Probing the Role of Bone Lamellar Patterns through Collagen Microarchitecture Mapping, Numerical Modeling, and 3D‐Printing

Grezzana, Gabriele; Loh, Hyun-Chae; Qin, Zhao; Buehler, Markus J.; Mašić, Admir; Libonati, Flavia

doi:10.1002/adem.202000387

Cited by 11 publications

(15 citation statements)

References 47 publications

(47 reference statements)

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“…The cracks penetrated the entire sample with the VFs, whereas the cracks in the sample with the TFs were mostly confined in the ML and presented a radial pattern similar to the cracks in the spike (Figure d). Specifically, the twisted fibers in the OL and IL delayed the structural failure and improved the mechanical performance of the samples. − …”

Section: Resultsmentioning

confidence: 99%

Optimized Hierarchical Structure and Chemical Gradients Promote the Biomechanical Functions of the Spike of Mantis Shrimps

Liu

Lin

et al. 2021

ACS Appl. Mater. Interfaces

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The tail spike of the mantis shrimp is the appendage for counteracting the enemy from behind. Here, we investigate the correlations between the chemical compositions, the microstructures, and the mechanical properties of the spike. We find that the spike is a hollow beam with a varying cross section along the length. The cross section comprises four different layers with distinct features of microstructures and chemical compositions. The local mechanical properties of these layers correlate well with the microstructures and chemical compositions, a combination of which effectively restricts the crack propagation while maximizing the release of strain energy during deformation. Finite element analysis and mechanics modeling demonstrate that the optimized structure of the spike confines the mechanical damage in the region near the tip and prevents catastrophic breakage at the base. Furthermore, we use a 3D printing technique to fabricate multiple hollow cylindrical samples consisting of biomimetic microstructures of the spike and confirm that the combination of the Bouligand structure with radially oriented parallel sheets greatly improves the toughness and strength during compression tests. The multiscale design strategy of the spike revealed here is expected to be of great interest for the development of novel bioinspired materials.

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Section: Resultsmentioning

confidence: 99%

Optimized Hierarchical Structure and Chemical Gradients Promote the Biomechanical Functions of the Spike of Mantis Shrimps

Liu

Lin

et al. 2021

ACS Appl. Mater. Interfaces

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“…Fig. 1 b shows the fast prototype of such a respirator with a polyjet multi-material 3D printer ( Grezzana et al, 2020 ; Qin et al, 2017 ; Xiang Gu et al, n.d. ). The 3D model was modified based on an open-source stereolithography file ( “MY FACE MASK: 3D printed face Mask with a replaceable filter,” n.d .…”

Section: Resultsmentioning

confidence: 99%

“…To balance the environmental issue and personal protection during the usage of respirators, one solution is to develop substituting fibrous network material that can provide similar protection but will not generate environmental issues in the long term. Natural materials including chitin, cellulose, hemicellulose, silk, collagen, keratin are found to have forms of various fibrous networks including mycelium (L. Yang et al, 2021 ), bamboo/wood/cotton fibers ( Cui et al, 2021 ), spider web/cocoon, basement membrane, and hair ( Buehler and Yung, 2009 ) that all have natural functions of filtration but can also be degraded within a more reasonable timeframe than plastics by microorganisms, causing no long-term issue to the environment ( Greer and Deshpande, 2019 ; Grezzana et al, 2020 ; Jones et al, 2020 ; Qin and Buehler, 2013 ; Shah et al, 2016 ). It is feasible to make fibrous membrane by using these biodegradable materials with an electro/melt spinning method and tailor the membrane into pieces of a desire shape to work as a changeable filter for the respirator.…”

Section: Discussionmentioning

confidence: 99%

Design, manufacture, and testing of customized sterilizable respirator

Yang

Qin

2022

Journal of the Mechanical Behavior of Biomedical Materials

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“…Based on Bancelin et al, 2015;Yang et al, 2015;Lynch et al, 2017. Zhang et al, 2019;Grezzana et al, 2020;Zorzetto et al, 2020). Nevertheless, using the same approach in soft fibrous tissues is more scarce.…”

Section: Structural Mechanisms In Biomimetic Materials and Soft Tissue Engineeringmentioning

confidence: 99%

“…For hard tissues, hierarchy is much frequently studied and mimicked. Moreover, and very notably, the nanoscale reinforcement is known to simultaneously favor the strength and toughness of materials (Evans, 1990; Launey and Ritchie, 2009), in particular bone (Gupta et al, 2005;Gupta et al, 2006;Launey and Ritchie, 2009;Libonati and Vergani, 2016;Grezzana et al, 2020). Therefore, combining nanoscale structures in higher levels constructs may provide valuable advantages.…”

Section: Structural Hierarchy and Nested Compositesmentioning

confidence: 99%

Structural Mechanisms in Soft Fibrous Tissues: A Review

Sharabi

2022

Front. Mater.

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Through years of evolution, biological soft fibrous tissues have developed remarkable functional properties, unique hierarchical architectures, and -most notably, an unparalleled and extremely efficient deformation ability. Whereas the structure-function relationship is well-studied in natural hard materials, soft materials are not getting similar attention, despite their high prevalence in nature. These soft materials are usually constructed as fiber-reinforced composites consisting of diverse structural motifs that result in an overall unique mechanical behavior with large deformations. Biomimetics of their mechanical behavior is currently a significant bioengineering challenge. The unique properties of soft fibrous tissues stem from their structural complexity, which, unfortunately, also hinders our ability to generate adequate synthetic analogs, such that autografts remain the “gold standard” materials for soft-tissue repair and replacement. This review seeks to understand the structural and deformation mechanisms of soft collagenous tissues, with a particular emphasis on tendon and ligaments, the annulus fibrosus (AF) in the intervertebral disc (IVD), skin, and blood vessels. We examined and compared different mechanical and structural motifs in these different tissue types, which are subjected to complex and varied mechanical loads, to isolate the mechanisms of their deformation behavior. Herein, we focused on their composite structure from a perspective of the different building blocks, architecture, crimping patterns, fiber orientation, organization and their structure-function relationship. In the second part of the review, we presented engineered soft composite applications that used these structural motifs to mimic the structural and mechanical behavior of soft fibrous tissues. Moreover, we demonstrated new methodologies and materials that use biomimetic principles as a guide. These novel architectural materials have tailor-designed J-shaped large deformations behavior. Structural motifs in soft composites hold valuable insights that could be exploited to generate the next generation of materials. They actually have a two-fold effect: 1) to get a better understanding of the complex structure-function relationship in a simple material system using reverse biomimetics and 2) to develop new and efficient materials. These materials could revolutionize the future tailor-designed soft composite materials together with various soft-tissue repair and replacement applications that will be mechanically biocompatible with the full range of native tissue behaviors.

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Probing the Role of Bone Lamellar Patterns through Collagen Microarchitecture Mapping, Numerical Modeling, and 3D‐Printing

Cited by 11 publications

References 47 publications

Optimized Hierarchical Structure and Chemical Gradients Promote the Biomechanical Functions of the Spike of Mantis Shrimps

Optimized Hierarchical Structure and Chemical Gradients Promote the Biomechanical Functions of the Spike of Mantis Shrimps

Design, manufacture, and testing of customized sterilizable respirator

Structural Mechanisms in Soft Fibrous Tissues: A Review

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