Bio-Inspired Toughening of Composites in 3D-Printing

Stögerer, Johannes; Baumgartner, Sonja; Hochwallner, Alexander; Stampfl, Jürgen

doi:10.3390/ma13214714

Cited by 11 publications

(10 citation statements)

References 55 publications

(62 reference statements)

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“…Step by step, the raw material of unbound powder is finally removed, and a 3D model is constructed [ 47 ]. This technology is usually used in combination with other technologies, such as high temperature burning [ 49 ], stereolithography [ 50 ], or electro-hydro dynamic jetting [ 51 ], etc. The following is a commercial application of a more widely used, but also a combination of a variety of technologies of printing technology.…”

Section: Several Different 3d Printing Technologiesmentioning

confidence: 99%

Applications of 3D printed bone tissue engineering scaffolds in the stem cell field

Wang

Guo

2021

Regenerative Therapy

122

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Due to traffic accidents, injuries, burns, congenital malformations and other reasons, a large number of patients with tissue or organ defects need urgent treatment every year. The shortage of donors, graft rejection and other problems cause a deficient supply for organ and tissue replacement, repair and regeneration of patients, so regenerative medicine came into being. Stem cell therapy plays an important role in the field of regenerative medicine, but it is difficult to fill large tissue defects by injection alone. The scientists combine three-dimensional (3D) printed bone tissue engineering scaffolds with stem cells to achieve the desired effect. These scaffolds can mimic the extracellular matrix (ECM), bone and cartilage, and eventually form functional tissues or organs by providing structural support and promoting attachment, proliferation and differentiation. This paper mainly discussed the applications of 3D printed bone tissue engineering scaffolds in stem cell regenerative medicine. The application examples of different 3D printing technologies and different raw materials are introduced and compared. Then we discuss the superiority of 3D printing technology over traditional methods, put forward some problems and limitations, and look forward to the future.

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Section: Several Different 3d Printing Technologiesmentioning

confidence: 99%

Applications of 3D printed bone tissue engineering scaffolds in the stem cell field

Wang

Guo

2021

Regenerative Therapy

122

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“…Architecting materials to improve the fracture toughness without losing strength are emerging trends in materials engineering and often challenging. [1,2] Nowadays, a notable number of promising concept designs are available, most of them inspired by the animate and inanimate nature (e.g., biomimetics [2][3][4][5][6][7][8][9][10] and lithomimetics, [2,11] respectively), while others are born in the minds of scientists and engineers unrelated to nature (e.g., topological interlocking [2,[12][13][14][15] or lattice metamaterials [2,16] ).…”

Section: Introductionmentioning

confidence: 99%

“…[2] In the field of biomimetics, numerous examples of composites linking high strength and toughness can be found. [7] Well-known examples for such material compositions are nacre [17] or the skeleton of Euplectella aspergillum [18,19] (deep-sea sponge from the Western Pacific), both combining different hard and soft phases to gain outstanding mechanical performance. [6,7,18] Among other mechanisms, the underlying phenomenon providing these improved behaviors can be explained by the material inhomogeneity effect, which has been studied intensively.…”

Section: Introductionmentioning

confidence: 99%

“…[7] Well-known examples for such material compositions are nacre [17] or the skeleton of Euplectella aspergillum [18,19] (deep-sea sponge from the Western Pacific), both combining different hard and soft phases to gain outstanding mechanical performance. [6,7,18] Among other mechanisms, the underlying phenomenon providing these improved behaviors can be explained by the material inhomogeneity effect, which has been studied intensively. [6,[20][21][22][23][24][25] This effect is caused by the spatial variation of mechanical properties (i.e., Young´s modulus and yield strength).…”

Section: Introductionmentioning

confidence: 99%

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Multimaterial Extrusion‐Based Additive Manufacturing of Compliant Crack Arrester: Influence of Interlayer Length, Thickness, and Applied Strain Rate

2022

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Additive manufacturing is a useful tool for fabricating complex multimaterial structures. Compliant interlayers (ILs) can easily be introduced into stiff materials to increase toughness and stop or impede crack growth, as is done in nature. The aim herein is to analyze the influence of varying IL lengths and thicknesses on crack propagation in 3D‐printed polymers at different loading rates. A glycol‐modified poly(ethylene terephthalate) is used as a matrix material, while a thermoplastic elastomer on a copolyester basis serves as an compliant IL. Specimen fabrication is done with a fused filament fabrication 3D printer equipped with a multimaterial unit, which allows to print a component composed of several materials within one print. Additively manufactured Charpy samples are tested in three‐point bending at loading rates between 0.1 mm min−1 and 3.8 m s−1. The thickness of the IL almost shows no effect on energy absorption as long as remaining in the same printing orientation and loading rate. For varying IL lengths, a constant fight between crack penetration and crack deflection occurs. At low loading rates, the IL acts as a defect. As the loading rate increases, the total absorbed energy of composites increases compared with the pure matrix material.

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“…This increasing need for innovation is fortified by the development of biomimetic science, which deals with the study of biological processes in order to highlight innovative solutions to everyday problems [ 1 ]. Across years of evolution and natural selection, living creatures have resourcefully accomplished a wide range of captivating functions towards optimized performances as a requisite to survive, adapt and interact with their ever-changing complex natural environments [ 2 ]. This field specifically aims at understanding nature’s solutions as a mine of novel design ideas in order to exploit them to find concrete applications [ 3 ].…”

Section: Introductionmentioning

confidence: 99%

Down to the Bone: A Novel Bio-Inspired Design Concept

et al. 2021

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The solutions provided through natural evolution of living creatures serve as an ingenious source of inspiration for many technological and applicative fields. Along these lines, bone-inspired concepts lead to fascinating advances in product design, architecture and garments, thanks to the bone’s exceptional combination of strength, toughness and lightness. Structural applications are inspired by the bone’s ability to resist fracture under a large spectrum of forces, while the high surface area and pore connectivity of bone architecture present exciting opportunities from an aesthetic point of view. Behind these inspirations, a disruptive common belief emerges: “down to the bone”, a journey in search of equality, universality and substantiality. Herein, we explore the current state of the art in bone-inspired applications in these fields, considering the two major categories of structural and aesthetic inspirations and discussing further technological developments.

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Bio-Inspired Toughening of Composites in 3D-Printing

Cited by 11 publications

References 55 publications

Applications of 3D printed bone tissue engineering scaffolds in the stem cell field

Applications of 3D printed bone tissue engineering scaffolds in the stem cell field

Multimaterial Extrusion‐Based Additive Manufacturing of Compliant Crack Arrester: Influence of Interlayer Length, Thickness, and Applied Strain Rate

Down to the Bone: A Novel Bio-Inspired Design Concept

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