Damage shielding mechanisms in hierarchical composites in nature with potential for design of tougher structural materials

Marthin, Otte; Gamstedt, E. Kristofer

doi:10.1098/rsos.181733

Cited by 12 publications

(6 citation statements)

References 35 publications

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“…Although wood is stiffer and less tough than other non-mineralised biological materials, its time-dependent deformation is likely to absorb energy similarly and resist fracture, both in the living, hydrated state 3 and when dried as a constructional material. Understanding the nanoscale mechanisms will help us to extract optimised performance from softwoods and to design new materials, made from wood or otherwise 65 , 66 , with enhanced strength and manufacturability.…”

Section: Discussionmentioning

confidence: 99%

Nanostructural deformation of high-stiffness spruce wood under tension

Thomas

Altaner

Forsyth

et al. 2021

Sci Rep

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Conifer wood is an exceptionally stiff and strong material when its cellulose microfibrils are well aligned. However, it is not well understood how the polymer components cellulose, hemicelluloses and lignin co-operate to resist tensile stress in wood. From X-ray scattering, neutron scattering and spectroscopic data, collected under tension and processed by novel methods, the ordered, disordered and hemicellulose-coated cellulose components comprising each microfibril were shown to stretch together and demonstrated concerted, viscous stress relaxation facilitated by water. Different cellulose microfibrils did not all stretch to the same degree. Attempts were made to distinguish between microfibrils showing large and small elongation but these domains were shown to be similar with respect to orientation, crystalline disorder, hydration and the presence of bound xylan. These observations are consistent with a major stress transfer process between microfibrils being shear at interfaces in direct, hydrogen-bonded contact, as demonstrated by small-angle neutron scattering. If stress were transmitted between microfibrils by bridging hemicelluloses these might have been expected to show divergent stretching and relaxation behaviour, which was not observed. However lignin and hemicellulosic glucomannans may contribute to stress transfer on a larger length scale between microfibril bundles (macrofibrils).

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Section: Discussionmentioning

confidence: 99%

Nanostructural deformation of high-stiffness spruce wood under tension

Thomas

Altaner

Forsyth

et al. 2021

Sci Rep

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“…We had found through the pilot study that the water jet drilling only worked when it was within a certain range of pressure and time. The stress was concentrated on a region surface, causing the existence of a low-stress area and resulting in a stress shielding effect, so brittle failure appeared [31]. However, it is pointed out that spallation damage would occur only when the tensile stress was greater than the spallation strength (i.e., 0.5 tensile strength) of the hard brittle material, and the stress history should be taken into consideration [32].…”

Section: Discussionmentioning

confidence: 99%

Water jet as a novel technique for enamel drilling ex vivo

et al. 2021

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To investigate the usage of a water jet for enamel drilling ex vivo, 210 individual extracted molars without lesions or fillings were collected. Then, the specimens were drilled by a water jet or a high-speed dental drill. The cavities of 50 teeth were reconstructed digitally by micro-computed tomography (micro-CT) to measure the height and width. The cavities of 10 teeth were longitudinally incised and their surfaces were observed by scanning electronic microscopy (SEM). After the cavities were filled, 50 fillings were vertically incised. The bonding interface between tooth and filling was observed by SEM. 50 teeth with fillings were stained in 0.1% rhodamine B solution, and then the dye penetration between tooth and filling was observed under the stereomicroscope and confocal laser scanning microscopy (CLSM). The bonding strength between enamel and filling of 50 teeth was simulated and predicted with finite element analysis (FEA). At 140–150 MPa and for 2–3 s, cavities were made with a depth of approximately 764 μm in each tooth. SEM showed the cavity surface in the water jet group had a more irregular concave and convex structure than that in the high-speed dental drill group. There was a trend that the microleakage and bonding width was smaller in the water jet group than in the high-speed dental drill group. FEA indicated that the stress on the resin surface was greater than on the enamel surface in the water jet group. Compared with the tooth drilled by a high-speed dental drill, the tooth drilled by a water jet gained better retention of the filling material and suffered less bonding strength on the enamel surface. Water jet drilling is effective for enamel drilling.

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“…One reason for that better performance is the effective distribution of the stress over a large area, thus increasing the scaffold's toughness in general. [ 211 ] Moreover, the hierarchical organization has been adopted in nature by many species to prevent the accumulation of somatic mutations. [ 212 ] This emphasizes the influence of hierarchical‐based scaffolds on cell proliferation and differentiation during tissue healing.…”

Section: Biophysical Cell Responses In Tissue Engineeringmentioning

confidence: 99%

“…One reason for that better performance is the effective distribution of the stress over a large area, thus increasing the scaffold's toughness in general. [211] Moreover, the hierarchical organization has been adopted in nature by many species to Figure 7. A) Schematic illustration of the effect of surface topography (flat, micro, nano, and hierarchical) on cellular responses.…”

Section: Micro and Macroenvironments For Cellular Responsesmentioning

confidence: 99%

Recent Advances in Regenerative Tissue Fabrication: Tools, Materials, and Microenvironment in Hierarchical Aspects

Ratri

Brilian

Setiawati

et al. 2021

Advanced NanoBiomed Research

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As part of regenerative medicine, artificial, hierarchical tissue engineering is a favorable approach to satisfy the needs of patients for new tissues and organs to replace those with defects caused by age, disease, or trauma or to correct congenital disabilities. However, the application of tissue engineering faces critical issues, such as the biocompatibility of the fabricated tissues and organs, the scaffolding, the complex biomechanical processes within cells, and the regulation of cell biology. Although fabrication strategies, including the traditional bioprinting, photolithography, and organ‐on‐a‐chip methods, as well as combinations of fabrication processes, face many challenges, they are methods that can be used in hierarchical tissue engineering. The strategic approach to synthetic, hierarchical tissue engineering is to use a combination of several technologies incorporating material science, cell biology, additive manufacturing (AM), on‐a‐chip strategies, and biomechanics. Herein, in a review, the current materials and biofabrication strategies of various artificial hierarchical tissues are discussed based on the level of tissue complexity from nano to macrosize and the adaptive interactions between cells and the scaffolding surrounding the incorporated cells.

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Damage shielding mechanisms in hierarchical composites in nature with potential for design of tougher structural materials

Cited by 12 publications

References 35 publications

Nanostructural deformation of high-stiffness spruce wood under tension

Nanostructural deformation of high-stiffness spruce wood under tension

Water jet as a novel technique for enamel drilling ex vivo

Recent Advances in Regenerative Tissue Fabrication: Tools, Materials, and Microenvironment in Hierarchical Aspects

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