In vivo viscoelastic properties of cetacean integument: an experimental characterization

IF 2 3区生物学 Q2 MARINE & FRESHWATER BIOLOGY

Marine Mammal Science Pub Date : 2024-07-06 DOI:10.1111/mms.13153

Dory Y. Yang, K. Alex Shorter, Michael Moore, Julie Rocho‐Levine, Randall S. Wells, Kira Barton, Mark Johnson

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引用次数: 0

Abstract

Suction cups are commonly used to attach biologging tags to cetaceans, and interact mechanically with compliant integument, an organ primarily composed of skin and blubber. However, the impact of compliance on suction cup performance is difficult to predict because knowledge about in vivo integument mechanics is lacking. Here, an experimental approach is used to investigate the mechanical properties of common bottlenose dolphin (Tursiops truncatus) integument using a custom instrument, the static suction cup (SSCup), to collect data from both trained dolphins and wild individuals (n = 17) during a static pose. Three loading profiles were applied at three sites to quantify nonlinear stiffness, hysteresis, and creep. The site at the dorsal fin insertion exhibited the highest stiffness, while sites posterior to the blowhole and above the pectoral fin showed greater energy dissipation during cyclic loading. Viscoelastic behavior was observed across all sites. Suction cup performance on a surrogate material with broadly similar compliance showed reduced performance compared to cups on rigid acrylic: the maximum applied force at detachment on acrylic (50 N) was twice as large as the compliant substrate (25 N). Site‐dependent compliance of integument may lead to varying performance of suction cups as an attachment method for tags.

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鲸目动物皮肤的体内粘弹性特性：实验表征

吸盘通常用于在鲸类动物身上粘贴生物标签，并与顺应性皮膜（主要由皮肤和脂肪组成的器官）发生机械相互作用。然而，由于缺乏有关体内骨膜力学的知识，因此很难预测顺应性对吸盘性能的影响。本文采用一种实验方法，使用一种定制仪器--静态吸盘（SSCup），从训练有素的海豚和野生个体（n = 17）身上收集静态姿势时的数据，研究普通瓶鼻海豚（Tursiops truncatus）体表的机械特性。在三个部位施加了三种加载剖面，以量化非线性刚度、滞后和蠕变。背鳍插入部位的刚度最大，而吹孔后方和胸鳍上方的部位在循环加载时能量耗散更大。在所有部位都观察到了粘弹性行为。吸盘在顺应性大致相似的代用材料上的性能比吸盘在刚性丙烯酸树脂上的性能要低：丙烯酸树脂上脱离时的最大作用力（50 N）是顺应性基质（25 N）的两倍。不同部位的皮肤顺应性可能导致吸盘作为标签附着方法的性能不同。

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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来源期刊

Marine Mammal Science 生物-动物学

CiteScore

4.80

自引率

8.70%

发文量

审稿时长

6-12 weeks

期刊介绍： Published for the Society for Marine Mammalogy, Marine Mammal Science is a source of significant new findings on marine mammals resulting from original research on their form and function, evolution, systematics, physiology, biochemistry, behavior, population biology, life history, genetics, ecology and conservation. The journal features both original and review articles, notes, opinions and letters. It serves as a vital resource for anyone studying marine mammals.