Equine hoof wall: Structure, properties, and bioinspired designs.
Abstract: The horse hoof wall exhibits exceptional impact resistance and fracture control due to its unique hierarchical structure which contains tubular, lamellar, and gradient configurations. In this study, structural characterization of the hoof wall was performed revealing features previously unknown. Prominent among them are tubule bridges, which are imaged and quantified. The hydration-dependent viscoelasticity of the hoof wall is described by a simplified Maxwell-Weichert model with two characteristic relaxation times corresponding to nanoscale and mesoscale features. Creep and relaxation tests reveal that the specific hydration gradient in the hoof keratin likely leads to reduced internal stresses that arise from spatial stiffness variations. To better understand realistic impact modes for the hoof wall in-vivo, drop tower tests were executed on hoof wall samples. Fractography revealed that the hoof wall's reinforced tubular structure dominates at lower impact energies, while the intertubular lamellae are dominant at higher impact energies. Broken fibers were observed on the surface of the tubules after failure, suggesting that the physically intertwined nature of the tubule reinforcement and intertubular matrix improves the toughness of this natural fiber reinforced composite. The augmented understanding of the structure-mechanical property relationship in dynamic loading led to the design of additively manufactured bioinspired structures, which were evaluated in quasistatic and dynamic loadings. The inclusion of gradient structures and lamellae significantly reduced the damage sustained in drop tower tests, while tubules increased the energy absorption of samples tested in compact tension. The samples most similar to the hoof wall displayed remarkably consistent fracture control properties. STATEMENT OF SIGNIFICANCE: The horse hoof wall, capable of withstanding large, repeated, dynamic loads, has been touted as a candidate for impact-resistant bioinspiration. However, our understanding of this biological material and its translation into engineered designs is incomplete. In this work, new features of the horse hoof wall are quantified and the hierarchical failure mechanisms of this remarkable material under near-natural loading conditions are uncovered. A model of the hoof wall's viscoelastic response, based on studies of other keratinous materials, was developed. The role of hydration, strain rate, and impact energy on the material's response were elucidated. Finally, multi-material 3D printed designs based on the hoof's meso/microstructure were fabricated and exhibited advantageous energy absorption and fracture control relative to control samples.
Copyright © 2022. Published by Elsevier Ltd.
Publication Date: 2022-08-20 PubMed ID: 35995409DOI: 10.1016/j.actbio.2022.08.028Google Scholar: Lookup
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- Journal Article
- Research Support
- U.S. Gov't
- Non-P.H.S.
Summary
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This research paper focuses on the structure of horse hoof walls and their noteworthy resistance to impact and ability to control fractures. By understanding and quantifying the hoof’s structural characteristics, the study further provides new bio-inspired designs engineered for similar high-impact resistance.
Study Highlights
- The research primarily focused on undertaking a structural characterization of a horse hoof wall. New features were identified; mostly the tubule bridges, that were imaged and comprehensively quantified.
- The hoof wall’s hydration-dependent viscoelasticity was outlined using a simplified model. This model identified two distinct relaxation times that correspond to nanoscale and mesoscale features.
- To understand the realistic impact modes that the horse hoof wall experiences in-vivo, drop tower tests were performed. The results of these tests revealed that the hoof wall’s reinforced tubular structure dominates at lower impact energies, and the intertubular lamellae become dominant at higher impact energies.
- The finding of broken fibers on the tubules’ surface after the occurrence of a failure, facilitates the assumption that the intertwined nature of the tubule reinforcement and intertubular matrix helps improve the toughness of the natural fiber reinforced composite.
Outcome and Significance
- The improved comprehension of the horse hoof wall’s structure-mechanical property relationship during dynamic loading guided the fabrication of additively manufactured bioinspired structures. These structures were assessed for their performance under quasistatic and dynamic loadings.
- It was found that the inclusion of gradient structures and lamellae significantly diminished the damage incurred in drop tower tests, whereas tubules amplified the energy absorption of the samples tested in compact tension. The samples that were most similar to the hoof wall demonstrated remarkably consistent fracture control properties.
- The horse hoof wall has long been noticed for its distinct ability to withstand large, repeated, dynamic loads, making it a feasible candidate for impact-resistant bioinspiration. This study contributes valuable insights into the hoof wall features and their hierarchical failure mechanisms under near-natural loading conditions. A model of the hoof wall’s viscoelastic response was also developed.
- The influence of hydration, strain rate, and impact energy on the hoof wall’s response was additionally elucidated within the research. Finally, the study successfully introduced bioinspired 3D printed designs based on the hoof’s microstructure that displayed advantageous energy absorption and fracture control capabilities.
Cite This Article
APA
Lazarus BS, Luu RK, Ruiz-Pérez S, Bezerra WBA, Becerra-Santamaria K, Leung V, Durazo VHL, Jasiuk I, Barbosa JDV, Meyers MA.
(2022).
Equine hoof wall: Structure, properties, and bioinspired designs.
Acta Biomater, 151, 426-445.
https://doi.org/10.1016/j.actbio.2022.08.028 Publication
Researcher Affiliations
- Materials Science and Engineering, University of California San Diego, 9500 Gilman Drive, La Jolla, CA 92093-0418, USA. Electronic address: bslazaru@eng.ucsd.edu.
- Department of Mechanical and Aerospace Engineering, University of California San Diego, USA.
- Facultad de Ciencias, Universidad Nacional Autónoma de México, Mexico City, Mexico.
- Department of Materials Science, Military Institute of Engineering-IME, Rio de Janeiro 22290270, Brazil.
- Facultad de Ingeniería, Arquitectura y Diseño, Universidad Autónoma de Baja California, Mexicali, Mexico.
- Materials Science and Engineering, University of California San Diego, 9500 Gilman Drive, La Jolla, CA 92093-0418, USA.
- Departamento de Ciencias Químico-Biológicas, Universidad de Sonora, Hermosillo, Mexico.
- Department of Mechanical Science and Engineering, University of Illinois Urbana-Champaign, Champaign, IL, USA.
- Department of Materials, University Center SENAI CIMATEC, Salvador, Brazil.
- Materials Science and Engineering, University of California San Diego, 9500 Gilman Drive, La Jolla, CA 92093-0418, USA; Department of Mechanical and Aerospace Engineering, University of California San Diego, USA; Department of Nanoengineering, University of California San Diego, USA.
MeSH Terms
- Animals
- Extremities
- Fractures, Bone
- Hoof and Claw
- Horses
- Keratins / chemistry
Conflict of Interest Statement
Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
Citations
This article has been cited 3 times.- Zhang X, Yang B, Wu J, Li X, Zhou R. Research Progress on Helmet Liner Materials and Structural Applications. Materials (Basel) 2024 May 30;17(11).
- Luu RK, Buehler MJ. BioinspiredLLM: Conversational Large Language Model for the Mechanics of Biological and Bio-Inspired Materials. Adv Sci (Weinh) 2024 Mar;11(10):e2306724.
- Hobbs SJ, Curtis S, Martin J, Sinclair J, Clayton HM. Hoof Matters: Developing an Athletic Thoroughbred Hoof. Animals (Basel) 2022 Nov 11;12(22).
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