The turtle carapace as an optimized multi-scale biological composite armor:​ a review

Achrai, Ben; Wagner, H. Daniel

Affiliations

¹Department of Materials & Interfaces, Weizmann Institute of Science, Rehovot 76100, Israel

Abstract and keywords

The turtle carapace, the top dorsal part of the shell, is a remarkable multi-scale dermal armor that has evolved to withstand various types of high-stress events encountered in nature. This keratin-covered boney exoskeleton exhibits a number of structural motifs, including alternating rigid and flexible components, layering and functionally graded elements, designed to protect the reptile during predatory attacks, and smashing events. Here we review the multi-scale structural hierarchy of the turtle carapace and its corresponding mechanical properties. We show how the microscopic features of the carapace govern its various macroscopic mechanical responses relevant to protective functioning, including dynamic (impact and cyclic) compression and bending loading situations. In addition, the effect of hydration, a crucial factor for proper physiological-mechanical behavior of biological materials, is illustrated throughout. We also discuss carapace-inspired designs that could be advantageous over the traditional strategies adopted in impact-resistant materials, and could bring new mechanistic insights.

Keywords: Turtle shell; Biological composites; Hierarchical structure; Bio-inspired materials; Mechanical properties; Functionally graded materials

Links

DOI: 10.1016/j.jmbbm.2017.02.027

PubMed: 28325492

WoS: 000405976300005

History

Received: 2016-09-15

Revised: 2017-02-19

Accepted: 2017-02-24

Online: 2017-02-27

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Cited By (6)

Year	Entry
2019	Ampaw E, Owoseni TA, Du F, Pinilla N, Obayemi J, Hu J, Nigay P-M, Nzihou A, Uzonwanne V, Zebaze-Kana MG, Dewoolkar M, Tan T, Soboyejo W. Compressive deformation and failure of trabecular structures in a turtle shell. Acta Biomater. October 1, 2019;97:535-543.
2022	Micheletti C, Hurley A, Gourrier A, Palmquist A, Tang T, Shah FA, Grandfield K. Bone mineral organization at the mesoscale: a review of mineral ellipsoids in bone and at bone interfaces. Acta Biomater. April 1, 2022;142:1-13.
2023	Buss DJ, Rechav K, Reznikov N, McKee MD. Mineral tessellation in mouse enthesis fibrocartilage, Achilles tendon, and Hyp calcifying enthesopathy: a shared 3D mineralization pattern. Bone. September 2023;174:116818.
2019	Ishikawa N, Hirayama Y, Miake1 Y, Kitamura K, Kasahara N, Abe S, Yamamoto H. Comparison of the morphological structures of the human calvarium and turtle shell. J Hard Tiss Biol. 2019;28(3):289-296.
2020	Buss DJ, Reznikov N, McKee MD. Crossfibrillar mineral tessellation in normal and Hyp mouse bone as revealed by 3D FIB-SEM microscopy. J Struct Biol. November 1, 2020;212(2):107603.
2023	Buss DJ. Mineralization of Biological Fiber Systems [PhD thesis]. McGill University; July 2023.