing high quality research articles and reviews on all aspects of animal life. As a biological discipline, zoology has one of the longest histories. Today it occasionally appears as though, due to the rapid expansion of life sciences, zoology has been replaced by more or less independent sub-disciplines amongst which exchange is often sparse. However, the recent advance of molecular methodology into "classical" fields of biology, and the development of theories that can explain phenomena on different levels of organisation, has led to a re-integration of zoological disciplines promoting a broader than usual approach to zoological questions. Zoology has re-emerged as an integrative discipline encompassing the most diverse aspects of animal life, from the level of the gene to the level of the ecosystem. Frontiers in Zoology is the first open access journal focusing on zoology as a whole. It aims to represent and re-unite the various disciplines that look at animal life from different perspectives and at providing the basis for a comprehensive understanding of zoological phenomena on all levels of analysis. Frontiers in Zoology provides a unique opportunity to publish high quality research and reviews on zoological issues that will be internationally accessible to any reader at no cost. The journal was initiated and is supported by the Deutsche Zoologische Gesellschaft, one of the largest national zoological societies with more than a century-long tradition in promoting high-level zoological research.