Lamellar architectures in stiff biomaterials may not always be templates for enhancing toughness in composites

Monn, Michael A.; Vijaykumar, Kaushik; Kochiyama, Sayaka; Kesari, Haneesh

doi:10.1038/s41467-019-14128-8

Cited by 46 publications

(23 citation statements)

References 62 publications

(94 reference statements)

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“…Numerous studies of glass sponges skeletons suggest that the unique fracture toughness results from the spicules cylindrical layered architecture. However, Monn et al [18] discovered that while interfacial fracture does improve the toughness of the cylindrically layered beam, its impact is relatively small compared to the arrest and re-nucleation mechanism that occurs in the planar layered beam [18]. This finding is questioning this theory and shows that the understanding of the relationship between layered architectures and toughness enhancement is not yet complete.…”

Section: Siliceous Skeletal Frameworkmentioning

confidence: 99%

“…1 Sponges possess a unique ability to produce hierarchically structured 3D scaffolds made of chitin, spongin, or silica-based biocomposites of both biopolymers. Due to the cultivation of sponges, they represent a unique renewable source of such 3D constructs of novel materials [21,22], by means of existing tools and manufacturing schemes, for the targeted application in new 3D open-celled products to be used for human endeavors [13,18]. Over the last decades numerous research groups analyzed the organic constituents involved in spiculogenesis and supporting formation of sophisticated glass sponge constructs.…”

Section: Siliceous Skeletal Frameworkmentioning

confidence: 99%

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Modern scaffolding strategies based on naturally pre-fabricated 3D biomaterials of poriferan origin

et al. 2020

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Modern scaffolding strategies include two key ways: to produce requested 3D constructs from corresponding precursors using technological tools, or simply use naturally already prefabricated scaffolds if they originate from renewable sources. Marine sponges inhabit oceans since the Precambrian. These ancient multicellular organisms possess a broad variety of evolutionary approved and ready to use skeletal structures, which seem to be well applicable as 3D scaffolds in diverse fields of modern bioinspired materials science, biomimetics and regenerative medicine. In this review, most attention is paid to biosilica-, chitin-, and spongin-based scaffolds of poriferan origin with respect to their potential use.

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Section: Siliceous Skeletal Frameworkmentioning

confidence: 99%

Section: Siliceous Skeletal Frameworkmentioning

confidence: 99%

Modern scaffolding strategies based on naturally pre-fabricated 3D biomaterials of poriferan origin

et al. 2020

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“…First, single-spicule studies have revealed the presence of an underlying laminated architecture consisting of concentric lamellae of consolidated silica nanoparticles separated by thin organic interlayers. The silica layers decrease in thickness from the spicule core to its periphery, resulting in a functionally graded design that effectively retards crack propagation through the spicules, while simultaneously increasing their buckling resistance [3,6].…”

Section: Introductionmentioning

confidence: 99%

Mechanical and hydrodynamic analyses of helical strake-like ridges in a glass sponge

Fernandes

Saadat

Cauchy-Dubois

et al. 2021

J. R. Soc. Interface.

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From the discovery of functionally graded laminated composites, to near-structurally optimized diagonally reinforced square lattice structures, the skeletal system of the predominantly deep-sea sponge Euplectella aspergillum has continued to inspire biologists, materials scientists and mechanical engineers. Building on these previous efforts, in the present study, we develop an integrated finite element and fluid dynamics approach for investigating structure–function relationships in the complex maze-like organization of helical ridges that surround the main skeletal tube of this species. From these investigations, we discover that not only do these ridges provide additional mechanical reinforcement, but perhaps more significantly, provide a critical hydrodynamic benefit by effectively suppressing von Kármán vortex shedding and reducing lift forcing fluctuations over a wide range of biologically relevant flow regimes. By comparing the disordered sponge ridge geometry to other more symmetrical strake-based vortex suppression systems commonly employed in infrastructure applications ranging from antennas to underwater gas and oil pipelines, we find that the unique maze-like ridge organization of E. aspergillum can completely suppress vortex shedding rather than delaying their shedding to a more downstream location, thus highlighting their potential benefit in these engineering contexts.

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“…Biogenic materials usually exceed the mechanical performance achievable by man-made counterparts, even if built from similar components. This justi es the ongoing quest to approach biomimicry as a design process to achieve such performance, [1][2][3][4][5][6] which has considered biomineralization and other mechanisms. In the animal kingdom, such processes lead to the formation of bones, enamel and cuticles, among others.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of self-assembled nacre-like materials with 3D periodic layers from nanochitin via hydrogelation and mineralization

Liu

et al. 2021

Preprint

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Here introduced a route for the synthesis of 3D structures that display a mechanical strength that competes with that of the toughest materials found in nature. Following the “brick-and-mortar” biomineralization typical of nacre, self-stratified, periodic materials are obtained by one-step ion diffusion gradient and hydrogelation of nanochitin with simultaneous mineral coprecipitation. Specifically, under appropriate electrolyte conditions, hydroxyapatite (HA) microspheres grow in an organic network formed from partially deacetylated chitin nanofibers (NCh), resulting in periodic stacking of mineralized (HA) and non-mineralized (NCh) layers. By directional diffusion, customizable 3D shapes are self-assembled and demonstrated to function as optical waveguides with selective light transmission at interfaces. Upon hot pressing, the resulting solid structures exhibit a superb mechanical performance while being biocompatible (tested with chondrogenic ATDC5 cells as a model for physiological mineralization). Overall, a shape-controlled, one-pot biomineralization method was proposed that achieves hierarchical, periodic and strong “nacre-like” structures suitable as biomedical material.

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Lamellar architectures in stiff biomaterials may not always be templates for enhancing toughness in composites

Cited by 46 publications

References 62 publications

Modern scaffolding strategies based on naturally pre-fabricated 3D biomaterials of poriferan origin

Modern scaffolding strategies based on naturally pre-fabricated 3D biomaterials of poriferan origin

Mechanical and hydrodynamic analyses of helical strake-like ridges in a glass sponge

Synthesis of self-assembled nacre-like materials with 3D periodic layers from nanochitin via hydrogelation and mineralization

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