Your search keyword '"NACRE"' showing total 458 results

1. Percolation theory analysis of nacre‐like bioinspired poly(trimethylene terephthalate)/graphene nanosheets‐iron oxide composites.

Author

Huang, Chien‐Lin, Lin, En‐Zai, Tung, Ping‐Zhang, and Xue, Ming‐Ru

Subjects

*PERCOLATION theory, *HEAT treatment, *BIOMIMETIC polymers, *POLYMERIC nanocomposites, *GRAPHENE oxide, *IRON oxides, *MORTAR

Abstract

Highlights Biomimetic polymer composites with micro/nano‐scale brick‐and‐mortar structures show promise for advancing nacre‐like polymer bioinspired nanocomposites. This study used a solvothermal method to graft MIL‐101 onto graphene oxide (GO), forming GO‐g‐MIL‐101. Subsequent heat treatments at 700 and 900°C under inert gas produced magnetic graphene nanosheets (GNS@Fe) with iron oxide particles. Poly(trimethylene terephthalate) (PTT) served as the matrix. PTT/GNS@Fe powders were prepared by coagulation then formed into bioinspired PTT/GNS@Fe and PTT/GNS@Fe‐m composites via solvent casting and hot pressing, yielding brick‐and‐mortar structures with and without magnetic alignment. PTT served as the soft phase and GNS@Fe as the hard phase. Rheological and conductivity analysis of PTT bioinspired composites, based on percolation theory, revealed microstructural changes. Results show that magnetic field assistance enhances GNS@Fe alignment in PTT/GNS@Fe‐m composites. With higher GNS@Fe content, reduced interlayer spacing creates a PTT‐GNS@Fe network, where nanoscale confinement limits PTT chain mobility, impacting crystallization. Low GNS@Fe levels promote crystallization, while high levels hinder it, with PTT unable to crystallize in nacre‐like composites above 40 wt% GNS@Fe. Additionally, we tested the electromagnetic interference (EMI) shielding of the PTT/GNS@Fe bioinspired composite system, finding that the shielding efficiency of PTT/GNS@Fe‐m with 40 wt% filler, though affected in magnetism by processing, approaches commercial application levels. Rheological and conductivity analysis via percolation theory. Percolation analysis revealed microstructures in the nacre‐like composite. Magnetic self‐assembly in PTT/GNS@Fe‐m led to more oriented structures. Higher GNS@Fe content reduced spacing, forming PTT‐GNS@Fe networks. Nanoconfinement and adsorption limited PTT chains, reducing crystallinity. [ABSTRACT FROM AUTHOR]

Published

2024

2. On the Damage Tolerance of Bioinspired Gradient Composites with Nacre‐Like Architecture.

Author

Zhang, Nan, Liu, Zengqian, Yu, Qin, Li, Xiaotao, Zhu, Yankun, Wang, Shaogang, Hao, Yuquan, Jiang, Bailing, Zhang, Zhefeng, and Ritchie, Robert O.

Subjects

*FRACTURE mechanics, *SURFACE cracks, *STRESS concentration, *POROUS polymers, *MOTHER-of-pearl

Abstract

The evolution of natural armor materials has led to gradient structures with specific architectures to achieve high damage tolerance, thus offering valuable inspiration for the design of man‐made materials. Here, bioinspired gradient composites with a nacre‐like brick‐and‐mortar architecture are fabricated by infiltrating a polymer phase into porous ceramic scaffolds with position‐specific ceramic content. These composites demonstrate an integrated structure with notable several‐fold variations in local hardness and modulus across the thickness. The asymmetric mechanical properties and toughening mechanisms of the composites are investigated and compared to those of uniform composites. Specifically, when loaded along the direction of decreasing stiffness – resembling the typical loading configuration of natural armors, the gradient composites exhibit superior damage tolerance compared to the opposite direction and a uniform composite with equivalent ceramic content. This is attributed to the decreased peak stress, broader stress distribution, and increased deformation capacity, along with enhanced toughening effects that impede crack growth through mechanisms of crack deflection, crack bridging by uncracked ligaments, together with their frictional pull‐out from crack surfaces. This study deepens the understanding of the damage tolerance of gradient materials and offers insights for the bioinspired design of highly damage‐tolerant materials. [ABSTRACT FROM AUTHOR]

Published

2024

3. Study on the Effect of Soft–Hard Material Interface Differences on Crack Deflection in Nacre-Inspired Brick-and-Mortar Structures.

Author

Wang, Yifan, Yang, Xiao, Niu, Shichao, Tang, Biao, and Shao, Chun

Subjects

*MOTHER-of-pearl, *FRACTURE toughness

Abstract

Nacre has excellent balanced strength and toughness. In this paper, the mechanical performance of the typical "brick-and-mortar" structure, including the stress–strain and strain at the interface as well as the stress in the bricks, was calculated by a simplified analytical model of the nacre. This paper proposes a new method to control the crack deflection based on the toughening mechanism of the nacre. The crack extension of the "brick-and-mortar" structure was simulated using cohesive elements based on the traction–separation law with elastic and softening stiffness as variables, and it was found that both stiffness could effectively control the crack extension. The strength and toughness of the models with different stiffness combinations were calculated and plotted as a function of elastic stiffness and softening stiffness, showing that elastic stiffness significantly affects strength and softening stiffness is a determinant of toughness. [ABSTRACT FROM AUTHOR]

Published

2024

4. 基于珍珠层和凤凰螺内部结构的混合仿生设计.

Author

侯泽凯, 栾云博, 雷科明, 董前希, 牛途瑶, and 李永存

Subjects

BIOMIMETICS, STRESS concentration, COMPOSITE structures, EPOXY resins, CARBON fibers

Abstract

Copyright of Chinese Journal of High Pressure Physics is the property of Chinese Journal of High Pressure Physics Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

5. Nacreous Glass Composites with Superior Performance Engineered through Mechanical Vibration and Silanization.

Author

Amini, Ali, Tirgar, Pouria, Bahmani, Aram, Jafari, Maziar, Siaj, Mohamed, Barthelat, Francois, and Ehrlicher, Allen

Subjects

*GLASS composites, *VIBRATION (Mechanics), *COMPOSITE materials, *FRACTURE toughness, *SURFACE energy

Abstract

Bioinspiration offers alternative solutions to overcome the inherent drawbacks of glass, such as low fracture toughness, strength, and impact resistance. Synthetic composites inspired by natural materials, such as nacre, have been recently introduced as an alternative to glasses. However, these have all suffered from trade‐offs between rigidity, optical clarity, fabrication scalability, and complexity. Here, two wave‐based fabrication techniques are presented to create a nacreous structure from glass flakes and polymethyl methacrylate. The glass's surface energy is controlled by adjusting the silane coverage on the glass surface, enabling high levels of structural compactness, mechanical properties, and optical clarity. The scalable glass composite, with a ≈60% glass volume fraction, possesses strength, fracture toughness, and impact resistance values, outperforming annealed glass by 4300%, 350%, and 400%, respectively. It also has a haze level of ≈18%, almost 60% less than that of the similar centrifuged‐based glass composite. This composite is proposed as a potential glass alternative in diverse applications. [ABSTRACT FROM AUTHOR]

Published

2024

6. Investigations on compression behavior of fused filament fabricated hybrid biomimetic structures.

Author

Aravind Raj, Sakthivel, Pulinat, Kuruvilla George, Sau, Sumit Kalipada, Moss, Pratik Noel, and Sakthi Balan, Ganapathy

Abstract

The objective of this study is to design a biomimetic hybrid structure inspired by nacre, and conch shells and compare how the compressive characteristics change when key geometric design parameters are varied. Nacre, also known as mother of pearl, has a host of traits, suitable for survival, like its stiffness and strength. Conch, which is a common name for a number of sea snails, possesses a unique cross-lamellar structure which has a tough outer layer to resist penetration from the sharp-toothed attacks of predators, and a nacreous inner layer which can dissipate energy. A novel nacre–conch–nacre inspired sandwich core structure is designed and fabricated with fuse filament fabrication using acrylonitrile styrene acrylate filament according to the ASTM C365 standard for the flatwise compression test of sandwich core structures. Three key design parameters, namely the wall thickness, the thickness between two nacre walls, and the angle of conch were selected and varied to form nine different iterations of this design. An Abaqus finite element analysis was validated by experimental testing using an Instron 8801 servo-hydraulic universal testing machine. The results showed that conch-inspired structures' compression properties depend on wall thickness and angle. The sample with 2 mm wall thickness and 45° conch angle had the highest compressive strength of 3.62 MPa, while the sample with 1 mm wall thickness and 50° conch angle had the lowest at 2.09 MPa. These findings suggest this structure could be used in lightweight armor, car, and aerospace parts. [ABSTRACT FROM AUTHOR]

Published

2024

7. Organic Matrices of Calcium Carbonate Biominerals Improve Osteoblastic Mineralization.

Author

Nahle, Sarah, Lutet-Toti, Camille, Namikawa, Yuto, Piet, Marie-Hélène, Brion, Alice, Peyroche, Sylvie, Suzuki, Michio, Marin, Frédéric, and Rousseau, Marthe

Abstract

Many organisms incorporate inorganic solids into their tissues to improve functional and mechanical properties. The resulting mineralized tissues are called biominerals. Several studies have shown that nacreous biominerals induce osteoblastic extracellular mineralization. Among them, Pinctada margaritifera is well known for the ability of its organic matrix to stimulate bone cells. In this context, we aimed to study the effects of shell extracts from three other Pinctada species (Pinctada radiata, Pinctada maxima, and Pinctada fucata) on osteoblastic extracellular matrix mineralization, by using an in vitro model of mouse osteoblastic precursor cells (MC3T3-E1). For a better understanding of the Pinctada-bone mineralization relationship, we evaluated the effects of 4 other nacreous mollusks that are phylogenetically distant and distinct from the Pinctada genus. In addition, we tested 12 non-nacreous mollusks and one extra-group. Biomineral shell powders were prepared, and their organic matrix was partially extracted using ethanol. Firstly, the effect of these powders and extracts was assessed on the viability of MC3T3-E1. Our results indicated that neither the powder nor the ethanol-soluble matrix (ESM) affected cell viability at low concentrations. Then, we evaluated osteoblastic mineralization using Alizarin Red staining and we found a prominent MC3T3-E1 mineralization mainly induced by nacreous biominerals, especially those belonging to the Pinctada genus. However, few non-nacreous biominerals were also able to stimulate the extracellular mineralization. Overall, our findings validate the remarkable ability of CaCO3 biomineral extracts to promote bone mineralization. Nevertheless, further in vitro and in vivo studies are needed to uncover the mechanisms of action of biominerals in bone. [ABSTRACT FROM AUTHOR]

Published

2024

8. Freezing-derived functional materials.

Author

Miao, Shuangshuang, Wang, Yu, Lu, Minhui, Liu, Xiangdong, Chen, Yongping, and Zhao, Yuanjin

Subjects

*ICE crystals, *BIOMEDICAL engineering, *ENERGY conversion, *ENERGY storage, *CRYSTAL structure

Abstract

This review focus on the current advances of freezing-derived functional materials, involving the design rationale (freezing stratagems and curing methods) of material fabrication and various applications, including mechanical, thermal, energy, environmental, and biomedical applications. The emphasis is put on the correlations among multiscale structures, extraordinary properties and multifarious applications. Promising research directions and challenges about the freezing processing tools are also presented. [Display omitted] Ice-templating, also known as freeze-casting, has emerged as a novel and versatile processing technology in various applications such as strong and tough structured materials, thermal management, energy storage and conversion, biomedical engineering, and so on. By replicating the fractal ice crystal structure, both multiscale hierarchical architectures (from macroscale to micrometer-, and nanometer-scales) and corresponding unique structure-derived functions can be achieved. This review focus on the current advances of freezing-derived functional materials, involving the design rationale (freezing strategies and curing methods) of material fabrication and various applications, including mechanical, thermal, energy, environmental, and biomedical applications. Opportunities (promising research directions and new application scenarios) and challenges about the ice-templating tools are also presented. [ABSTRACT FROM AUTHOR]

Published

2024

9. Transcriptome analysis of mantle and pearl sac of freshwater pearl mussel Lamellidens marginalis to identify biomineralisation-associated genes.

Author

Suman, Sonal, Pavan-Kumar, A., Saurabh, Shailesh, Katneni, Vinaya Kumar, Prabhudas, Sudheesh K., Varshney, Shubham, Pradhan, Sweta, Gireesh-Babu, P., Das, Rekha, and Chaudhari, Aparna

Abstract

The freshwater pearl mussel, Lamellidens marginalis, is widely distributed in India and is cultured for freshwater pearl production. Understanding the biomineralisation process sheds light on the genes responsible for nacre secretion. However, information on the transcriptome of L. marginalis mantle tissue and pearl sac is lacking. This study generated transcriptome resources for L. marginalis, identifying genes involved in biomineralisation. Illumina paired-end sequencing yielded 11.13 million raw reads, assembled into 133,246 contigs and 26,373 unigenes. Of these, 21,033 unigenes exhibited homology with previously reported molluscan proteins. Genes related to biomineralisation, such as pif, perlucin, calreticulin, calmodulin, chitin synthase, chitin dehydrogenase, carbonic anhydrase, tyrosinase, shell matrix protein, dermatopontin isoform X1, chitinase 3, chitinase domain-containing protein 1, and putative chitinase-1were identified. This baseline information will help to compare the expression levels between the phenotypes of high-quality and low-quality pearls. Further investigations, incorporating large sample sizes and phenotype information, could assist in identifying type I genetic markers linked to pearl quality. [ABSTRACT FROM AUTHOR]

Published

2024

10. Converting ocean nacre into bone mineral matrix composite for bone regeneration- in vitro and in vivo studies

Author

Rui Ruan, Behzad Shiroud Heidari, Peilin Chen, Junjie Gao, Ziming Chen, Lianzhi Chen, Euphemie Landao-Bassonga, Yongquan Wang, Lingqiang Chen, Bing Wang, and Minghao Zheng

Subjects

Nacre, Bone substitute, Bioactive calcium-orthophosphates, Biodegradation, Bone defect model, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Nacre of Pinctada maxima is a natural biomineralized matrix, appeared 7 million years before hominins. In this study, we converted nacre into a self-setting particle bound with multiple calcium orthophosphates that reassemble mammals’ bone mineral matrices for induction of bone regeneration. The nacre-based calcium orthophosphates composite (NCOC) exhibited a compression strength of 10 MPa, which is superior to human trabecular bone. In vitro bioactivity tests revealed the formation of apatite with nano-porous flake-like crystals on the composite surface that mimic HA structure of a human bone matrix. NCOC demonstrated efficient attachment and proliferation of osteoblast cells, promoting osteogenic differentiation by increasing expressions of RUNX2 and OPN. In vivo studies using rabbit back fascia demonstrated that NCOC displays better bone healing and biocompatibility than conventional bone substitute apatite in critical bone defect models. The degradation of calcium carbonate crystal in vivo does not compromise structural integrity of NCOC. Overall, our data showed that NCOC produced through self-setting reactions, presents advantages such as accelerated biodegradation and osteostimulative properties, making it a promising bone substitute for effective bone regeneration.

Published

2024

11. New material connections in a mother-of-pearl Enconchado from the Viceroyalty of New Spain

Author

Avalon H. Dismukes, José L. Lazarte, and Silvia A. Centeno

Subjects

Enconchado, Viceregal paintings, Miguel González, Mother-of-pearl, Nacre, Pre-Hispanic shell processing, Fine Arts, Analytical chemistry, QD71-142

Abstract

Abstract Adoration of the Magi (ca. 1695–1700), an enconchado painting attributed to Miguel González, active in Mexico in the late seventeenth century, exemplifies the refinement of the arts produced in Spanish America as a response to the taste for Asian goods during the seventeenth and eighteenth centuries. The painting and its original mother-of-pearl inlaid frame were examined and analyzed using non-invasive and micro-sampling methods, an approach that permitted answering outstanding questions about the stratigraphy, pigments, and the use of shells throughout the painting and frame. The identification of the mother-of-pearl, determined to be from a Pinctada species, was a central focus of this study. In addition to the inlaid shells in the painting and frame, shell fragments were observed mixed with gypsum in the ground preparation of the painting by SEM–EDS. To our knowledge, this is a novel identification of marine shells in the ground of an easel painting. Traces of workmanship in the inlaid shells observed by SEM and optical microscopy are possibly connected to pre-Hispanic methodologies of mother-of-pearl refinement. Graphical Abstract

Published

2024

12. Study on the Effect of Soft–Hard Material Interface Differences on Crack Deflection in Nacre-Inspired Brick-and-Mortar Structures

Author

Yifan Wang, Xiao Yang, Shichao Niu, Biao Tang, and Chun Shao

Subjects

nacre, interface, fracture toughness, cohesive, Technology

Abstract

Nacre has excellent balanced strength and toughness. In this paper, the mechanical performance of the typical “brick-and-mortar” structure, including the stress–strain and strain at the interface as well as the stress in the bricks, was calculated by a simplified analytical model of the nacre. This paper proposes a new method to control the crack deflection based on the toughening mechanism of the nacre. The crack extension of the “brick-and-mortar” structure was simulated using cohesive elements based on the traction–separation law with elastic and softening stiffness as variables, and it was found that both stiffness could effectively control the crack extension. The strength and toughness of the models with different stiffness combinations were calculated and plotted as a function of elastic stiffness and softening stiffness, showing that elastic stiffness significantly affects strength and softening stiffness is a determinant of toughness.

Published

2024

13. Structure and Composition of Mantle Tissue from Red Abalone Haliotis rufescens, with Implications for Pearl Farming.

Author

Sáez-Saavedra, Camila, Saucedo, Pedro E., Granados-Amores, Andrés, Rojas-Figueroa, Alejandro, Tanguy, Arnaud, and Araya, Rubén

Abstract

The structure and composition of mantle tissue from red abalone Haliotis rufescens were studied in relation to pearl farming. Histological (hematoxylin-eosin) and histochemical (PAS Alcian Blue, Sudan Black, Dahl's) tools were used to determine variations in the glycogen index, lipid index, and calcium coverage index of mantle tissue as a function of seasonality (cold and warm period) and body region (dorsal, central, ventral). Anatomically, only two well-developed and functional mantle folds (inner and outer) were observed across the marginal zone, together with a poorly developed, and presumably, rudimentary fold with the same cellular morphology as the inner fold. The inner mantle epithelium stored significantly higher concentrations of glycogen and mucins, triglycerides, and calcium than the outer epithelium. This pattern occurred significantly more during the cold season than during the warm season. Mucins from mantle tissue not only regulate crystal nucleation and orientation during biomineralization, but also give the inner nacreous layer its luster and color. High concentrations of lipids in mantle tissue could help compensate for the energy loss caused by the wound-healing processes associated with mantle tissue removal and seeding, which are stressful and energetically costly. The absorption of calcium ions from the environment to integrate a microlaminate of calcareous compounds gives the shell its structural properties of hardness and strength. An approach with molecular-ultrastructural tools is recommended to broaden the understanding of mantle tissue regionalization and its relationship to pearl sac formation, which may help increase pearl yield and quality in H. rufescens. [ABSTRACT FROM AUTHOR]

Published

2024

14. New material connections in a mother-of-pearl Enconchado from the Viceroyalty of New Spain

Author

Dismukes, Avalon H., Lazarte, José L., and Centeno, Silvia A.

Published

2024

15. Scalable Production of Robust and Tough Biomimetic Composite by Rapid In‐Situ Mineralization.

Author

Qiu, Zhe, Lang, Lizhong, Yu, Zhengyang, Zhu, Jiaying, Ye, Yuhang, Zou, Yu, Xie, Yanjun, and Jiang, Feng

Subjects

*STRUCTURAL engineering, *MOTHER-of-pearl, *BENDING strength, *MINERALIZATION, *STRUCTURAL engineers, *BIOMIMETIC materials

Abstract

Nacre‐inspired materials with combined high strength and toughness have been widely developed and utilized for various engineering applications. However, existing preparation techniques suffer from intricate processes, high energy‐consumption, and lack of scalability, all of which collectively impede the efficient production of three‐dimensional materials. Here, a viable strategy is reported for the efficient and scalable production of bulk nacre‐mimetic materials, drawing inspiration from the intricate structures found in both nacre and wood. The prepared millimeter‐thick wooden artificial nacres (WANs) exhibit the presence of multi‐hierarchical lamellar structures, organic bridges, and micro‐asperities. Those features lead to the WANs exhibiting impressive mechanical performances, presenting excellent bending strength (≈93.31 MPa), toughness (≈7.40 MPa m1/2), tensile strength (≈122.59 MPa), and work of fracture (≈4.61 MJ m−3). In addition, owing to the low density (≈1.59 g cm−3), the WANs show much higher specific mechanical properties compared to nacre and related artificial nacre materials. Considering both its production process and exceptional properties, this material holds great promise for practical applications within the realm of engineering and structural fields. [ABSTRACT FROM AUTHOR]

Published

2024

16. Tensile properties of SiC/AZ31 inverse nacre structured composite

Author

HE Bo, LUO Xi, CHANG Chao, ZHAO Ke, and LIU Jinling

Subjects

magnesium matrix nanocomposites, nacre, architecture, strength, toughness, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

SiC/AZ31 inverse nacre structured composite was prepared by mechanical ball milling and thermal deformation, and the microstructure of the composite was effectively controlled by process control. The microstructure was characterized by X-ray diffraction（XRD）and scanning electron microscopy（SEM）, the mechanical properties of the material were tested by quasi-static tensile test, and the strengthening and toughening mechanism and failure mechanism were preliminarily analyzed by combining the microstructure. The results show that the inverse nacre structure obtained by hot deformation process can significantly improve the tensile properties. When the strain hardening ability of the matrix in the inverse nacre structured composite is improved, it can better compensate for the softening effect caused by crack propagation in the hard phase, and the strain hardening ability of the composite is improved. The tensile properties can be controlled by adjusting the size of the lamellar soft phase in the inverse nacre structured composite. When the size of lamellar soft phase is large, the composite has better toughness. When the size of lamellar soft phase is small, the composite has higher strength. The excellent strength and toughness of the inverse nacre structure composite are arising from its structural characteristics, and the continuous hard phase plays a good role in bearing, while the dispersed lamellar soft phase benefits for improving the toughness of the composite. The main strengthening mechanisms of this material include dispersion strengthening, fine grain strengthening, and heterogeneous deformation induced strengthening, and the improvement of toughness are attributed to the crack blunting and deflection induced by lamellar soft phase. In summary, the architecture design of inverse nacre structure is an effective way to obtain high-strength and tough magnesium matrix composite.

Published

2023

17. Bioinspired Design Rules from Highly Mineralized Natural Composites for Two-Dimensional Composite Design.

Author

Prasad, Anamika, Varshney, Vikas, Nepal, Dhriti, and Frank, Geoffrey J.

Subjects

*BIOLOGICALLY inspired computing, *MACHINE learning, *MULTISCALE modeling, *MEDICAL electronics, *BIOSENSORS, *MACHINE design

Abstract

Discoveries of two-dimensional (2D) materials, exemplified by the recent entry of MXene, have ushered in a new era of multifunctional materials for applications from electronics to biomedical sensors due to their superior combination of mechanical, chemical, and electrical properties. MXene, for example, can be designed for specialized applications using a plethora of element combinations and surface termination layers, making them attractive for highly optimized multifunctional composites. Although multiple critical engineering applications demand that such composites balance specialized functions with mechanical demands, the current knowledge of the mechanical performance and optimized traits necessary for such composite design is severely limited. In response to this pressing need, this paper critically reviews structure–function connections for highly mineralized 2D natural composites, such as nacre and exoskeletal of windowpane oysters, to extract fundamental bioinspired design principles that provide pathways for multifunctional 2D-based engineered systems. This paper highlights key bioinspired design features, including controlling flake geometry, enhancing interface interlocks, and utilizing polymer interphases, to address the limitations of the current design. Challenges in processing, such as flake size control and incorporating interlocking mechanisms of tablet stitching and nanotube forest, are discussed along with alternative potential solutions, such as roughened interfaces and surface waviness. Finally, this paper discusses future perspectives and opportunities, including bridging the gap between theory and practice with multiscale modeling and machine learning design approaches. Overall, this review underscores the potential of bioinspired design for engineered 2D composites while acknowledging the complexities involved and providing valuable insights for researchers and engineers in this rapidly evolving field. [ABSTRACT FROM AUTHOR]

Published

2023

18. The Use of Shells of Marine Molluscs in Spanish Ethnomedicine: A Historical Approach and Present and Future Perspectives.

Author

González, José A. and Vallejo, José Ramón

Subjects

*SEASHELLS, *TRADITIONAL medicine, *MOTHER-of-pearl, *MOLLUSKS, *DENTAL hygiene, *BREAST, *HISTORY of medicine

Abstract

Since ancient times, the shells of marine molluscs have been used as a therapeutic and/or prophylactic resource. In Spain, they were part of practical guides for doctors or pharmacists until the 19th century. In general, seashells were prepared by dissolving in vinegar and were part of plasters or powders used as toothpaste, or to treat dyspepsia, heartburn and leprosy. Thus, the nacre or mother-of-pearl of various molluscs was regularly used in the Royal Colleges of Surgery and in hospitals during the times of the Cortes of Cadiz, as a medicine in galenic preparations based on powders. In contemporary Spanish ethnomedicine, seashells, with a high symbolic value, have been used as an amulet to prevent cracks in the breasts and promote their development during lactation, to avoid teething pain in young children, to eliminate stains on the face or to cure erysipelas. But, as in other countries, products derived from seashells have also been empirically applied. The two resources used traditionally have been the cuttlebone, the internal shell of cuttlefish and the nacre obtained from the external shells of some species. Cuttlebone, dried and pulverised, has been applied externally to cure corneal leukoma and in dental hygiene. In the case of nacre, a distinction must be made between chemical and physical remedies. Certain seashells, macerated in lemon juice, were used in coastal areas to remove spots on the face during postpartum. However, the most common practice in Spain mainland was to dissolve mother-of-pearl buttons in lemon juice (or vinegar). The substance thus obtained has been used to treat different dermatological conditions of the face (chloasma, acne), as well as to eliminate freckles. For the extraction of foreign bodies in the eyes, a very widespread traditional remedy has been to introduce small mother-of-pearl buttons under the lid. These popular remedies and practices are compared with those collected in classic works of medicine throughout history, and data on the pharmacological activity and pharmaceutical applications of the products used are provided. The use of cuttlebone powders is supported by different works on anti-inflammatory, immune-modulatory and/or wound healing properties. Nacre powder has been used in traditional medicines to treat palpitations, convulsions or epilepsy. As sedation and a tranquilisation agent, nacre is an interesting source for further drug development. Likewise, nacre is a biomaterial for orthopaedic and other tissue bioengineering applications. This article is a historical, cultural and anthropological view that can open new epistemological paths in marine-derived product research. [ABSTRACT FROM AUTHOR]

Published

2023

19. Anisotropic Mechanical Response of Nacre to Heat Treatment Under Indentation: Effect of Structural Orientation

Author

Liang, Simin, Li, Yingying, Ji, Hongmei, and Li, Xiaowu

Published

2024

20. Reinforcement learning design framework for nacre-like structures optimized for pre-existing crack resistance

Author

Bor-Yann Tseng, You-Cheng Cai, Chen-Wei Conan Guo, Elena Zhao, and Chi-Hua Yu

Subjects

Nacre, Bioinspired structural materials, Artificial intelligence, Reinforcement learning, Structural material design, Mining engineering. Metallurgy, TN1-997

Abstract

Nacre is known for its uniquely high toughness and lightweight capabilities. Its unique structure is composed of soft nacre proteins and stiff calcium carbonates, allowing it to deflect cracks that expand in straight lines to increase energy dissipation. However, nacre microstructures are challenging to mimic due to the intractable number of combinations in the design space. We thus propose a reinforcement learning (RL) framework to efficiently design a high-toughness nacre-like structure. By designing local structures at the crack tip, we incorporated reinforcement learning with finite element to optimize the structure by replacing the soft and stiff materials in the design space. Starting from the initial unit cell, where the majority of the unit cell consists of soft materials, our method gradually improves the cell by arranging stiff and soft materials on the unit cell to achieve higher toughness. The optimized designs exhibit crack-insensitive behavior and excellent crack resistance when subjected to finite element simulation and experimental testing. This design framework can be used in synthetic instruments that require rapid construction rearrangements such as biomaterials and unexposed substructures, increasing their mechanical performance.

Published

2023

21. Dietary supplementation with nacre reduces cortical bone loss in aged female mice

Author

Dung Kim Nguyen, Arnaud Vanden-Bossche, Norbert Laroche, Mireille Thomas, Marie-Thérèse Linossier, Sylvie Peyroche, Delphine Farlay, Hélène Follet, Patrice Laquerrière, Marie-Hélène Lafage-Proust, Thierry Thomas, Laurence Vico, Hubert Marotte, and Marthe Rousseau

Subjects

Osteoporosis, Aging, Bone, Nacre, Animal experimentation, Medicine, Biology (General), QH301-705.5

Abstract

Aging is associated with detrimental bone loss leading to fragility fractures in both men and women. Notably, a majority of bone loss with aging is cortical, as well as a large number of fractures are non-vertebral and at the non-hip sites. Nacre is a product of mollusks composed of calcium carbonate embedded in organic components. As our previous study demonstrated the protective effect of nacre supplementation on trabecular bone loss in ovariectomized rats, we sought to evaluate the effect of dietary nacre on bone loss related to aging in female mice which do not suffer true menopause as observed in women. The current study compared the effect of a 90-day long nacre-supplemented diet to that of Standard or CaCO3 diets on both bone mass and strength in 16-month-old C57BL/6 female mice. Multiple approaches were performed to assess the microarchitecture and mechanical properties of long bones, analyze trabecular histomorphometry, and measure bone cell-related gene expressions, and bone turnover markers. In the cortex, dietary nacre improved cortical bone strength in line with lower expression levels of genes reflecting osteoclasts activity compared to Standard or CaCO3 diets (p

Published

2023

22. Structural and biological characterization of two freshwater mussel shells (Bivalvia: Unionidae).

Author

ŞEREFLİŞAN, Hülya

Subjects

*SEASHELLS, *FRESHWATER mussels, *UNIONIDAE, *BIVALVE shells, *BIOMATERIALS, *BIVALVES, *MOLLUSKS

Abstract

The shell of a freshwater mussel (Mollusca: Bivalvia) is a composite biological material that plays an active role in maintaining ecosystem services. Mussel shells have variable structures both within and between species. In this study, the structural and biological characteristics of the shells of Potomida semirugata and Leguminaia wheatleyi were investigated in order to use freshwater mussel shells as a biological material. Close observation of the microstructure of the shells of the two common freshwater bivalves revealed a variation in construction from the outer periostracum to the inner nacreous layer. In P. semirugata, a polygonal arrangement with columnar prisms of different sizes was observed more significantly. In L. wheatleyi the prismatic columns are oval and irregularly polygonal. The nacreous layers of P. semirugata, in which the individual aragonite layers are horizontally overlapped, are more uniformly distributed. The overlapping of the aragonite sheets in L. wheatleyi is more irregular. The presence of calcium carbonate (CaCO3) in the shells was confirmed by the identification of the characteristic carbonate bands at 701.9, 713.5, and 865.8 cm-1. This information was used to classify and distinguish the different layers of the shells, allowing interspecific comparisons and variations in the different layers. The results clearly showed that shell samples were highly biocompatible and nontoxic compared to the control group. This finding suggests that these materials have promising potential for use in various biomedical applications where biocompatibility is a critical factor. The results indicated that the shells of the freshwater bivalves P. semirugata and L. wheatleyi are biological materials with potential multiple applications for human well-being and environmental quality. [ABSTRACT FROM AUTHOR]

Published

2023

23. Geochemical and mineralogical proxies beyond temperature: Autumn seasons trapped in freshwater nacre.

Author

Farfan, Gabriela A., Bullock, Emma S., Zhou, Chunhui, and Valley, John W.

Subjects

*AUTUMN, *MOTHER-of-pearl, *FRESH water, *WATER temperature, *SPRING, *SPECTROSCOPIC imaging, *ENVIRONMENTAL geochemistry, *WINTER

Abstract

Measurements of trace element chemistry, mineralogy, and isotope geochemistry are rarely combined with known environmental data to provide a more complete story about how environmental conditions are recorded in biomineral carbonates. Here, cultured (farmed) pearls serve as relatively pristine time capsules to study these geochemical and mineral-based proxies. Cathodoluminescence (CL) imaging and Raman spectroscopic mapping on the µm-scale reveals that heterogeneous crystal bonding environments, geochemistry, and organic contents across the growth history of a freshwater pearl reflect environmental shifts in Kentucky Lake, TN, USA. A major CL peak at 551 nm aligns with increased manganese and organic contents and correlates with lake conductivity and alkalinity data. These CL features are temporally offset from previous 10-µm-scale aragonite nacre oxygen isotope measurements (δ18O Arg) that record periods of minimum lake temperatures in winter seasons. Thus, we suggest that these trace element and organic features represent autumn or spring rainy seasons that experience lake turnover events and more land runoff rich in Mn and nutrients, increasing aragonite-bound Mn and organic contents in the nacre. This 551 nm signal is absent in Mn-poor saltwater pearl nacre. A second CL peak at 444 nm shows different heterogeneous features likely due to crystal structure shifts, as evidenced by correlations to a Raman map of translational (T): librational (L) mode height ratios typically signaling changes in nacre tablet orientation. Thus, we show that µm-scale CL and Raman mapping may serve as complementary environmental proxies to novel SIMS-based δ18O Arg temperature proxies in order to capture additional information about local lake environments at seasonal to sub-seasonal temporal resolutions. [ABSTRACT FROM AUTHOR]

Published

2023

24. Biomimetic Nacre-like Hydroxyapatite/Polymer Composites for Bone Implants.

Author

Tabrizian, Parinaz, Sun, Huijun, Jargalsaikhan, Urangua, Sui, Tan, Davis, Sean, and Su, Bo

Subjects

HYDROXYAPATITE, BIOMIMETIC materials, METHYL methacrylate, POLYMERS, ACRYLIC acid, SEASHELLS, YOUNG'S modulus

Abstract

One of the most ambitious goals for bone implants is to improve bioactivity, incapability, and mechanical properties; to reduce the need for further surgery; and increase efficiency. Hydroxyapatite (HA), the main inorganic component of bones and teeth, has high biocompatibility but is weak and brittle material. Cortical bone is composed of 70% calcium phosphate (CaP) and 30% collagen and forms a complex hierarchical structure with anisotropic and lamellar microstructure (osteons) which makes bone a light, strong, tough, and durable material that can support large loads. However, imitation of concentric lamellar structure of osteons is difficult to achieve in fabrication. Nacre from mollusk shells with layered structures has now become the archetype of the natural "model" for bio-inspired materials. Incorporating a nacre-like layered structure into bone implants can enhance their mechanical strength, toughness, and durability, reducing the risk of implant catastrophic failure or fracture. The layered structure of nacre-like HA/polymer composites possess high strength, toughness, and tunable stiffness which matches that of bone. The nacre-like HA/polymer composites should also possess excellent biocompatibility and bioactivity which facilitate the bonding of the implant with the surrounding bone, leading to improved implant stability and long-term success. To achieve this, a bi-directional freeze-casting technique was used to produce elongated lamellar HA were further densified and infiltrated with polymer to produce nacre-like HA/polymer composites with high strength and fracture toughness. Mechanical characterization shows that increasing the ceramic fractions in the composite increases the density of the mineral bridges, resulting in higher flexural and compressive strength. The nacre-like HA/(methyl methacrylate (MMA) + 5 wt.% acrylic acid (AA)) composites with a ceramic fraction of 80 vol.% showed a flexural strength of 158 ± 7.02 MPa and a Young's modulus of 24 ± 4.34 GPa, compared with 130 ± 5.82 MPa and 19.75 ± 2.38 GPa, in the composite of HA/PMMA, due to the higher strength of the polymer and the interface of the composite. The fracture toughness in the composition of 5 wt.% PAA to PMMA improves from 3.023 ± 0.98 MPa·m1/2 to 5.27 ± 1.033 MPa·m1/2 by increasing the ceramic fraction from 70 vol.% to 80 vol.%, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

25. 珍珠层成骨活性物质的研究进展.

Author

刘琳 徐普

Abstract

Osteoporosis is a systemic bone disease characterized by low bone mass and micro- architectural change of bone tissue, leading to an increased bone fragility which can lead to secondary fractures. It has become one of the major factors affecting the quality of life in recent years, especially for the elderly. Currently, treatment drugs have problems with their efficacy and long-term use. Nacre contains osteogenic active substances, which has the potential to be used in osteoporosis and other bone diseases. The characteristics, extraction, and osteogenesis of active components in nacre are reviewed in this paper. [ABSTRACT FROM AUTHOR]

Published

2023

26. Role of Nacre and Biodentine to Inducing the TGF-β1 in the Dentin Tertiary Formation on the Pulpitis Reversible of Rattus norvegicus

Author

Marpaung, Yeamy Agustina, Abidin, Trimurni, Ilyas, Syafruddin, Nainggolan, Irwana, and Gani, Basri A.

Published

2022

27. A Numerical Modelling Framework for Investigating the Ballistic Performance of Bio-Inspired Body Armours.

Author

Ghazlan, Abdallah, Ngo, Tuan, Tan, Ping, Tran, Phuong, and Xie, Yi Min

Subjects

*BALLISTIC missile defenses, *BODY armor, *PROJECTILES, *FINITE element method, *COMPUTER simulation

Abstract

Biological structures possess excellent damage tolerance, which makes them attractive for ballistic protection applications. This paper develops a finite element modelling framework to investigate the performance of several biological structures that are most relevant for ballistic protection, including nacre, conch, fish scales, and crustacean exoskeleton. Finite element simulations were conducted to determine the geometric parameters of the bio-inspired structures that can survive projectile impact. The performances of the bio-inspired panels were benchmarked against a monolithic panel with the same 4.5 mm overall thickness and projectile impact condition. It was found that the biomimetic panels that were considered possessed better multi-hit resistant capabilities compared to the selected monolithic panel. Certain configurations arrested a fragment simulating projectile with an initial impact velocity of 500 m/s, which was similar to the performance of the monolithic panel. [ABSTRACT FROM AUTHOR]

Published

2023

28. miR-10a-3p Participates in Nacre Formation in the Pearl Oyster Pinctada fucata martensii by Targeting NPY.

Author

Yang, Min, Li, Xin lei, Zhang, Yu ting, Deng, Yue wen, and Jiao, Yu

Abstract

MicroRNAs (miRNAs) are small noncoding RNAs that regulate gene expression via the recognition of their target messenger RNAs. MiR-10a-3p plays an important role in the process of ossification. In this study, we obtained the precursor sequence of miR-10a-3p in the pearl oyster Pinctada fucata martensii (Pm-miR-10a-3p) and verified its sequence by miR-RACE technology, and detected its expression level in the mantle tissues of the pearl oyster P. f. martensii. Pm-nAChRsα and Pm-NPY were identified as the potential target genes of Pm-miR-10a-3p. After the over-expression of Pm-miR-10a-3p, the target genes Pm-nAChRsα and Pm-NPY were downregulated, and the nacre microstructure became disordered. The Pm-miR-10a-3p mimic obviously inhibited the luciferase activity of the 3′ untranslated region of the Pm-NPY gene. When the interaction site was mutated, the inhibitory effect disappeared. Our results suggested that Pm-miR-10a-3p participates in nacre formation in P. f. martensii by targeting Pm-NPY. This study can expand our understanding of the mechanism of biomineralization in pearl oysters. [ABSTRACT FROM AUTHOR]

Published

2023

29. Investigation of the structure and hardness properties of Anodonta anatina mussel shells.

Author

Öksüz, Kerim Emre and Şereflişan, Hülya

Subjects

SEASHELLS, HARDNESS, BIOMATERIALS, MUSSELS, FRESHWATER mussels

Abstract

Copyright of Ege Journal of Fisheries & Aquatic Sciences (EgeJFAS) / Su Ürünleri Dergisi is the property of Ege Journal of Fisheries & Aquatic Sciences (EgeJFAS) / Su Urunleri Dergisi and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

30. Distinct impacts of growth band on the mechanical properties of abalone nacre under compressive and tensile stresses

Author

S.M. Liang, H.M. Ji, and X.W. Li

Subjects

Abalone shell, Nacre, Growth band, Compressive behavior, Three-point bending behavior, Kink band, Mining engineering. Metallurgy, TN1-997

Abstract

In abalone nacre, growth bands occur periodically with the change of living environments. To explore the specific role of growth bands playing in the mechanical properties of nacre, the compressive and three-point bending behaviors of composites with growth bands in green abalone shell and pure nacre without growth bands in whitened ear abalone shell were comparatively investigated. It is found that the mechanical effects of growth bands under different stress states are significantly distinct, mainly attributing to the different responses of organic matrix interlayer in growth bands. Specifically, due to the remarkable ductility of thicker organic matrix interlayer under the action of compressive stress, the growth bands could be bent without fracturing in the region of kink band. However, the existence of growth bands leads to a lower interfacial strength, finally causing the fact that the composites with growth bands exhibit a lower strength but a higher toughness than pure nacre under uniaxial compression tests. Contrastively, both the strength and toughness of the composites are lower than those of pure nacre under three-point bending tests, since micro-cracks will be first initiated in growth bands on account of the weaker organic matrix interlayer under tensile stress. Therefore, the growth bands actually play different roles in the mechanical performances of nacre under compressive and tensile stresses.

Published

2022

31. Review of Artificial Nacre for Oil–Water Separation.

Author

Khayrani, Apriliana Cahya, Sambudi, Nonni Soraya, Wijaya, Hans, Buys, Yose Fachmi, Radini, Fitri Ayu, Jusoh, Norwahyu, Kamal, Norashikin Ahmad, and Suhaimi, Hazwani

Subjects

*MOTHER-of-pearl, *COMPOSITE membranes (Chemistry), *OIL spill cleanup, *WASTEWATER treatment, *INORGANIC polymers

Abstract

Due to their extraordinary prospective uses, particularly in the areas of oil–water separation, underwater superoleophobic materials have gained increasing attention. Thus, artificial nacre has become an attractive candidate for oil–water separation due to its superhydrophilicity and underwater superoleophobicity properties. Synthesized artificial nacre has successfully achieved a high mechanical strength that is close to or even surpasses the mechanical strength of natural nacre. This can be attributed to suitable synthesis methods, the selection of inorganic fillers and polymer matrices, and the enhancement of the mechanical properties through cross-linking, covalent group modification, or mineralization. The utilization of nacre-inspired composite membranes for emerging applications, i.e., is oily wastewater treatment, is highlighted in this review. The membranes show that full separation of oil and water can be achieved, which enables their applications in seawater environments. The self-cleaning mechanism's basic functioning and antifouling tips are also concluded in this review. [ABSTRACT FROM AUTHOR]

Published

2023

32. Nacre-inspired hierarchical bionic substrate for enhanced thermal and mechanical stability in flexible applications.

Author

Sun, Baichuan, Xu, Gaobin, Guan, Cunhe, Ji, Xu, Yang, Zhaohui, Chen, Shirong, Chen, Xing, Ma, Yuanming, Yu, Yongqiang, and Feng, Jianguo

Subjects

*ELASTIC modulus, *FLEXIBLE electronics, *BIOMIMETICS, *SUBSTRATES (Materials science), *DIFFERENTIAL scanning calorimetry

Abstract

Flexible substrates, essential for flexible electronics by providing support and flexibility while influencing sensor stability, still face challenges in achieving mechanical and thermal stability, particularly in large-scale production and cost control. Inspired by the nacre's "brick-and-mortar" hierarchical microstructure, this study introduces PPSN (paper/polydimethylsiloxane (PDMS)/Si₃N₄ nanoparticles), a novel flexible substrate that mimics the "brick-and-mortar" structure. PPSN, with its topological interlocking and assembly technique, provides excellent thermal and mechanical stability, including high-temperature resistance and stress dissipation. An optimized Si₃N₄ content of 1.0 wt% yields a peak elastic modulus of 1245.27 MPa while maintaining hydrophobicity, with a contact angle of 127.1° at 3.0 wt%. The substrate shows excellent fatigue durability, retaining its morphology after 10,000 bending cycles. Thermal analysis indicates a stable CTE below 20 ppm/°C up to 300°C, rising to 200 ppm/°C between 350 and 400°C. Differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA) reveal minimal thermal decomposition with mass loss below 0.5 % from 25 to 300°C and under 3 % at 400°C. Additionally, electrodes were printed on the substrate using screen printing and ion beam deposition (IBD), demonstrating good material adhesion. A flexible temperature sensor was fabricated and exhibited good sensitivity and stability with a TCR of −0.262 % °C⁻¹. PPSN advances traditional materials with superior mechanical strength, thermal stability, and durability, offering significant scientific and practical value for flexible electronics and low-cost biomimetic processes. [Display omitted] • PPSN mimics nacre's structure, offering high thermal and mechanical stability. • Peak elastic modulus at 1.0 wt% Si₃N₄, with hydrophobicity and durability. • Stable CTE below 20 ppm/°C up to 300°C with minimal thermal mass loss. • Excellent performance in flexible sensors with a TCR of −0.262 % °C⁻¹. [ABSTRACT FROM AUTHOR]

Published

2024

33. The Use of Shells of Marine Molluscs in Spanish Ethnomedicine: A Historical Approach and Present and Future Perspectives

Author

José A. González and José Ramón Vallejo

Subjects

cuttlebone, nacre, seashells, Spanish ethnomedicine, historical data, pharmacology, Medicine, Pharmacy and materia medica, RS1-441

Abstract

Since ancient times, the shells of marine molluscs have been used as a therapeutic and/or prophylactic resource. In Spain, they were part of practical guides for doctors or pharmacists until the 19th century. In general, seashells were prepared by dissolving in vinegar and were part of plasters or powders used as toothpaste, or to treat dyspepsia, heartburn and leprosy. Thus, the nacre or mother-of-pearl of various molluscs was regularly used in the Royal Colleges of Surgery and in hospitals during the times of the Cortes of Cadiz, as a medicine in galenic preparations based on powders. In contemporary Spanish ethnomedicine, seashells, with a high symbolic value, have been used as an amulet to prevent cracks in the breasts and promote their development during lactation, to avoid teething pain in young children, to eliminate stains on the face or to cure erysipelas. But, as in other countries, products derived from seashells have also been empirically applied. The two resources used traditionally have been the cuttlebone, the internal shell of cuttlefish and the nacre obtained from the external shells of some species. Cuttlebone, dried and pulverised, has been applied externally to cure corneal leukoma and in dental hygiene. In the case of nacre, a distinction must be made between chemical and physical remedies. Certain seashells, macerated in lemon juice, were used in coastal areas to remove spots on the face during postpartum. However, the most common practice in Spain mainland was to dissolve mother-of-pearl buttons in lemon juice (or vinegar). The substance thus obtained has been used to treat different dermatological conditions of the face (chloasma, acne), as well as to eliminate freckles. For the extraction of foreign bodies in the eyes, a very widespread traditional remedy has been to introduce small mother-of-pearl buttons under the lid. These popular remedies and practices are compared with those collected in classic works of medicine throughout history, and data on the pharmacological activity and pharmaceutical applications of the products used are provided. The use of cuttlebone powders is supported by different works on anti-inflammatory, immune-modulatory and/or wound healing properties. Nacre powder has been used in traditional medicines to treat palpitations, convulsions or epilepsy. As sedation and a tranquilisation agent, nacre is an interesting source for further drug development. Likewise, nacre is a biomaterial for orthopaedic and other tissue bioengineering applications. This article is a historical, cultural and anthropological view that can open new epistemological paths in marine-derived product research.

Published

2023

34. Bioinspired Design Rules from Highly Mineralized Natural Composites for Two-Dimensional Composite Design

Author

Anamika Prasad, Vikas Varshney, Dhriti Nepal, and Geoffrey J. Frank

Subjects

MXene, 2D materials, bioinspired design, nacre, biomimetic mineralization, multiscale modeling, Technology

Abstract

Discoveries of two-dimensional (2D) materials, exemplified by the recent entry of MXene, have ushered in a new era of multifunctional materials for applications from electronics to biomedical sensors due to their superior combination of mechanical, chemical, and electrical properties. MXene, for example, can be designed for specialized applications using a plethora of element combinations and surface termination layers, making them attractive for highly optimized multifunctional composites. Although multiple critical engineering applications demand that such composites balance specialized functions with mechanical demands, the current knowledge of the mechanical performance and optimized traits necessary for such composite design is severely limited. In response to this pressing need, this paper critically reviews structure–function connections for highly mineralized 2D natural composites, such as nacre and exoskeletal of windowpane oysters, to extract fundamental bioinspired design principles that provide pathways for multifunctional 2D-based engineered systems. This paper highlights key bioinspired design features, including controlling flake geometry, enhancing interface interlocks, and utilizing polymer interphases, to address the limitations of the current design. Challenges in processing, such as flake size control and incorporating interlocking mechanisms of tablet stitching and nanotube forest, are discussed along with alternative potential solutions, such as roughened interfaces and surface waviness. Finally, this paper discusses future perspectives and opportunities, including bridging the gap between theory and practice with multiscale modeling and machine learning design approaches. Overall, this review underscores the potential of bioinspired design for engineered 2D composites while acknowledging the complexities involved and providing valuable insights for researchers and engineers in this rapidly evolving field.

Published

2023

35. Tensile and Viscoelastic Behavior in Nacre-Inspired Nanocomposites: A Coarse-Grained Molecular Dynamics Study.

Author

Singh, Param Punj and Ranganathan, Raghavan

Subjects

*MOLECULAR dynamics, *MORTAR, *SEASHELLS, *NANOCOMPOSITE materials, *MOTHER-of-pearl, *TENSILE strength

Abstract

Organisms hold an extraordinarily evolutionary advantage in forming complex, hierarchical structures across different length scales that exhibit superior mechanical properties. Mimicking these structures for synthesizing high-performance materials has long held a fascination and has seen rapid growth in the recent past thanks to high-resolution microscopy, design, synthesis, and testing methodologies. Among the class of natural materials, nacre, found in mollusk shells, exhibits remarkably high mechanical strength and toughness. The highly organized "brick and mortar" structure at different length scales is a basis for excellent mechanical properties and the capability to dissipate energy and propagation in nacre. Here, we employ large-scale atomistic coarse-grained molecular dynamics simulations to study the mechanical and viscoelastic behavior of nacre-like microstructures. Uniaxial tension and oscillatory shear simulations were performed to gain insight into the role of complex structure-property relationships. Specifically, the role played by the effect of microstructure (arrangement of the crystalline domain) and polymer-crystal interactions on the mechanical and viscoelastic behavior is elucidated. The tensile property of the nanocomposite was seen to be sensitive to the microstructure, with a staggered arrangement of the crystalline tablets giving rise to a 20–30% higher modulus and lower tensile strength compared to a columnar arrangement. Importantly, the staggered microstructure is shown to have a highly tunable mechanical behavior with respect to the polymer-crystal interactions. The underlying reasons for the mechanical behavior are explained by showing the effect of polymer chain mobility and orientation and the load-carrying capacity for the constituents. Viscoelastic responses in terms of the storage and loss moduli and loss tangent are studied over three decades in frequency and again highlight the differences brought about by the microstructure. We show that our coarse-grained models offer promising insights into the design of novel biomimetic structures for structural applications. [ABSTRACT FROM AUTHOR]

Published

2022

36. Organic Matrix and Secondary Metabolites in Nacre.

Author

de Muizon, Capucine Jourdain, Iandolo, Donata, Nguyen, Dung Kim, Al-Mourabit, Ali, and Rousseau, Marthe

Abstract

Nacre, also called mother-of-pearl, is a naturally occurring biomineral, largely studied by chemists, structural biologists, and physicists to understand its outstanding and diverse properties. Nacre is constituted of aragonite nanograins surrounded by organic matrix, and it has been established that the organic matrix is responsible for initiating and guiding the biomineralization process. The first challenge to study the organic matrix of nacre lays in its separation from the biomineral. Several extraction methods have been developed so far. They are categorized as either strong (e.g., decalcification) or soft (e.g., water, ethanol) and they allow specific extractions of targeted compounds. The structure of the nacreous organic matrix is complex, and it provides interesting clues to describe the mineralization process. Proteins, sugars, lipids, peptides, and other molecules have been identified and their role in mineralization investigated. Moreover, the organic matrix of nacre has shown interesting properties for human health. Several studies are investigating its activity on bone mineralization and its properties for skin care. In this review, we focus on the organic constituents, as lipids, sugars, and small metabolites which are less studied since present in small quantities. [ABSTRACT FROM AUTHOR]

Published

2022

37. Biomimetic Nacre-like Hydroxyapatite/Polymer Composites for Bone Implants

Author

Parinaz Tabrizian, Huijun Sun, Urangua Jargalsaikhan, Tan Sui, Sean Davis, and Bo Su

Subjects

biomimetic, bioactive, hydroxyapatite, nacre, bi-directional freeze-casting, nacre-like composite, Biotechnology, TP248.13-248.65, Medicine (General), R5-920

Abstract

One of the most ambitious goals for bone implants is to improve bioactivity, incapability, and mechanical properties; to reduce the need for further surgery; and increase efficiency. Hydroxyapatite (HA), the main inorganic component of bones and teeth, has high biocompatibility but is weak and brittle material. Cortical bone is composed of 70% calcium phosphate (CaP) and 30% collagen and forms a complex hierarchical structure with anisotropic and lamellar microstructure (osteons) which makes bone a light, strong, tough, and durable material that can support large loads. However, imitation of concentric lamellar structure of osteons is difficult to achieve in fabrication. Nacre from mollusk shells with layered structures has now become the archetype of the natural “model” for bio-inspired materials. Incorporating a nacre-like layered structure into bone implants can enhance their mechanical strength, toughness, and durability, reducing the risk of implant catastrophic failure or fracture. The layered structure of nacre-like HA/polymer composites possess high strength, toughness, and tunable stiffness which matches that of bone. The nacre-like HA/polymer composites should also possess excellent biocompatibility and bioactivity which facilitate the bonding of the implant with the surrounding bone, leading to improved implant stability and long-term success. To achieve this, a bi-directional freeze-casting technique was used to produce elongated lamellar HA were further densified and infiltrated with polymer to produce nacre-like HA/polymer composites with high strength and fracture toughness. Mechanical characterization shows that increasing the ceramic fractions in the composite increases the density of the mineral bridges, resulting in higher flexural and compressive strength. The nacre-like HA/(methyl methacrylate (MMA) + 5 wt.% acrylic acid (AA)) composites with a ceramic fraction of 80 vol.% showed a flexural strength of 158 ± 7.02 MPa and a Young’s modulus of 24 ± 4.34 GPa, compared with 130 ± 5.82 MPa and 19.75 ± 2.38 GPa, in the composite of HA/PMMA, due to the higher strength of the polymer and the interface of the composite. The fracture toughness in the composition of 5 wt.% PAA to PMMA improves from 3.023 ± 0.98 MPa·m1/2 to 5.27 ± 1.033 MPa·m1/2 by increasing the ceramic fraction from 70 vol.% to 80 vol.%, respectively.

Published

2023

38. “Wood-nacre”: Development of a Bio-inspired Wood-Based Composite for Beam and 3D-Surface Elements with Improved Failure Mechanisms

Author

Müller, Ulrich, Halbauer, Peter, Stadlmann, Alexander, Grabner, Maximilian, Al-musawi, Hajir, Ungerer, Bernhard, and Pramreiter, Maximilian

Published

2023

39. Investigation of Bioinspired Nacreous Structure on Strength and Toughness.

Author

Tang, Biao, Niu, Shichao, Yang, Jiayi, Shao, Chun, Wang, Ming, Ni, Jing, Zhang, Xuefeng, and Yang, Xiao

Subjects

*COMPOSITE materials, *TENSILE strength, *CRACK propagation (Fracture mechanics), *COMPUTER simulation, *FINITE element method

Abstract

The toughening mechanism of the nacre was widely investigated in recent decades, which presents a great prospect for designing high performance composite materials and engineering structures with bioinspired structures. To further elucidate which structural parameters and which kinds of morphology of the nacre-inspired structure are the best for improving tensile strength without sacrificing too much toughness is extremely significant for composite materials and engineering structures. The "brick-and-mortar" structure is a classical nacre-inspired bionic structure. Three characteristic structural parameters, including the aspect ratio ρ of the brick length and width, the thickness ratio β between the thickness of brick and mortar, and the spacing ratio τ between the width of brick and mortar, were used as variables to study their effect on tensile strength and toughness. It was found that ρ was the most prominent factor in determining the strength and toughness, and τ could improve the strength and toughness almost simultaneously. Racked and wedged morphology of the structural unit were established based on the structural parameters of the regular staggered unit, and were used to compare tensile behavior. It was found that the model with the wedged unit possessed the highest strength and toughness, and could absorb more strain energy during fracture crack growing. The crack propagation path further illustrated that the crack resisting ability of the wedged unit was the best. Our simulation results presented the connection between three characteristic structural parameters with the strength and toughness, and proved that the wedged staggered unit was the best in improving the strength and toughness. [ABSTRACT FROM AUTHOR]

Published

2022

40. Protective Effect on Bone of Nacre Supplementation in Ovariectomized Rats.

Author

Nguyen, Dung Kim, Laroche, Norbert, Vanden‐Bossche, Arnaud, Linossier, Marie‐Thérèse, Thomas, Mireille, Peyroche, Sylvie, Normand, Myriam, Bertache‐Djenadi, Yacine, Thomas, Thierry, Marotte, Hubert, Vico, Laurence, Lafage‐Proust, Marie‐Hélène, and Rousseau, Marthe

Subjects

MOTHER-of-pearl, LUMBAR vertebrae, CALCIUM metabolism, CANCELLOUS bone, PRINCIPAL components analysis, DIETARY supplements, BONE products, FRACTURE healing

Abstract

Nacre has emerged as a beneficial natural product for bone cells and tissues, but its effect was only studied by gavage in the ovariectomized mouse model. We sought to assess the antiosteoporotic effect of nacre through a nutritional supplementation in the ovariectomized rat model. Sixteen‐week‐old female Wistar rats were either Sham‐operated or bilateral ovariectomized (OVX) and then fed with standard diet (Sham and OVX groups) or standard diet supplemented with either 0.25% CaCO3 or nacre (OVX CaCO3 and OVX Nacre group, respectively) for 28 days (n = 10/group). The bone microarchitecture was assessed at appendicular and axial bones by micro‐computed tomography (μCT). Histomorphometric analysis was performed to determine cellular and dynamic bone parameters. Bone metabolism was also evaluated by biochemical markers and gene expression levels. Nacre‐based diet prevented the OVX‐induced bone loss better than that of the CaCO3 supplement, given the significant changes in trabecular bone volume fraction (BV/TV) both at the femoral distal metaphysis (difference, 35%; p = 0.004) and at the second lumbar spine (difference, 11%; p = 0.01). Trabecular osteoclast surfaces (Oc.S/BS) were also 1.5‐fold lower at the tibial proximal metaphysis in OVX Nacre group compared with OVX CaCO3 group (p = 0.02). By principal component analysis (PCA), OVX Nacre group formed a cluster away from OVX group and with a trend closest to Sham group. These data were consistent with biological measurements demonstrating a positive profile related to nacre supplementation, which blunted an increase in serum CTX level and enhanced serum P1NP secretion 14 days post‐OVX compared with CaCO3 supplementation. Bmp2 mRNA expression in OVX Nacre group was +1.76‐fold (p = 0.004) and +1.30‐fold (p = 0.20) compared with OVX and OVX CaCO3 groups, respectively. We conclude that supplementation with nacre could effectively limit bone loss induced by estrogen deficiency just after OVX in rats by modulating the negative imbalance of bone turnover. © 2022 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research. [ABSTRACT FROM AUTHOR]

Published

2022

41. Tough, Bioinspired Transparent Glass‐Ceramics.

Author

Fu, Qiang, Aaldenberg, Emily M., Coon, Erin N., Gross, Timothy M., Whittier, Alana M., Abel, Brett M., and Baker, David E.

Subjects

LITHIUM, STRENGTH of materials, FRACTURE toughness, LITHIUM silicates, MOTHER-of-pearl, LOW temperatures, APATITE, GLASS-ceramics, POLYMERIC composites

Abstract

Transparent materials with high strength and toughness are highly demanded as engineering materials for consumer electronic, structural, and optical applications. Inspired by the "brick‐and‐mortar" structure in nacre, transparent glass/polymer composites have demonstrated an exceptionally high toughness and impact resistance. However, these composites suffer from low strength and low working temperatures due to polymeric components. Herein, a simple bioinspired approach to achieve a combination of high fracture toughness (KIC = 2.0 MPa m1/2) and optical transparency in a lithium disilicate/apatite glass‐ceramic through the creation of an acicular crystalline phase and a weak glassy interface is reported. This bioinspired approach represents a new pathway to manufacturing transparent materials for a variety of applications where mechanical performance is a necessity. [ABSTRACT FROM AUTHOR]

Published

2022

42. Orientation-dependent micromechanical behavior of nacre: In situ TEM experiments and finite element simulations.

Author

Peng, Xiang-Long, Lee, Subin, Wilmers, Jana, Oh, Sang Ho, and Bargmann, Swantje

Subjects

MOTHER-of-pearl, TRANSMISSION electron microscopy, FRACTURE toughness, MECHANICAL failures, STRUCTURAL models

Abstract

Nacre's superior mechanical properties and failure behavior are strongly orientation-dependent due to its brick-and-mortar microstructure. In this work, the anisotropic microscopic deformation and the resulting macroscopic mechanical properties are evaluated under different loading conditions. Our in situ transmission electron microscopy deformation experiments and finite element simulations reveal that nacre possesses enhanced indentation resistance along the direction normal to the tablets through delocalization of indentation-induced deformation by taking advantage of its layered structure. In addition, nacre's ability to recover from large deformations is observed. We study the strong loading direction dependence of nacre's macroscopic mechanical properties and elucidate the underlying microscopic deformation patterns in the tablets and the soft matrix. Particularly, its performance along the transverse direction is optimized to withstand the loading conditions in nature. We show the importance of the vertical matrix for the initial stiffness and fracture toughness of the composite. These findings provide guidelines for designing nacre-inspired artificial composites with enhanced mechanical properties. Nacre is widely recognized as an excellent structural model for designing bio-inspired tough and strong artificial composites. Due to its brick-and-mortar microstructure, it exhibits loading direction-dependent mechanical behavior. In this contribution, we investigate the macroscopic mechanical properties and microscopic deformation behavior of nacre under different loading conditions by means of in situ TEM deformation tests and FE simulations. It is found that effective elastic moduli and microscopic deformation strongly depend on the loading direction. The organic matrix is highly deformable. The indentation resistance along the direction normal to tablets is enhanced via deformation delocalization. Our quantitative and qualitative results provide guidelines on optimizing the mechanical properties of nacre-inspired novel composites. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

43. Protective Effect on Bone of Nacre Supplementation in Ovariectomized Rats

Author

Dung Kim Nguyen, Norbert Laroche, Arnaud Vanden‐Bossche, Marie‐Thérèse Linossier, Mireille Thomas, Sylvie Peyroche, Myriam Normand, Yacine Bertache‐Djenadi, Thierry Thomas, Hubert Marotte, Laurence Vico, Marie‐Hélène Lafage‐Proust, and Marthe Rousseau

Subjects

BONE, NACRE, OSTEOPOROSIS, OVARIECTOMY, RATS, Orthopedic surgery, RD701-811, Diseases of the musculoskeletal system, RC925-935

Abstract

ABSTRACT Nacre has emerged as a beneficial natural product for bone cells and tissues, but its effect was only studied by gavage in the ovariectomized mouse model. We sought to assess the antiosteoporotic effect of nacre through a nutritional supplementation in the ovariectomized rat model. Sixteen‐week‐old female Wistar rats were either Sham‐operated or bilateral ovariectomized (OVX) and then fed with standard diet (Sham and OVX groups) or standard diet supplemented with either 0.25% CaCO3 or nacre (OVX CaCO3 and OVX Nacre group, respectively) for 28 days (n = 10/group). The bone microarchitecture was assessed at appendicular and axial bones by micro‐computed tomography (μCT). Histomorphometric analysis was performed to determine cellular and dynamic bone parameters. Bone metabolism was also evaluated by biochemical markers and gene expression levels. Nacre‐based diet prevented the OVX‐induced bone loss better than that of the CaCO3 supplement, given the significant changes in trabecular bone volume fraction (BV/TV) both at the femoral distal metaphysis (difference, 35%; p = 0.004) and at the second lumbar spine (difference, 11%; p = 0.01). Trabecular osteoclast surfaces (Oc.S/BS) were also 1.5‐fold lower at the tibial proximal metaphysis in OVX Nacre group compared with OVX CaCO3 group (p = 0.02). By principal component analysis (PCA), OVX Nacre group formed a cluster away from OVX group and with a trend closest to Sham group. These data were consistent with biological measurements demonstrating a positive profile related to nacre supplementation, which blunted an increase in serum CTX level and enhanced serum P1NP secretion 14 days post‐OVX compared with CaCO3 supplementation. Bmp2 mRNA expression in OVX Nacre group was +1.76‐fold (p = 0.004) and +1.30‐fold (p = 0.20) compared with OVX and OVX CaCO3 groups, respectively. We conclude that supplementation with nacre could effectively limit bone loss induced by estrogen deficiency just after OVX in rats by modulating the negative imbalance of bone turnover. © 2022 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research.

Published

2022

44. Insights from tyrosinase into the impacts of modified morphology of calcium carbonate on the nacre formation of pearl oysters

Author

Xinwei Xiong, Yanfei Cao, Zhixin Li, Ronglian Huang, Yu Jiao, Liqiang Zhao, Xiaodong Du, and Zhe Zheng

Subjects

tyrosinase, nacre, morphologies, calcium carbonate crystallization, calcium carbonate precipitation, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

Tyrosinase is a type-3 copper protein with six conserved histidine residues within the copper-binding sites. It participates in mollusk nacre formation. Here, we identified nacreous-layer-specific tyrosinases (NLSTyr) from Pinctada fucata martensii (PmTyr-4 and PmTyr-6), as well as their homologs in Pinctada maxima (PmaxTyr and PmaxTyr4) and Pinctada margaritifera (PmarTyr and PmarTyr-4), which encoded tyrosinases without the six conserved histidine residues within the copper-binding sites. PmTyr-4 and PmTyr-6 mRNAs were spatially concentrated in the mantle central and pearl sac, which are the organs responsible for nacre formation. During shell regeneration and pearl formation, PmTyr-4 and PmTyr-6 were also significantly highly expressed in the mantle and pearl sac. RNA interference showed that PmTyr-4 participated in nacreous-layer formation. The recombinant protein of PmTyr-4 (rPmTyr-4) inhibited the calcium carbonate precipitation rate. Correspondingly, calcium carbonate crystallization assay showed that the aragonite crystals of the rPmTyr-4 group were smaller than those of the control group. Moreover, the calcite and aragonite morphologies of the rPmTyr-4 group were modified compared with the control group. These results suggested that NLSTyr in pearl oyster inhibited calcium carbonate precipitation and affected crystal morphologies during nacre formation. Our findings provided new insights into the evolution and function gain of tyrosinase in Mollusk.

Published

2022

45. Converting ocean nacre into bone mineral matrix composite for bone regeneration- in vitro and in vivo studies.

Author

Ruan, Rui, Shiroud Heidari, Behzad, Chen, Peilin, Gao, Junjie, Chen, Ziming, Chen, Lianzhi, Landao-Bassonga, Euphemie, Wang, Yongquan, Chen, Lingqiang, Wang, Bing, and Zheng, Minghao

Subjects

*BONE substitutes, *BONE remodeling, *CANCELLOUS bone, *CRYSTAL surfaces, *MOTHER-of-pearl, *BONE regeneration

Abstract

[Display omitted] • Developed a nacre-based calcium orthophosphates composite (NCOC) using a unique two-step self-setting technique, remodelling the human bone matrix. • NCOC showed a superior compression strength of 10 MPa, surpassing the strength of human trabecular bone. • In vitro tests showed the formation of apatite crystals with porous nanostructure, promoting efficient osteoblast attachment, proliferation, and osteogenic differentiation. • NCOC provides superior bone regeneration in critical bone defect models compared to conventional bone substitute apatite. Nacre of Pinctada maxima is a natural biomineralized matrix, appeared 7 million years before hominins. In this study, we converted nacre into a self-setting particle bound with multiple calcium orthophosphates that reassemble mammals' bone mineral matrices for induction of bone regeneration. The nacre-based calcium orthophosphates composite (NCOC) exhibited a compression strength of 10 MPa, which is superior to human trabecular bone. In vitro bioactivity tests revealed the formation of apatite with nano-porous flake-like crystals on the composite surface that mimic HA structure of a human bone matrix. NCOC demonstrated efficient attachment and proliferation of osteoblast cells, promoting osteogenic differentiation by increasing expressions of RUNX2 and OPN. In vivo studies using rabbit back fascia demonstrated that NCOC displays better bone healing and biocompatibility than conventional bone substitute apatite in critical bone defect models. The degradation of calcium carbonate crystal in vivo does not compromise structural integrity of NCOC. Overall, our data showed that NCOC produced through self-setting reactions, presents advantages such as accelerated biodegradation and osteostimulative properties, making it a promising bone substitute for effective bone regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

46. Mechanical behavior of MXene-Polymer layered nanocomposite using computational finite element analysis.

Author

Prasad, Anamika, Hasse, Jason, Steimle, Timothy, Nepal, Dhriti, Frank, Geoffrey J., and Varshney, Vikas

Subjects

*ELASTIC modulus, *ENERGY storage, *MOTHER-of-pearl, *GEOMETRIC modeling, *NANOCOMPOSITE materials

Abstract

The structural integrity of MXene and MXene-based materials is important across applications from sensors to energy storage. While MXene processing has received significant attention, its structural integrity for real-world applications remains challenging due to its flake-like structure. Here the mechanical response of layered MXene-polymer nanocomposites (MPC) with high MXene concentration (>70 %) and bioinspired nacre-like brick-and-mortar architecture is investigated to offer insights for MPC design and processing. An automated finite element analysis (FEA) framework is developed to analyze MPC models with randomized geometries and multiple combinations of the parameter space. Specifically, the influence of concentration, aspect ratio (AR), flake thickness, flake distribution, and interfacial strength is investigated. The results reveal property trends such as increasing elastic modulus, strength, and toughness with increasing cohesive strength and concentration for lower AR (=40, 60) but a decreasing trend at higher AR of 75. Local structural features like flake distribution, overlapping MXene lengths, and interconnected polymers in adjacent layers was found a critical determinant of performance. For example, stronger cohesive interaction showed 6X high toughness (291 ± 226 K J / m 3) compared to weaker case (50 ± 24 K J / m 3), but the large scatter highlighted the impact of microstructural features. The results are compared and validated with theoretical, computational, and experimental work. The findings provide valuable guidance for optimizing MPC design and their processing. Finally, the automation of the framework allows the design to be extended beyond the current system and chosen material combinations. [ABSTRACT FROM AUTHOR]

Published

2024

47. A Numerical Modelling Framework for Investigating the Ballistic Performance of Bio-Inspired Body Armours

Author

Abdallah Ghazlan, Tuan Ngo, Ping Tan, Phuong Tran, and Yi Min Xie

Subjects

ballistic protection, bio-inspired, body armour, nacre, conch, fish scale, Technology

Abstract

Biological structures possess excellent damage tolerance, which makes them attractive for ballistic protection applications. This paper develops a finite element modelling framework to investigate the performance of several biological structures that are most relevant for ballistic protection, including nacre, conch, fish scales, and crustacean exoskeleton. Finite element simulations were conducted to determine the geometric parameters of the bio-inspired structures that can survive projectile impact. The performances of the bio-inspired panels were benchmarked against a monolithic panel with the same 4.5 mm overall thickness and projectile impact condition. It was found that the biomimetic panels that were considered possessed better multi-hit resistant capabilities compared to the selected monolithic panel. Certain configurations arrested a fragment simulating projectile with an initial impact velocity of 500 m/s, which was similar to the performance of the monolithic panel.

Published

2023

48. Graphene Oxide/Elastin Nanostructure-Based Membranes for Bone Regeneration.

Author

Li, Hao, Buck, Emily, Elkashty, Osama, Tran, Simon D., Szkopek, Thomas, and Cerruti, Marta

Abstract

Nacre has an excellent combination of strength and toughness due to its "brick-and-mortar" layered structure. Graphene oxide (GO) is an ideal candidate as a "brick" material due to its two-dimensional structure, outstanding ultimate strength, and Young's modulus. GO is also able to stimulate osteogenesis, which suggests the potential application of nacre-like GO-based nanocomposites in bone regeneration. Most nacre-like GO-based nanocomposites developed thus far focus on the simultaneous enhancement of strength and toughness, with only three studies published to date investigating the osteogenic potential of the nanocomposites. All three studies used a ternary system with GO as the brick, chitosan as the mortar, and hydroxyapatite or calcium silicate as the bioactive additive to stimulate apatite formation and bone integration. Herein we introduce a binary nacre-like nanocomposite based on GO and elastin for bone regeneration. Elastin, as an extracellular matrix protein, confers elasticity to tissues. Elastin also initiates mineral deposition in the aorta, suggesting its potential to induce mineral formation during bone regeneration. Hence, elastin acts as the bioactive additive in addition to its function as the mortar phase. The nacre-like GO/elastin nanocomposite membranes can be fabricated with a simple evaporation approach; they have a compact "brick-and-mortar" multilayered structure, a tensile strength of 93 ± 10 MPa, and Young's modulus of 13.4 ± 0.4 GPa, comparable with cortical bone. Elastin incorporation promotes mineralization in simulated body fluid and enhances the proliferation as well as osteogenic differentiation of mouse bone marrow mesenchymal stem cells compared to pristine GO membranes. These results suggest that nacre-like GO/elastin membranes are promising materials for biomedical applications in bone regeneration, including bone implants, barrier membranes for guided bone regeneration, and coatings for implant materials. [ABSTRACT FROM AUTHOR]

Published

2022

49. Induction of Osseointegration by Nacre in Pigs.

Author

Leelatian, Leena, Chunhabundit, Panjit, Charoonrut, Phingphol, and Asvanund, Pattapon

Subjects

*OSSEOINTEGRATION, *MOTHER-of-pearl, *DENTAL implants, *CANCELLOUS bone, *PACIFIC oysters, *BONE regeneration, *OPERATIVE dentistry

Abstract

Nacre is a biomaterial that has shown osteoinductive and osteoconductive properties in vitro and in vivo. These properties make nacre a material of interest for inducing bone regeneration. However, information is very limited regarding the introduction of nacre to dental implant surgery for promoting osteogenesis. This study investigated the potential of nacre powder for peri-implant bone regeneration in a porcine model. Ninety-six dental implants were placed into the tibia of twelve male domestic pigs. The dental implants were coated with nacre powder from the giant oyster before implantation. Implantations without nacre powder were used as control groups. Euthanization took place at 2, 4 and 6 weeks after implantation, after which we measured bone-to-implant contact (BIC) and bone volume density (BVD) of the implanted bone samples using micro-computed tomography (micro-CT), and examined the histology of the surrounding bone using histological sections stained with Stevenel's blue and Alizarin red S. The micro-CT analyses showed that the BIC of dental implantations with nacre powder were significantly higher than those without nacre powder, by 7.60%. BVD of implantations with nacre powder were significantly higher than those without nacre powder, by 12.48% to 13.66% in cortical bone, and by 3.37% to 6.11% in spongy bone. Histological study revealed more peri-implant bone regeneration toward the surface of the dental implants after implantation with nacre powder. This was consistent with the micro-CT results. This study demonstrates the feasibility of using nacre to promote peri-implant bone regeneration in dental implantation. [ABSTRACT FROM AUTHOR]

Published

2022

50. Nacre-like alumina composites reinforced by zirconia particles.

Author

Henry, Ronan, Saad, Hassan, Dankic-Cottrino, Sandrine, Deville, Sylvain, and Meille, Sylvain

Subjects

*ALUMINA composites, *ZIRCONIUM oxide, *IMPACT (Mechanics), *TOUGHNESS (Personality trait), *CRACK propagation (Fracture mechanics), *FLEXURAL strength

Abstract

• Nacre-like composites were prepared with a simple process, including zirconia particles in monoclinic or in tetragonal phase. • A R-curve effect is noted for all samples, mainly driven by crack deflection along the platelet interfaces. • The addition of tetragonal zirconia increases the strength and limits the growth of alumina grains during sintering. • Composites with tetragonal zirconia and no glass phase are potential candidates for high temperature applications. Nacre-like alumina is a class of bio-inspired ceramic composite manufactured by field-assisted sintering of green bodies made primarily of alumina platelets with an anisotropic microstructure. Here we investigate the addition of zirconia particles to enhance the mechanical properties of the composite. The resulting structure is a nacre-like anisotropic structure which features deflection and reinforcement during crack propagation. Monoclinic zirconia has no impact on the mechanical properties of the composite while tetragonal zirconia improves its fracture resistance properties. Both types of zirconia seem to slow down grain growth during sintering. The addition of zirconia stabilised in the tetragonal phase is thus a good option to obtain a composite with a fine microstructure and higher mechanical properties than a standard nacre-like alumina, with a flexural strength of 626 ± 39 MPa and a crack initiation toughness of 6.1 ± 0.6 MPa.m0.5. [ABSTRACT FROM AUTHOR]

Published

2022