Your search keyword '"Biomimetics"' showing total 2,715 results

1. Simple model for synchronization of two Belousov–Zhabotinsky gels interacting mechanically.

Author

Sukegawa, Taro, Yamada, Yuhei, and Maeda, Shingo

Subjects

BELOUSOV-Zhabotinskii reaction, SYNCHRONIZATION, BIOMIMETICS, DEFORMATIONS (Mechanics), PHENOMENOLOGY

Abstract

A Belousov–Zhabotinsky (BZ) gel is a unique biomimetic system that undergoes autonomous volume oscillations induced by the redox oscillation of the BZ reaction. In a previous study, researchers reported that the oscillations of two BZ gels coupled by compression were synchronized by a mechanical interaction. They mathematically explained the synchronization behavior using a phase oscillator model. As a different approach to the previous study, a physicochemical investigation of the phenomenon will lead to a better understanding of the functional biological rhythms essential for life. In this study, we construct a simple phenomenological model to understand the synchronization of BZ gels. The model consists of two parts. One is the dynamics of the chemical reactions in the BZ gels. We use a phenomenological model based on the Oregonator for the BZ reaction. The other is the dynamics of the mechanical deformation of the BZ gel. Using approximations, we extract the parameters essential for the synchronization of a mechanical interaction. Thus, we can derive a novel equation for the deformation dynamics of mechanically coupled BZ gels. By combining these two parts, we perform numerical calculations. This allows us to find that the synchronization of the two BZ gels is less likely to occur under stronger compression. We explain this trend through one physicochemical parameter in our model: the volume fraction of the BZ gel in the reduced state. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cephalopods' Skin‐Inspired Design of Nanoscale Electronic Transport Layers for Adaptive Electrochromic Tuning.

Author

Yu, Yilin, Zhu, Xinyi, Jiang, Shiqi, Wu, Shuangshuang, Zhao, Yu, Zhang, Lingli, Song, Liping, and Huang, Youju

Subjects

BIOMIMETICS, HUMAN skin color, CHARGE exchange, OXIDATION-reduction reaction, CEPHALOPODA

Abstract

Cephalopods can change their skin color by using high‐speed electron transduction among receptors, neural networks, and pigmentary effectors. However, it remains challenging to realize a neuroelectrical transmission system like that found in cephalopods, where electrons/ions transmit on nanoscale, which is crucial for fast adaptive electrochromic tuning. Inspired by that, hereby an ideal, rapidly responsive, and multicolor electrochromic biomimetic skin is introduced. Specifically, the biomimetic skin comprises W18O49 nanowires (NWs) that are either colorless or blue, Au nanoparticles@polyaniline (Au NPs@PANI) ranging from green to pink, and a flexible conductive substrate. As the applied voltage changes from 0.4 V to ‐0.7 V and back to 0 V, the color of the biomimetic skin transforms from green to blue and ultimately to pink. This color change is attributed to the electrically induced redox reaction of Au NPs@PANI and W18O49 NWs, triggered by the transfer of electrons and ions. Furthermore, the high versatility and adaptability of electrical stimulus enable the creation of a highly interactive electrochromic biomimetic skin system through the integration of sensitive acoustic sensors, providing a perfect environment‐responsive platform. This work provides a biomimetic multicolor electrochromic skin that depends on electron/ion transfer on nanoscale, expands potential uses for camouflage skin. [ABSTRACT FROM AUTHOR]

Published

2024

3. Intelligent Rock‐Climbing Robot Capable of Multimodal Locomotion and Hybrid Bioinspired Attachment.

Author

Zi, Peijin, Xu, Kun, Chen, Jiawei, Wang, Chang, Zhang, Tao, Luo, Yang, Tian, Yaobin, Wen, Li, and Ding, Xilun

Subjects

UNGULATES, PLANETARY exploration, QUADRATIC programming, ROCK climbing, EXTREME environments

Abstract

Rock‐climbing robots have significant potential in fieldwork and planetary exploration. However, they currently face limitations such as a lack of stability and adaptability on extreme terrains, slow locomotion, and single functionality. This study introduces a novel multimodal and adaptive rock‐climbing robot (MARCBot), which addresses these limitations through spiny grippers that draw inspiration from morpho‐functionalities observed in beetles, arboreal birds, and hoofed animals. This hybrid bioinspired design enables high attachment strength, passive adaptability to different terrains, and quick attachment on rock surfaces. The multimodal functionality of the gripper allows for attachment during climbing and support during walking. A novel control strategy using dynamics and quadratic programming (QP) optimizes attachment wrench distribution, reducing cost‐of‐transport by 20.03% and 6.05% compared to closed‐loop inverse kinematic (CLIK) and virtual model control (VMC) methods, respectively. MARCBot achieved climbing speeds of 0.15 m min−1 on a vertical discrete rock surface under gravity and trotting speeds of up to 0.21 m s−1 on various complex terrains. It is the first robot capable of climbing on rock surfaces and trotting in complex terrains without the need for switching end‐effectors. This study highlights significant advancements in climbing and multimodal locomotion for robots in extreme environments. [ABSTRACT FROM AUTHOR]

Published

2024

4. A Soft, Fatigue‐free, and Self‐healable Ionic Elastomer via the Synergy of Skin‐like Assembly and Bouligand Structure.

Author

Jiang, Xinyuan, Cheng, Yin, Shi, Liangjing, Sun, Jing, and Wang, Ranran

Subjects

FATIGUE limit, BIOMIMETICS, FATIGUE cracks, FRACTURE toughness, THERMOPLASTIC composites

Abstract

Soft ionic elastomers that are self‐healable, fatigue‐free, and environment‐tolerant are ideal structural and sensing materials for artificial prosthetics, soft electronics, and robotics to survive unpredictable service conditions. However, most synthetic strategies failed to unite rapid healing, fatigue resistance, and environmental robustness, limited by their singular compositional/structural designs. Here, we present a soft, tough, fatigue‐resistant, and self‐healable ionic elastomer (STFSI elastomer), which fuses skin‐like binary assembly and Bouligand helicoidal structure into a composite of thermoplastic polyurethane (TPU) fibers and a supramolecular ionic biopolymer. The interlocked binary assembly enables skin‐like softness, high stretchability, and strain‐adaptive stiffening through a matrix‐to‐scaffold stress transfer. The Bouligand structure contributes to superhigh fracture toughness (101.6 kJ m−2) and fatigue resistance (4937 J m−2) via mechanical toughening by interlayer slipping and twisted crack propagation path. Besides, the STFSI elastomer is self‐healable through a "bridging" method and environment‐tolerant (−20 °C, strong acid/alkali, saltwater). To demonstrate the versatile structural and sensing applications, we showcase a safety cushion with efficient damping and suppressed rebounding, and a robotic sensor with excellent fatigue crack tolerance and instant sensation recovery upon cutting‐off damage. Our presented synthetic strategy is generalizable to other fiber‐reinforced tough polymers for applications involving demanding mechanical/environmental conditions. [ABSTRACT FROM AUTHOR]

Published

2024

5. A Soft, Fatigue‐free, and Self‐healable Ionic Elastomer via the Synergy of Skin‐like Assembly and Bouligand Structure.

Author

Jiang, Xinyuan, Cheng, Yin, Shi, Liangjing, Sun, Jing, and Wang, Ranran

Subjects

FATIGUE limit, BIOMIMETICS, FATIGUE cracks, FRACTURE toughness, THERMOPLASTIC composites

Abstract

Soft ionic elastomers that are self‐healable, fatigue‐free, and environment‐tolerant are ideal structural and sensing materials for artificial prosthetics, soft electronics, and robotics to survive unpredictable service conditions. However, most synthetic strategies failed to unite rapid healing, fatigue resistance, and environmental robustness, limited by their singular compositional/structural designs. Here, we present a soft, tough, fatigue‐resistant, and self‐healable ionic elastomer (STFSI elastomer), which fuses skin‐like binary assembly and Bouligand helicoidal structure into a composite of thermoplastic polyurethane (TPU) fibers and a supramolecular ionic biopolymer. The interlocked binary assembly enables skin‐like softness, high stretchability, and strain‐adaptive stiffening through a matrix‐to‐scaffold stress transfer. The Bouligand structure contributes to superhigh fracture toughness (101.6 kJ m−2) and fatigue resistance (4937 J m−2) via mechanical toughening by interlayer slipping and twisted crack propagation path. Besides, the STFSI elastomer is self‐healable through a "bridging" method and environment‐tolerant (−20 °C, strong acid/alkali, saltwater). To demonstrate the versatile structural and sensing applications, we showcase a safety cushion with efficient damping and suppressed rebounding, and a robotic sensor with excellent fatigue crack tolerance and instant sensation recovery upon cutting‐off damage. Our presented synthetic strategy is generalizable to other fiber‐reinforced tough polymers for applications involving demanding mechanical/environmental conditions. [ABSTRACT FROM AUTHOR]

Published

2024

6. Exceptional Nitrate Reduction to Ammonia Catalyst Enabled by BO2− Anion Induction Effects Combining Heterogeneous Branching Architecture‐Driven Mass Transport Enhancement.

Author

Ding, Liping, Yan, Han, Zhang, Lin, Bai, Ruijie, Du, Qian, Xu, Chun, Gu, Haojie, Guo, Suer, Cheng, Guoxia, Fu, Qiaomei, Liu, Siqi, Yin, Kang, Li, Qi, and Wang, Yanqing

Subjects

ELECTRON density, DENITRIFICATION, BIOMIMETICS, CATALYTIC activity, BINDING energy, MASS transfer, PHASE-transfer catalysis, ELECTROLYTIC reduction

Abstract

In this paper, an exceptional nitrate reduction to ammonia catalyst is reported, enabled by BO2− anion induction effects combining heterogeneous branching architecture‐driven mass transport enhancement strategies. The implantation of the BO2− anion can inductively enhance the electron cloud density and electron transmission paths of intrinsic catalysts, makes electron more active to improve the conductivity, regulates the adsorption and desorption rates of intermediates by space barrier effect, reduces the binding energy of the electron and 3d orbital of Ni in NiFe(BO2)O(OH), thereby lowing the transform free energy of the determining *NO3 to *HNO3 step. 3D hollow sea urchin lattice heterogeneous branching structure can self‐drive generate differentiated micro convection intervals, which will be beneficial for improving mass transfer dynamics especially localized disturbance mass transfer effect of catalyst for nitrate reduction reaction (NO3RR) catalysis process. Amazingly, the as‐prepared 3D NiFe metaborate oxyhydroxide hollow bionic sea urchins lattice catalyst has a high NH3 rate 6.27mmol·h−1·cm−2 with 98.7% Faradaic efficiency at low ‐0.25V(vs RHE) NO3RR potential. Moreover, the catalytic activity of this highly stable catalyst decreases only slightly over 100 h at ultra‐high 1500mA·cm−2 current. This work breaks through the bottleneck that plagues the performance improvement of non Cu‐based high‐current NO3RR catalysts. [ABSTRACT FROM AUTHOR]

Published

2024

7. A cluster-nanozyme-coenzyme system mimicking natural photosynthesis for CO2 reduction under intermittent light irradiation.

Author

Cui, Xiaofeng, Bai, Hui, Zhang, Jun, Liu, Rong, Yu, Haiyan, Wang, Yangxiang, Kong, Tingting, Gao, Mei-Yan, Lu, Zhou, and Xiong, Yujie

Subjects

ARTIFICIAL photosynthesis, BIOMIMETICS, PRECIOUS metals, COENZYMES, SOLAR energy

Abstract

Natural photosynthesis utilizes solar energy to convert water and atmospheric CO2 into carbohydrates through all-weather light/dark reactions based on molecule-based enzymes and coenzymes, inspiring extensive development of artificial photosynthesis. However, development of efficient artificial photosynthetic systems free of noble metals, as well as rational integration of functional units into a single system at the molecular level, remain challenging. Here we report an artificial system, the assembly system of Cu6 cluster and cobalt terpyridine complex, that mimics natural photosynthesis through precise integration of nanozyme complexes and ubiquinone (coenzyme Q) on Cu6 clusters. This biomimetic system efficiently reduces CO2 to CO in light reaction, achieving a production rate of 740.7 μmol·g−1·h−1 with high durability for at least 188 hours. Notably, our system realizes the decoupling of light and dark reactions, utilizing the phenol-evolutive coenzyme Q acting as an electron reservoir. By regulating the stabilizer of coenzyme Q, the dark reaction time can be extended up to 8.5 hours, which fully meets the natural day/night cycle requirements. Our findings advance the molecular design of artificial systems that replicate the comprehensive functions of natural photosynthesis. Natural photosynthesis converts H2O and CO2 into carbohydrates through all-weather reactions based on enzymes and coenzymes. Here, the authors report an artificial photosynthesis system under intermittent light irradiation by integrating nanozyme complexes and ubiquinone on a copper nanocluster. [ABSTRACT FROM AUTHOR]

Published

2024

8. Ultra-soft cellular solids inspired by marine mussel plaques: scaling of the mechanical properties.

Author

Pang, Yong, Busfield, James, and Liu, Tao

Subjects

BULK solids, MYTILIDAE, YOUNG'S modulus, MATERIALS science, FAILURE mode & effects analysis

Abstract

The porous core of the marine mussel provides mechanical advantages of achieving substantial deformation and high toughness. Inspired by the unique mechanical behaviours of mussel plaque cores, the present study develops ultra-soft, stretchable and tough cellular solids by bio-mimicking their porosity and properties. Although scaling laws to correlate the mechanical properties of cellular solids with bulk materials have been established, they are primarily based on experimental data from stiff cellular solids. In this article, the scaling law for soft cellular solids is studied to relate tensile properties and toughness with volume fractions. Unlike conventional stiff cellular solids, the scaling law shows that soft lattices experience bending-dominated deformation at the elastic state and fail under stretching-dominated deformation. Uniaxial and planar tensile tests demonstrate that the proposed soft lattices achieved Young's modulus of 0.04∼0.17 MPa, failure strain of 135.5∼213.9% and toughness of 582∼941 J m−2 by manipulating the volume fraction (0.2∼0.5), positioning them as softer, more stretchable and tougher than the majority of engineering foams in the Ashby diagram. In addition, the toughness of soft lattices is found to be sensitive to volume fraction but insensitive to initial crack length, thickness and height (≥20mm). Two distinct failure modes, truss failure and joint failure, are correlated with volume fraction. The soft lattice with a volume fraction (around 0.4) similar to mussel plaque fails at the transition of these two failure modes and achieves the highest toughness. This study contributes new insights to the materials science community and lays the foundation for the development of lightweight, damage-tolerant and high-performance metamaterials. [ABSTRACT FROM AUTHOR]

Published

2024

9. Engineered protein elastomeric materials.

Author

Liu, Zhongcheng, Li, Haopeng, Li, Jingjing, Yu, Jing, and Liu, Kai

Subjects

ELASTOMERS, RECOMBINANT proteins, BIOMIMETICS, SYNTHETIC proteins, PROTEIN engineering, SYNTHETIC biology

Abstract

Natural evolution endows some insects and marine organisms with a special class of protein-based elastic tissues that possess energy feedback characteristics, providing them with the foundation for jumping and flying, and protecting them from the damage caused by movements or waves. However, the design and fabrication of such protein-based elastomeric materials that can function in human society through biomimetic strategies still remains challenging. Recombinant proteins designed by synthetic biology can mimic the advantageous structures in natural proteins and can be biosynthesized without the requirements for harsh conditions such as high temperatures and cytotoxic agents, which provides a great opportunity to prepare protein-based elastomeric materials. In this review, starting from the design of protein molecules, we highlight an overview of the synthesis of elastomeric materials based on recombinant resilin, recombinant elastin-like proteins and other recombinant folded proteins, etc., and then demonstrate their application progress in the fields of biomedicine and high technology. Finally, the challenges and prospects for the future development of protein-based elastomeric materials are envisioned to provide insights into the design and synthesis of the next generation of protein-based elastomeric materials. [ABSTRACT FROM AUTHOR]

Published

2024

10. Pangolin scales as adaptations for innate immunity against pathogens.

Author

Tian, Xuechen, Chen, Li, Zhou, Jinfeng, Wang, Enbo, Wang, Mu, Jakubovics, Nicholas, Li, Jing, Song, Kunping, Lau, King Tong, Koepfli, Klaus-Peter, Zhang, Siyuan, Tan, Geok Yuan Annie, Yang, Yixin, and Choo, Siew Woh

Subjects

MESENCHYMAL stem cells, BIOMIMETICS, NATURAL immunity, PATHOGENIC bacteria, PANGOLINS

Abstract

Background: Pangolins are the only mammals that have overlapping scales covering most of their bodies, and they play a crucial role in the ecosystem, biological research, and human health and disease. Previous studies indicated pangolin scale might provide an important mechanical defense to themselves. The origin and exact functions of this unique trait remain a mystery. Using a multi-omics analysis approach, we report a novel functional explanation for how mammalian scales can provide host–pathogen defense. Results: Our data suggest that pangolin scales have a sophisticated structure that could potentially trap pathogens. We identified numerous proteins and metabolites exhibiting antimicrobial activity, which could suggest a role for scales in pathogen defense. Notably, we found evidence suggesting the presence of exosomes derived from diverse cellular origins, including mesenchymal stem cells, immune cells, and keratinocytes. This observation suggests a complex interplay where various cell types may contribute to the release of exosomes and antimicrobial compounds at the interface between scales and viable tissue. These findings indicate that pangolin scales may serve as a multifaceted defense system, potentially contributing to innate immunity. Comparisons with human nail and hair revealed pangolin-specific proteins that were enriched in functions relating to sensing, immune responses, neutrophil degranulation, and stress responses. We demonstrated the antimicrobial activity of key pangolin scale components on pathogenic bacteria by antimicrobial assays. Conclusions: This study identifies a potential role of pangolin scales and implicates scales, as possible determinants of pathogen defense due to their structure and contents. We indicate for the first time the presence of exosomes in pangolin scales and propose the new functions of scales and their mechanisms. This new mechanism could have implications for multiple fields, including providing interesting new research directions and important insights that can be useful for synthesizing and implementing new biomimetic antimicrobial approaches. [ABSTRACT FROM AUTHOR]

Published

2024

11. Sequential Ion Induced Multilength‐Scale Structurally Fibers with Strain‐Stiffening, High Damping, and Shape‐Memory Features.

Author

Zhang, Wenjie, Wang, Penghui, Hu, Yi, Chen, Qiang, and Chi, Bo

Subjects

DAMPING capacity, SMART materials, SMART structures, BIOMEDICAL materials, BIOMIMETICS, SPIDER silk, SHAPE memory polymers

Abstract

Natural materials possess inherent multilength‐scale structures, showcasing outstanding mechanical properties such as strain‐stiffening, high damping, and shape‐memory features under ambient conditions. Such integrated properties are highly desirable for advanced materials in biomedical devices and soft robots but remain challenging in synthetic materials. Herein, a novel strategy of sequential ion treatment is employed to introduce micro/nanoscale‐ordered structures and molecular‐scale stimulus responses into hydrogel‐derived self‐assembly fibers under ambient conditions. The treated fibers exhibit strain‐stiffening properties with a high toughness of 257 MJ m−3 and 73% damping capacity comparable to spider silk. Owing to their cross‐linking network and reversible secondary structure, those fibers exhibit outstanding water‐stability, wet stretchability, and hydration‐responsive shape‐memory performance, with ultimate elongation of 407%, shape‐fixity ratio of 94%, and shape‐recovery rate of 97%. This work furthers the green fabrication of smart materials with multifunction and presents promising applications in diverse fields, including biomimetics and biomedicine. [ABSTRACT FROM AUTHOR]

Published

2024

12. A metabolic dysfunction-associated steatotic liver acinus biomimetic induces pancreatic islet dysfunction in a coupled microphysiology system.

Author

Aleman, Julio, K, Ravikumar, Wiegand, Connor, Schurdak, Mark E., Vernetti, Lawrence, Gavlock, Dillon, Reese, Celeste, DeBiasio, Richard, LaRocca, Greg, Angarita, Yulder Daniel, Gough, Albert, Soto-Gutierrez, Alejandro, Behari, Jaideep, Yechoor, Vijay K., Miedel, Mark T., Stern, Andrew M., Banerjee, Ipsita, and Taylor, D. Lansing

Subjects

MICROPHYSIOLOGICAL systems, BIOMIMETICS, INSULIN resistance, MODULAR design, ISLANDS, ISLANDS of Langerhans, INSULIN, GLUCOSE-regulated proteins

Abstract

Preclinical and clinical studies suggest that lipid-induced hepatic insulin resistance is a primary defect that predisposes to dysfunction in islets, implicating a perturbed liver-pancreas axis underlying the comorbidity of T2DM and MASLD. To investigate this hypothesis, we developed a human biomimetic microphysiological system (MPS) coupling our vascularized liver acinus MPS (vLAMPS) with pancreatic islet MPS (PANIS) enabling MASLD progression and islet dysfunction to be assessed. The modular design of this system (vLAMPS-PANIS) allows intra-organ and inter-organ dysregulation to be deconvoluted. When compared to normal fasting (NF) conditions, under early metabolic syndrome (EMS) conditions, the standalone vLAMPS exhibited characteristics of early stage MASLD, while no significant differences were observed in the standalone PANIS. In contrast, with EMS, the coupled vLAMPS-PANIS exhibited a perturbed islet-specific secretome and a significantly dysregulated glucose stimulated insulin secretion response implicating direct signaling from the dysregulated liver acinus to the islets. Correlations between several pairs of a vLAMPS-derived and a PANIS-derived factors were significantly altered under EMS, as compared to NF conditions, mechanistically connecting MASLD and T2DM associated hepatic-factors with islet-derived GLP-1 synthesis and regulation. Since vLAMPS-PANIS is compatible with patient-specific iPSCs, this platform represents an important step towards addressing patient heterogeneity, identifying disease mechanisms, and advancing precision medicine. A coupled liver-islet MPS was used to investigate the comorbidity between MASLD and T2DM. This study demonstrated that secreted factors from the MASLD liver disrupt islet function and suggest potential underlying mechanisms of disease progression along the liver-islet axis. [ABSTRACT FROM AUTHOR]

Published

2024

13. Pangolin scales as adaptations for innate immunity against pathogens.

Author

Tian, Xuechen, Chen, Li, Zhou, Jinfeng, Wang, Enbo, Wang, Mu, Jakubovics, Nicholas, Li, Jing, Song, Kunping, Lau, King Tong, Koepfli, Klaus-Peter, Zhang, Siyuan, Tan, Geok Yuan Annie, Yang, Yixin, and Choo, Siew Woh

Subjects

MESENCHYMAL stem cells, BIOMIMETICS, NATURAL immunity, PATHOGENIC bacteria, PANGOLINS

Abstract

Background: Pangolins are the only mammals that have overlapping scales covering most of their bodies, and they play a crucial role in the ecosystem, biological research, and human health and disease. Previous studies indicated pangolin scale might provide an important mechanical defense to themselves. The origin and exact functions of this unique trait remain a mystery. Using a multi-omics analysis approach, we report a novel functional explanation for how mammalian scales can provide host–pathogen defense. Results: Our data suggest that pangolin scales have a sophisticated structure that could potentially trap pathogens. We identified numerous proteins and metabolites exhibiting antimicrobial activity, which could suggest a role for scales in pathogen defense. Notably, we found evidence suggesting the presence of exosomes derived from diverse cellular origins, including mesenchymal stem cells, immune cells, and keratinocytes. This observation suggests a complex interplay where various cell types may contribute to the release of exosomes and antimicrobial compounds at the interface between scales and viable tissue. These findings indicate that pangolin scales may serve as a multifaceted defense system, potentially contributing to innate immunity. Comparisons with human nail and hair revealed pangolin-specific proteins that were enriched in functions relating to sensing, immune responses, neutrophil degranulation, and stress responses. We demonstrated the antimicrobial activity of key pangolin scale components on pathogenic bacteria by antimicrobial assays. Conclusions: This study identifies a potential role of pangolin scales and implicates scales, as possible determinants of pathogen defense due to their structure and contents. We indicate for the first time the presence of exosomes in pangolin scales and propose the new functions of scales and their mechanisms. This new mechanism could have implications for multiple fields, including providing interesting new research directions and important insights that can be useful for synthesizing and implementing new biomimetic antimicrobial approaches. [ABSTRACT FROM AUTHOR]

Published

2024

14. Advancements of biomaterials in oral tissue engineering: past, present, and future.

Author

Sun, Miao, Tang, Like, Yang, Xiaofu, Lu, Jingyi, He, Huihui, Lin, Jun, He, Yong, and Yu, Mengfei

Subjects

BIOMEDICAL materials, TISSUE engineering, REGENERATIVE medicine, COMPOSITE materials, THREE-dimensional printing, BIOMATERIALS

Abstract

Background: The deformation of oral and maxillofacial region leads to not only the damage of morphology and function, but also a series of aesthetic and psychological problems, severely affecting the quality of life of patients. Oral tissue engineering refers to developing biomaterials for repair or regeneration, with the application of tissue engineering technologies. This has become an area of increasing prominence. Current biologically inert materials are insufficient to fulfill clinical requirements. Therefore, tissue-engineered biomaterials with bioactive, even bionic properties are desperately needed. Main body: The complexity of the anatomy and the diversity of tissue types of oral and maxillofacial region pose great challenges to the regeneration, in the aspects of both biomaterials and manufacturing technologies. Biomaterials in clinical practice or research have evolved from natural materials to synthetic materials, from homogeneous materials to multiple composite materials. And now composite materials have increasingly demonstrated their advantages in terms of physicochemical and biological properties over conventional materials. In terms of manufacturing, traditional coating, sintering, and milling technologies can no longer satisfy the requirements for high-precision bionic structures of oral-tissue-engineering biomaterials. Scientists have turned to biofabrication technologies such as microfluidics and additive manufacturing. Short conclusion: This review aims to summarize the noteworthy advancements made in biomaterials of oral tissue engineering. We outlined the current biomaterials and manufacturing technologies and focused on various applications of these materials that may be connected to clinical treatment and research. We also suggested the future direction of development for biomaterials in oral tissue engineering. In future, biomaterials characterized by precision, functionalization, and individualization will be manufactured through digital, microfluidic, and 3D printing technologies. [ABSTRACT FROM AUTHOR]

Published

2024

15. Recent advances to engineer tough basalt fiber reinforced composites: A review.

Author

Chen, Changjie, Ding, Yi, Wang, Xinhou, and Bao, Limin

Subjects

INORGANIC fibers, MECHANICAL behavior of materials, GLASS composites, COMPOSITE materials, BIOMIMETICS

Abstract

Basalt fibers, known as "green materials without pollution in the 21st century", have gained widespread attention due to its good mechanical properties. Basalt fiber‐based composites have applications in various fields such as construction, transportation, energy, and protection. However, as an inorganic fiber material, basalt fiber is hard and brittle and prone to catastrophic failure, reducing the safety of the material. Therefore, it is important to strengthen the toughness of basalt fiber‐based composites. This paper reviews the contributions made by researchers in recent years to enhance the toughness of basalt fiber reinforced composites. It mainly focuses on four aspects: physical and chemical modification of fibers surface, mixed application of multiple fibers, different textile and 3D printing technology, and design of biomimetic structures. Through these methods, the toughness of basalt fiber‐reinforced composite materials was increased by 10%–90%. In today's advocacy for green industrial development, the research and application of basalt fibers are very important for advancing the process of green development. These contributions can promote the application of basalt fiber in engineering fields. Highlights: Basalt fiber is a green material without pollution.Basalt fiber reinforced composites is the key material for engineering field.Strengthening interfacial adhesion can significantly improve the toughness of composites.Basalt fibers can serve as an alternative to glass fibers in composite materials.The hybridization of basalt fibers with soft fibers can effectively enhance the toughness of composites. [ABSTRACT FROM AUTHOR]

Published

2024

16. Control of the Properties of the Voronoi Tessellation Technique and Biomimetic Patterns: A Review.

Author

Arvizu Alonso, Ana Karilú, Armendáriz Mireles, Eddie Nahúm, Calles Arriaga, Carlos Adrián, and Rocha Rangel, Enrique

Abstract

The cellular behavior of Voronoi tessellation has generated interest due to its applicability in various fields and its notable structural properties. Controlling factors such as the gradient of the cells, the position of seed points, and the thickness of the arms allows for adjusting rigidity and flexibility according to specific needs. This article analyzes the state of the art of this technique, exploring its modification for applications in engineering and design, complemented with information on natural structural properties. This comprehensive analysis provides a complete overview of Voronoi tessellation and its potential in engineering and design, categorizing methodologies according to selected processing methods and highlighting techniques for altering structural behavior. Additionally, it emphasizes the integration of biomimetic approaches, connecting nature with technology to foster continuous innovation. Finally, this article addresses encountered limitations, offering future perspectives for the cellular technique and highlights the complexity of reproducibility due to reserved or generalized steps, despite the significant diversity in implemented techniques. [ABSTRACT FROM AUTHOR]

Published

2024

17. Engineering of a Bio-Inspired Tiltable Oscillating Fin Submersible Thruster.

Author

Liu, Zihao and Li, Duanling

Abstract

Oscillating fins are devices designed to produce thrust through periodic undulating movements. However, these structures lack flexibility and often provide thrust in only one fixed direction. Observation and biological references suggest that the dorsal fin rays of seahorses can tilt longitudinally in the spine direction, changing the thrust direction. This study aims to analyze the dynamic effects of seahorse dorsal fin inclining and design a flexible bionic thruster based on this principle. Computational fluid dynamics analysis hypothesizes that fin inclination controls the net force direction in the vertical plane. A force sensor and pulley system test platform were constructed to examine the influences of wave features and the inclination angle on thrust in both vertical and horizontal directions, with discrete fin surfaces used to eliminate force interference. Force testing and snapshots indicate that wave velocity positively impacts net force magnitude, while fin inclination allows for control over force orientation. This tiltable oscillating fin thruster possesses more degrees of freedom, leading to better flexibility and providing controllable thrust orientation. [ABSTRACT FROM AUTHOR]

Published

2024

18. Biomimetic Tissue Engineering Strategies for Craniofacial Applications.

Author

Fatima Balderrama, Isis, Schafer, Sogand, El Shatanofy, Muhammad, Bergamo, Edmara T. P., Mirsky, Nicholas A., Nayak, Vasudev Vivekanand, Marcantonio Junior, Elcio, Alifarag, Adham M., Coelho, Paulo G., and Witek, Lukasz

Abstract

Biomimetics is the science of imitating nature's designs and processes to create innovative solutions for various fields, including dentistry and craniofacial reconstruction. In these areas, biomimetics involves drawing inspiration from living organisms/systems to develop new materials, techniques, and devices that closely resemble natural tissue structures and enhance functionality. This field has successfully demonstrated its potential to revolutionize craniofacial procedures, significantly improving patient outcomes. In dentistry, biomimetics offers exciting possibilities for the advancement of new dental materials, restorative techniques, and regenerative potential. By analyzing the structure/composition of natural teeth and the surrounding tissues, researchers have developed restorative materials that mimic the properties of teeth, as well as regenerative techniques that might assist in repairing enamel, dentin, pulp, cementum, periodontal ligament, and bone. In craniofacial reconstruction, biomimetics plays a vital role in developing innovative solutions for facial trauma, congenital defects, and various conditions affecting the maxillofacial region. By studying the intricate composition and mechanical properties of the skull and facial bones, clinicians and engineers have been able to replicate natural structures leveraging computer-aided design and manufacturing (CAD/CAM) and 3D printing. This has allowed for the creation of patient-specific scaffolds, implants, and prostheses that accurately fit a patient's anatomy. This review highlights the current evidence on the application of biomimetics in the fields of dentistry and craniofacial reconstruction. [ABSTRACT FROM AUTHOR]

Published

2024

19. Biomimetic Cooling: Functionalizing Biodegradable Chitosan Films with Saharan Silver Ant Microstructures.

Author

Zimmerl, Markus, van Nieuwenhoven, Richard W., Whitmore, Karin, Vetter, Wilfried, and Gebeshuber, Ille C.

Abstract

The increasing occurrence of hot summer days causes stress to both humans and animals, particularly in urban areas where temperatures can remain high, even at night. Living nature offers potential solutions that require minimal energy and material costs. For instance, the Saharan silver ant (Cataglyphis bombycina) can endure the desert heat by means of passive radiative cooling induced by its triangular hairs. The objective of this study is to transfer the passive radiative cooling properties of the micro- and nanostructured chitin hairs of the silver ant body to technically usable, biodegradable and bio-based materials. The potential large-scale transfer of radiative cooling properties, for example, onto building exteriors such as house facades, could decrease the need for conventional cooling and, therefore, lower the energy demand. Chitosan, a chemically altered form of chitin, has a range of medical uses but can also be processed into a paper-like film. The procedure consists of dissolving chitosan in diluted acetic acid and uniformly distributing it on a flat surface. A functional structure can then be imprinted onto this film while it is drying. This study reports the successful transfer of the microstructure-based structural colors of a compact disc (CD) onto the film. Similarly, a polyvinyl siloxane imprint of the silver ant body shall make it possible to transfer cooling functionality to technically relevant surfaces. FTIR spectroscopy measurements of the reflectance of flat and structured chitosan films allow for a qualitative assessment of the infrared emissivity. A minor decrease in reflectance in a relevant wavelength range gives an indication that it is feasible to increase the emissivity and, therefore, decrease the surface temperature purely through surface-induced functionalities. [ABSTRACT FROM AUTHOR]

Published

2024

20. Biomimetic Studies on the Antimicrobial Activity of Some Biocides Based on Garlic and Lavender in Surface Waters.

Author

Grinzeanu, Mădălina, Orbuleț, Oanamari Daniela, Dăncilă, Annette Madelene, Bobirică, Constantin, Modrogan, Cristina, Bobirică, Liliana, and Pandele, Mădălina Andreea

Abstract

For a given aquatic ecosystem that will be used as a water source, it is necessary to establish the quality of the water from a microbiological point of view by identifying the pathogens present in the water. The aim of this study was to determine and analyze the antimicrobial activity of some biocides derived from garlic (garlic–methanol extract) and lavender (lavender–water extract). Their efficiency was evaluated at different concentrations and contact times. Initially, through specific laboratory analyses, the microbiological characteristics of the river were determined. Biomimetic studies on the antimicrobial activity of biocides based on garlic and lavender in surface waters involved detailed exploration of how the natural antimicrobial properties of these plants can be effectively utilized to treat water contaminated with harmful microorganisms. Both the contact time and the amount of biocide used have a significant effect on the microorganisms of interest. Thus, to describe the degradation rate of coliform bacteria, a pseudo-first-order and zero-order kinetic model was used, r = − (d N / d t) = k o b s · t şi r 0 = k o b s · N 0 = k 0 , where r is the rate of degradation of microorganisms (CFU/min), N0 is the initial number of microorganisms in the aqueous solution (colony-forming unit, CFU), N is the final number of microorganisms after a contact time t (CFU), kobs is the pseudo-first-order rate constant (min−1), t is the contact time (min), r0 is the initial rate of degradation of microorganisms (CFU/min), and k0 is the pseudo-rate constant zero order (min−1). Following 60 min of treatment with 1 mL of lavender-water biocide, the inhibition rate of pathogenic microorganisms in the water reached 59.09%, whereas, under the same conditions, the garlic–methanol biocide achieved an inhibition rate of 40.86%. This study confirms the antimicrobial activity of both lavender and garlic biocides, highlighting their potential in mitigating water pollution caused by pathogens. [ABSTRACT FROM AUTHOR]

Published

2024

21. 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

22. Autonomous self‐healing 3D micro‐suction adhesives for multi‐layered amphibious soft skin electronics.

Author

Lim, Dohyun, Jeong, Min Woo, Min, Hyeongho, Lee, Yeon Soo, Hwang, Gui Won, Jeon, Seung Hwan, Jung, Kyu Ho, Vo, Ngoc Thanh Phuong, Kim, Min‐Seok, Kim, Da Wan, Oh, Jin Young, and Pang, Changhyun

Subjects

GOLD electrodes, STRUCTURAL models, STRUCTURAL design, ROUGH surfaces, HUMAN body, BIOMEDICAL adhesives

Abstract

Autonomously self‐healing, reversible, and soft adhesive microarchitectures and structured electric elements could be important features in stable and versatile bioelectronic devices adhere to complex surfaces of the human body (rough, dry, wet, and vulnerable). In this study, we propose an autonomous self‐healing multi‐layered adhesive patch inspired by the octopus, which possess self‐healing and robust adhesion properties in dry/underwater conditions. To implement autonomously self‐healing octopus‐inspired architectures, a dynamic polymer reflow model based on structural and material design suggests criteria for three‐dimensional patterning self‐healing elastomers. In addition, self‐healing multi‐layered microstructures with different moduli endows efficient self‐healing ability, human‐friendly reversible bio‐adhesion, and stable mechanical deformability. Through programmed molecular behavior of microlevel hybrid multiscale architectures, the bioinspired adhesive patch exhibited robust adhesion against rough skin surface under both dry and underwater conditions while enabling autonomous adhesion restoring performance after damaged (over 95% healing efficiency under both conditions for 24 h at 30°C). Finally, we developed a self‐healing skin‐mountable adhesive electronics with repeated attachment and minimal skin irritation by laminating thin gold electrodes on octopus‐like structures. Based on the robust adhesion and intimate contact with skin, we successfully obtained reliable measurements during dynamic motion under dry, wet, and damaged conditions. [ABSTRACT FROM AUTHOR]

Published

2024

23. Asymmetric fluid flow in helical pipes inspired by shark intestines.

Author

Levin, Ido, Sadaba, Naroa, Nelson, Alshakim, and Keller, Sarah L.

Subjects

BIOMIMETICS, ELASTOMERS, FLUID dynamics, TISSUES, FLUID flow

Abstract

Unlike human intestines, which are long, hollow tubes, the intestines of sharks and rays contain interior helical structures surrounding a cylindrical hole. One function of these structures may be to create asymmetric flow, favoring passage of fluid down the digestive tract, from anterior to posterior. Here, we design and 3D print biomimetic models of shark intestines, in both rigid and deformable materials. We use the rigid models to test which physical parameters of the interior helices (the pitch, the hole radius, the tilt angle, and the number of turns) yield the largest flow asymmetries. These asymmetries exceed those of traditional Tesla valves, structures specifically designed to create flow asymmetry without any moving parts. When we print the biomimetic models in elastomeric materials so that flow can couple to the structure's shape, flow asymmetry is significantly amplified; it is sevenfold larger in deformable structures than in rigid structures. Last, we 3D-print deformable versions of the intestine of a dogfish shark, based on a tomogram of a biological sample. This biomimic produces flow asymmetry comparable to traditional Tesla valves. The ability to influence the direction of a flow through a structure has applications in biological tissues and artificial devices across many scales, from large industrial pipelines to small microfluidic devices. [ABSTRACT FROM AUTHOR]

Published

2024

24. Self‐Assembled Bioinspired Short Metallopeptide Nanostructures for Plausible Biomedical Applications.

Author

Sharma, Shruti, Kautu, Aanand, Kumar, Nikunj, Swain, Narayan, Kumar, Vikas, Singh, Ramesh, Kesharwani, Khushboo, Singh, Narendra, Gupta, Puneet, and Ballabh Joshi, Khashti

Subjects

BIOMIMETICS, METAL ions, TRANSITION metals, STRUCTURAL stability, FUNCTIONAL groups

Abstract

Metal chelation, characterized by its precise interactions with diverse functional groups, assumes a pivotal role in providing structural stability and generating reactive centers within metalloproteins and metallopeptides. This, in turn, orchestrates the architecture and functionality of various biological processes in living organisms. In our biomimetic approach inspired by the intricacies of natural metallopeptides, we have purposefully designed pyridine‐bis‐tyrosine, a concise Metallopeptide Conjugate (sMPC). Demonstrating the capacity to form complexes with various bioactive metal ions, sMPC emerges as a promising tool for advancing our understanding of metal‐binding proteins and catalyzing the development of cutting‐edge biotechnological materials and technologies. Our investigations underscore the hierarchical self‐assembly of these abridged conjugates into toroidal to vesicle nanostructures, influenced by concentration, and their susceptibility to spatial manipulation through metal ion coordination with functional groups. These biocompatible metal peptide complexes and their resultant nanomaterials present specific potential as exceptional therapeutic agents to address problems associated with metal ion deficiencies, offering a facile and low‐cost alternative to traditional metallodrugs. [ABSTRACT FROM AUTHOR]

Published

2024

25. Advanced Biomimetic and Biohybrid Magnetic Micro/Nano‐Machines.

Author

Murali, Nandan, Das, Shashank Bhushan, Yadav, Satyam, Rainu, Simran Kaur, Singh, Neetu, and Betal, Soutik

Subjects

CILIA & ciliary motion, BIOLOGICAL systems, NEWTONIAN fluids, BIOMIMETICS, MICROMOTORS

Abstract

Biomimetic and biohybrid micro/nano‐structures involve the replication and creation of technologies, structures, and materials based on biological systems at the micrometer and nanometer scale. These strategies harness the natural biological principles to develop innovative treatment methods and advanced microstructure devices for noninvasive therapies. In this study, a detailed overview of fabrication processes, magnetically assisted locomotive techniques, and potential applications of biomimetic and biohybrid micro/nano‐machines are presented. The latest advancements in magnetically actuated biomimetic structures, such as annelid‐worm‐like microswimmers, jellyfish‐shaped microparticles, fish‐shaped microswimmers, and walnut‐shaped micromotors are explored. Additionally, the magnetic biohybrid systems, including sunflower seed‐based micro‐perforators, nanomotors extracted from the bamboo stem, sperm cell‐based micromotors, bacteria‐based robots, scaffold‐based microrobots, DNA‐based micromotors, microalgae‐based microswimmers, and red blood cell‐based microswimmers are also examined. A thorough investigation of the magnetically assisted locomotive behavior of these microstructure devices in biological Newtonian fluids, featuring cork‐screw motion, undulatory motion, surface wrinkling motion, traveling wave‐like motion, and ciliary stroke motion is discussed. Furthermore, unprecedented and innovative treatment methods developed using these minuscule devices such as cervical cancer treatment using tetrapod hybrid sperm micromotors, tissue regeneration using silk fibroin protein‐based magnetic microscale scaffolds, and doxorubicin drug delivery using mushroom‐based microrobots is extensively presented. [ABSTRACT FROM AUTHOR]

Published

2024

26. Bark‐Inspired Functional‐Carbon/Potassium Composite Electrode with Fast Ion Transport Channels for Dendrite‐Free Potassium Metal Batteries.

Author

Zhou, Jun‐Long, Zhao, Lu‐Kang, Lu, Yue, Gao, Xuan‐Wen, Chen, Yue, Liu, Zhao‐Meng, Gu, Qin‐Fen, and Luo, Wen‐Bin

Subjects

KILLER cells, BIOMIMETICS, ION channels, ENERGY density, ENERGY storage, POTASSIUM channels

Abstract

Potassium metal batteries (PMBs) are regarded as viable candidates for future electrochemical energy storage devices with potential high energy density and low cost. However, uncontrollable potassium dendrite growth and huge volume expansion severely inhibit the practical application of PMBs. Herein, inspired by the structure and functionalities of tree bark, an antimony (Sb) nano‐clusters decorated N‐doped interconnected carbon nanospheres/potassium composite electrode with biomimetic fast ionic channels is developed to realize the dendrite‐free potassium metal batteries. The composite electrode provides abundant nucleation sites and interconnected ion transport channels, facilitating rapid ion transport kinetics and highly reversible potassium plating/stripping behaviors. Consequently, the assembled symmetric cell exhibits an ultra‐long cycle life (1100 h at 1.0 mA cm−2/1.0 mAh cm−2) in carbonate electrolyte. Moreover, the K full cells demonstrate enhanced cycling stability (1500 cycles at 8 C) and rate capacity (117.27 mAh g−1 at 20 C). This novel biomimetic design of composite anode presents an effective and rational approach for achieving stable PMBs. [ABSTRACT FROM AUTHOR]

Published

2024

27. A Biomimetic Sketch-Based Form Finding Tool.

Author

ŞEN BAYRAM, Asena Kumsal and KÖRÜKCÜ, Berfin Aybike

Subjects

LITERATURE reviews, DIGITAL technology, BIOMIMETICS, COMPUTER engineering, WOMEN'S writings

Abstract

Copyright of Urban Academy/ Kent Akademisi is the property of ICAM NETWORK 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

28. Supramolecular fibrillation in coacervates and other confined systems towards biomimetic function.

Author

Sanchez-Fernandez, Adrian, Insua, Ignacio, and Montenegro, Javier

Subjects

CELL physiology, BIOMIMETICS, PHASE separation, INFORMATION sharing, MONOMERS

Abstract

As in natural cytoskeletons, the cooperative assembly of fibrillar networks can be hosted inside compartments to engineer biomimetic functions, such as mechanical actuation, transport, and reaction templating. Coacervates impose an optimal liquid-liquid phase separation within the aqueous continuum, functioning as membrane-less compartments that can organise such self-assembling processes as well as the exchange of information with their environment. Furthermore, biological fibrillation can often be controlled or assisted by intracellular compartments. Thus, the reconstitution of analogues of natural filaments in simplified artificial compartments, such as coacervates, offer a suitable model to unravel, mimic, and potentially exploit cellular functions. This perspective summarises the latest developments towards assembling fibrillar networks under confinement inside coacervates and related compartments, including a selection of examples ranging from biological to fully synthetic monomers. Comparative analysis between coacervates, lipid vesicles, and droplet emulsions showcases the interplay between supramolecular fibres and the boundaries of the corresponding compartment. Combining inspiration from natural systems and the custom properties of tailored synthetic fibrillators, rational monomer and compartment design will contribute towards engineering increasingly complex and more realistic artificial protocells. The bottom-up reconstitution of natural filaments within simplified artificial cellular compartments, such as coacervates, offer a model to study, mimic, and potentially exploit cellular functions. Here, the authors summarize the latest developments towards assembling confined fibrillar networks inside coacervates and related compartments, including a selection of examples ranging from biological to fully synthetic building blocks. [ABSTRACT FROM AUTHOR]

Published

2024

29. Biomimetic Remineralization of Dental Hard Tissues via Amyloid‐Like Protein Matrix Composite with Amorphous Calcium Phosphate.

Author

Pang, Yanyun, Fu, Chengyu, Zhang, Daixing, Li, Min, Zhou, Xinye, Gao, Yingtao, Lin, Kaiye, Hu, Bowen, Zhang, Kai, Cai, Qing, Yang, Peng, Liu, Yongchun, and Zhang, Xu

Subjects

BIOMINERALIZATION, BIOMIMETICS, EXTRACELLULAR matrix proteins, DENTINAL tubules, ETHYLENE glycol, CALCIUM phosphate

Abstract

Numerous remineralizing coatings aim to prevent or treat early enamel lesions and occlude exposed dentinal tubules (DTs). Nevertheless, the pace of remineralization is inadequate, and the mechanical robustness of the newly established mineral layer fails to match the inherent strength. In this study, a biomimetic mineralization strategy aimed at replicating key events in biological mineralization, specifically focusing on the organic–inorganic composite matrix, is proposed. The material utilizes Tris(2‐carboxyethyl)phosphine (TCEP), which serves a dual role: stabilized amorphous calcium phosphate (ACP) (ACP@TCEP) nanoparticles as its inorganic component, and catalyzing the cleavage of intramolecular disulfide bonds in poly(ethylene glycol) (PEG) grafted lysozyme (lyso‐PEG) to facilitate the formation of an amyloid‐like protein matrix composite with ACP (ACP@lyso‐PEG nanocomplexes). ACP@lyso‐PEG nanocomplexes can rapidly and efficiently form an enamel‐like remineralization layer on the surface of damaged dental hard tissue, reaching ≈4.205 µm thickness after 3 days of acid‐etched enamel. Furthermore, achieving a depth of DTs occlusion exceeding 60 µm after 5 days, using a simple immersion process. The resulting mineralized layer exhibits mechanical strength comparable to natural teeth. This study introduces a conceptual biomimetic mineralization strategy for effective enamel repair or DTs occlusion in clinical practices, and offers potential insights into the mechanisms of biomineral formation. [ABSTRACT FROM AUTHOR]

Published

2024

30. Electrochemical Monitoring of Real‐Time Vesicle Dynamics Induced by Tau in a Confined Nanopipette.

Author

Chen, Ke‐Le, Yu, Ru‐Jia, Zhong, Cheng‐Bing, Wang, Ziyi, Xie, Bao‐Kang, Ma, Hui, Ao, Mingjun, Zheng, Peng, Ewing, Andrew G., and Long, Yi‐Tao

Subjects

SYNAPTIC vesicles, BIOMIMETICS, CURRENT fluctuations, NEURAL transmission, LIPIDS

Abstract

The microtubule‐associated protein tau participates in neurotransmission regulation via its interaction with synaptic vesicles (SVs). The precise nature and mechanics of tau's engagement with SVs, especially regarding alterations in vesicle dynamics, remain a matter of discussion. We report an electrochemical method using a synapse‐mimicking nanopipette to monitor vesicle dynamics induced by tau. A model vesicle of ~30 nm is confined within a lipid‐modified nanopipette orifice with a comparable diameter to mimic the synaptic lipid environment. Both tau and phosphorylated tau (p‐tau) present two‐state dynamic behavior in this biomimetic system, showing typical ionic current oscillation, induced by lipid‐tau interaction. The results indicate that p‐tau has a stronger affinity to the lipid vesicles in the confined environment, blocking the vesicle movement to a higher degree. Taken together, this method bridges a gap for sensing synaptic vesicle dynamics in a confined lipid environment, mimicking vesicle movement near the synaptic membrane. These findings contribute to understanding how different types of tau protein regulate synaptic vesicle motility and to underlying its functional and pathological behaviours in disease. [ABSTRACT FROM AUTHOR]

Published

2024

31. Electrochemical Monitoring of Real‐Time Vesicle Dynamics Induced by Tau in a Confined Nanopipette.

Author

Chen, Ke‐Le, Yu, Ru‐Jia, Zhong, Cheng‐Bing, Wang, Ziyi, Xie, Bao‐Kang, Ma, Hui, Ao, Mingjun, Zheng, Peng, Ewing, Andrew G., and Long, Yi‐Tao

Subjects

SYNAPTIC vesicles, BIOMIMETICS, CURRENT fluctuations, NEURAL transmission, LIPIDS

Abstract

The microtubule‐associated protein tau participates in neurotransmission regulation via its interaction with synaptic vesicles (SVs). The precise nature and mechanics of tau's engagement with SVs, especially regarding alterations in vesicle dynamics, remain a matter of discussion. We report an electrochemical method using a synapse‐mimicking nanopipette to monitor vesicle dynamics induced by tau. A model vesicle of ~30 nm is confined within a lipid‐modified nanopipette orifice with a comparable diameter to mimic the synaptic lipid environment. Both tau and phosphorylated tau (p‐tau) present two‐state dynamic behavior in this biomimetic system, showing typical ionic current oscillation, induced by lipid‐tau interaction. The results indicate that p‐tau has a stronger affinity to the lipid vesicles in the confined environment, blocking the vesicle movement to a higher degree. Taken together, this method bridges a gap for sensing synaptic vesicle dynamics in a confined lipid environment, mimicking vesicle movement near the synaptic membrane. These findings contribute to understanding how different types of tau protein regulate synaptic vesicle motility and to underlying its functional and pathological behaviours in disease. [ABSTRACT FROM AUTHOR]

Published

2024

32. Tracking photoinduced charge separation in a perfluorinated Zn-tetraphenylporphyrin sensitizer.

Author

Cruz Neto, Daniel H., Gotico, Philipp, Tran, Thu-Trang, Szantai, Caroline, Halime, Zakaria, Sircoglou, Marie, Soto, Juan, Steenkeste, Karine, Peláez, Daniel, Pino, Thomas, and Ha-Thi, Minh-Huong

Subjects

RESONANCE Raman effect, OPTICAL resonance, BIOMIMETICS, CHEMICAL reactions, LIGHT absorption, ELECTRON donors, TIME-resolved spectroscopy, CHARGE transfer

Abstract

The development of artificial biomimetic systems with real-world applications relies on a profound understanding of all photophysical and photochemical processes taking place upon light absorption by a chromophoric unit. Efficient photoinduced charge separation in photosensitizers or specialized photocatalysts is the process triggering most of the chemical reactions in the production of solar fuels, and hence, its proper characterization is of utmost importance. In this work, we investigated photoinduced charge separation processes in a perfluorinated Zn-tetraphenylporphyrin photosensitizer (ZnF20). Ascorbate and 1,4-diazabicyclo[2.2.2]octane (DABCO) were used as reversible electron donors for nanosecond-resolved pump–probe experiments using both optical absorption and resonance Raman scattering as probes. Our results indicate that in spite of similar charge separation efficiencies, the DABCO-containing system exhibits a much faster kinetics of charge-separated state formation and decay. This is attributed to its inherent ability to coordinate to the metal center. Time-resolved resonance Raman measurements allow for the detection of vibrational modes specific to both the triplet excited state of ZnF20 and its reduced state, complementing transient absorption data to fully characterize the charge separation process. [ABSTRACT FROM AUTHOR]

Published

2024

33. Biomimetic Structurally Colored Film for High‐Performance Radiative Cooling.

Author

Lin, Yiyi, Qin, Chaohua, Liang, Zixian, Lin, Wanying, Wang, Jizhuang, and Li, Dan

Subjects

BIOMIMETICS, HYPOTHERMIA, PHASE separation, COOLING systems, COOLING

Abstract

In recent years, passive radiative cooling has garnered considerable attention as a sustainable thermal regulation without relying on external energy sources, thus mitigating pollutants generation. However, an intrinsic limitation of these cooling systems lies in the reflective glare, often characterized by an ivory or silvery appearance. This drawback limits their practical application, especially where both functional efficiency and aesthetic appeal are pivotal. Herein, a biomimetic approach inspired by Saharan silver ants' thermoregulatory capabilities is adopted. These ants, equipped with distinctive triangular‐shaped hair, maintain body temperature lower than the ambient air. Leveraging insights from this natural model, a reusable silicon template is employed to fabricate a metasurface structural colored film with a triangular prism array structure using thermoplastic polyurethane (TPU) and the phase separation technique. The film demonstrates an average emissivity of 96% within the atmospheric window and an average solar reflectivity of 93%, leading to a maximum temperature reduction of 8.6 °C during daytime and 5.9 °C at night. Furthermore, the film displays stretchability and mechanical resilience, bolstered by the microscale prismatic structure enhancing superhydrophobicity. This work introduces a biomimetic strategy aimed at augmenting thermal emission while reconciling the challenge of achieving visual appealand high radiative cooling performance. [ABSTRACT FROM AUTHOR]

Published

2024

34. Adhesion of retinal cells to gold surfaces by biomimetic molecules.

Author

Shpun, Gal, Markus, Amos, Farah, Nairouz, Zalevsky, Zeev, and Mandel, Yossi

Subjects

NEUROPROSTHESES, CELL adhesion, X-ray photoelectron spectroscopy, EXTRACELLULAR matrix, CONTACT angle

Abstract

Background: Neural cell-electrode coupling is crucial for effective neural and retinal prostheses. Enhancing this coupling can be achieved through surface modification and geometrical design to increase neuron-electrode proximity. In the current research, we focused on designing and studying various biomolecules as a method to elicit neural cell-electrode adhesion via cellspecific integrin mechanisms. Methods: We designed extracellular matrix biomimetic molecules with different head sequences (RGD or YIGSR), structures (linear or cyclic), and spacer lengths (short or long). These molecules, anchored by a thiol (SH) group, were deposited onto gold surfaces at various concentrations. We assessed the modifications using contact angle measurements, fluorescence imaging, and X-ray Photoelectron Spectroscopy (XPS). We then analyzed the adhesion of retinal cells and HEK293 cells to the modified surfaces by measuring cell density, surface area, and focal adhesion spots, and examined changes in adhesion-related gene and integrin expression. Results: Results showed that YIGSR biomolecules significantly enhanced retinal cell adhesion, regardless of spacer length. For HEK293 cells, RGD biomolecules were more effective, especially with cyclic RGD and long spacers. Both cell types showed increased expression of specific adhesion integrins and proteins like vinculin and PTK2; these results were in agreement with the adhesion studies, confirming the cell-specific interactions with modified surfaces. Conclusion: This study highlights the importance of tailored biomolecules for improving neural cell adhesion to electrodes. By customizing biomolecules to foster specific and effective interactions with adhesion integrins, our study provides valuable insights for enhancing the integration and functionality of retinal prostheses and other neural implants. [ABSTRACT FROM AUTHOR]

Published

2024

35. Complex Pathways Drive Pluripotent Fmoc‐Leucine Self‐Assemblies.

Author

Paul, Subir, Gayen, Kousik, Cantavella, Pau Gil, Escuder, Beatriu, and Singh, Nishant

Subjects

BIOMIMETICS, METASTABLE states, BIOMOLECULES, MONOMERS, HYDROGELS

Abstract

Nature uses complex self‐assembly pathways to access distinct functional non‐equilibrium self‐assemblies. This remarkable ability to steer same set of biomolecules into different self‐assembly states is done by avoiding thermodynamic pit. In synthetic systems, on demand control over 'Pathway Complexity' to access self‐assemblies different from equilibrium structures remains challenging. Here we show versatile non‐equilibrium assemblies of the same monomer via alternate assembly pathways. The assemblies nucleate using non‐classical or classical nucleation routes into distinct metastable (transient hydrogels), kinetic (stable hydrogels) and thermodynamic structures [(poly)‐crystals and 2D sheets]. Initial chemical and thermal inputs force the monomers to follow different assembly pathways and form soft‐materials with distinct molecular arrangements than at equilibrium. In many cases, equilibrium structures act as thermodynamic sink which consume monomers from metastable structures giving transiently formed materials. This dynamics can be tuned chemically or thermally to slow down the dissolution of transient hydrogel, or skip the intermediate hydrogel altogether to reach final equilibrium assemblies. If required this metastable state can be kinetically trapped to give strong hydrogel stable over days. This method to control different self‐assembly states can find potential use in similar biomimetic systems to access new materials for various applications. [ABSTRACT FROM AUTHOR]

Published

2024

36. Complex Pathways Drive Pluripotent Fmoc‐Leucine Self‐Assemblies.

Author

Paul, Subir, Gayen, Kousik, Cantavella, Pau Gil, Escuder, Beatriu, and Singh, Nishant

Subjects

BIOMIMETICS, METASTABLE states, MONOMERS, NUCLEATION, EQUILIBRIUM

Abstract

Nature uses complex self‐assembly pathways to access distinct functional non‐equilibrium self‐assemblies. This remarkable ability to steer same set of biomolecules into different self‐assembly states is done by avoiding thermodynamic pit. In synthetic systems, on demand control over 'Pathway Complexity' to access self‐assemblies different from equilibrium structures remains challenging. Here we show versatile non‐equilibrium assemblies of the same monomer via alternate assembly pathways. The assemblies nucleate using non‐classical or classical nucleation routes into distinct metastable (transient hydrogels), kinetic (stable hydrogels) and thermodynamic structures [(poly)‐crystals and 2D sheets]. Initial chemical and thermal inputs force the monomers to follow different assembly pathways and form soft‐materials with distinct molecular arrangements than at equilibrium. In many cases, equilibrium structures act as thermodynamic sink which consume monomers from metastable structures giving transiently formed materials. This dynamics can be tuned chemically or thermally to slow down the dissolution of transient hydrogel, or skip the intermediate hydrogel altogether to reach final equilibrium assemblies. If required this metastable state can be kinetically trapped to give strong hydrogel stable over days. This method to control different self‐assembly states can find potential use in similar biomimetic systems to access new materials for various applications. [ABSTRACT FROM AUTHOR]

Published

2024

37. Exploring the Esterase Catalytic Activity of Minimalist Heptapeptide Amyloid Fibers.

Author

Roldan, L., Rodríguez‐Santiago, L., Didier‐Marechal, J., and Sodupe, M.

Subjects

AMINO acid sequence, EXERGONIC reactions, CATALYTIC activity, BIOMIMETICS, ACTIVATION energy

Abstract

This paper investigates the esterase activity of minimalist amyloid fibers composed of short seven‐residue peptides, IHIHIHI (IH7) and IHIHIQI (IH7Q), with a particular focus on the role of the sixth residue position within the peptide sequence. Through computational simulations and analyses, we explore the molecular mechanisms underlying catalysis in these amyloid‐based enzymes. Contrary to initial hypotheses, our study reveals that the twist angle of the fiber, and thus the catalytic site's environment, is not notably affected by the sixth residue. Instead, the sixth residue interacts with the p‐nitrophenylacetate (pNPA) substrate, particularly through its −NO2 group, potentially enhancing catalysis. Quantum mechanics/molecular mechanics (QM/MM) simulations of the reaction mechanism suggest that the polarizing effect of glutamine enhances catalytic activity by forming a stabilizing network of hydrogen bonds with pNPA, leading to lower energy barriers and a more exergonic reaction. Our findings provide valuable insights into the intricate interplay between peptide sequence, structural arrangement, and catalytic function in amyloid‐based enzymes, offering potentially valuable information for the design and optimization of biomimetic catalysts. [ABSTRACT FROM AUTHOR]

Published

2024

38. Biomimetic Metal–Organic Framework Gated Nanoplatform for Sonodynamic Therapy against Extensively Drug Resistant Bacterial Lung Infection.

Author

Huang, Jianling, Hong, Xiuwen, Chen, Sixi, He, Yucong, Xie, Lixu, Gao, Fenglin, Zhu, Chenghua, Jin, Xiao, Yan, Haihao, Ye, Yongxia, Shao, Mingyue, Du, Xingran, and Feng, Ganzhu

Subjects

POLYMYXIN B, MESENCHYMAL stem cells, ACINETOBACTER baumannii, BIOMIMETICS, BACTERIAL diseases

Abstract

Novel antimicrobial strategies are urgently needed to treat extensively drug‐resistant (XDR) bacterial infections due to the high mortality rate and lack of effective therapeutic agents. Herein, nanoengineered human umbilical cord mesenchymal stem cells (hUC‐MSCs), named PMZMU, are designed as a sonosensitizer for synergistic sonodynamic‐nano‐antimicrobial therapy against gram‐negative XDR bacteria. PMZMU is composed of a bacterial targeting peptide (UBI29‐41) modified hUC‐MSCs membrane (MSCm), a sonosensitizer meso‐tetra(4‐car‐boxyphenyl) porphine doped mesoporous organo‐silica nanoparticle and an acidity‐responsive metal–organic framework ZIF‐8. This innovative formulation enables efficient loading of polymyxin B, reduces off‐target drug release, increases circulation and targeting efficacy, and generates reactive oxygen species upon ultrasound irradiation. PMZMU exhibits remarkable in vitro inhibitory activity against four XDR bacteria: Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa (PA), and Escherichia coli. Taking advantage of the bacterial targeting ability of UBI29‐41 and the inflammatory chemotaxis of hUC‐MSC, PMZMU can be precisely delivered to lung infection sites thereby augmenting polymyxin B concentration. PMZMU‐mediated sonodynamic therapy significantly reduces bacterial burden, relieves inflammatory damage by promoting the polarization of macrophages toward M2 phenotype, and improves survival rates without introducing adverse events. Overall, this study offers promising strategies for treating deep‐tissue XDR bacterial infections, and guides the design and optimization of biomimetic nanomedicine. [ABSTRACT FROM AUTHOR]

Published

2024

39. Enhanced strength, toughness and reliability in crab exoskeleton–inspired 3D-printed porous thermoplastics.

Author

Keleş, Özgür, Anderson, Eric H., Tan, Timothy L., Wu, Cheng-Lun, and Karakoç, Alp

Subjects

FUSED deposition modeling, BIOMIMETICS, BIOMATERIALS, IMPACT (Mechanics), MULTISCALE modeling

Abstract

Purpose: Fused deposition modeling enables multiscale structure control. However, most of this structural space is unexplored. Specifically, the impact of biomimetic porous structures on the mechanical behavior and reliability of common thermoplastics are unclear. In this work, porous structures inspired by the multifunctional crab exoskeleton were 3D-printed with different raster orientations, including fully rotating rasters similar to Bouligand structures found in biological materials. Tensile tests and simulations were performed to observe the stochastic behavior of fracture properties and to reveal the underlying origins of mechanical reliability in biomimetic porous systems. Design/methodology/approach: Tensile tests were performed on 3D-printed porous structures with four different rasters. These rasters were biomimetic Bouligand, semi-Bouligand, 00 raster and 45°/−45° raster. In addition, two different sets were manufactured to observe the impact of contours on the mechanical behavior. A total of 137 tensile tests were performed. A total of 88 finite element simulations were executed using Abaqus built-in Hashin damage initiation criterion and energy-based damage evolution law. Weibull analyses were performed to quantify the stochastic properties. Findings: Biomimetic Bouligand structure is effective in increasing fracture strength. Average fracture strength of the Bouligand structure was 33% higher compared to the default 45°/−45° and 10% higher compared to 00 rasters. Variations in strength were lower in Bouligand structure compared to the default 45°/−45° raster. However, 00 raster had the highest Weibull modulus m = 54 compared to Bouligand m = 25 and 45°/−45° m = 17. Simulations showed that Bouligand structure is effective in increasing the mechanical reliability through local damage accumulation around the holes. The simulated Weibull modulus of the Bouligand structure was 40 compared to the moduli of other rasters that ranged from 18 to 25. Practical implications: The mechanical reliability of porous Bouligand structures is higher compared to other rasters, which makes the biomimetic structure a better choice for industrial applications. Contours decrease the strength and strain at failure for 3D-printed porous structures. Bouligand structures with rotating raster orientations increased strength and strain at failure when contours are present in the porous structure. Originality/value: To the best of the authors' knowledge, this is the first study showing the effects of biomimetic raster orientations on the mechanical behavior and the effects of contours on the tensile fracture properties of 3D-printed porous acrylonitrile butadiene styrene using tensile tests and fracture simulations. This is the first study applying composite fracture model to anisotropic porous 3D-printed polymers. [ABSTRACT FROM AUTHOR]

Published

2024

40. 增材制造仿生结构的力学性能优化及其功能 设计研究进展.

Author

李家雨, 付宇彤, 李元庆, and 付绍云

Subjects

BIOMIMETICS, BIOMEDICAL engineering, THREE-dimensional printing, RAILROADS, MORPHOLOGY, BIOMIMETIC materials

Abstract

Copyright of Acta Materiae Compositae Sinica is the property of Acta Materiea Compositae Sinica Editorial Department 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

41. Recent Advances in Smart Self‐Assembled Bioinspired Hydrogels: A Bridging Weapon for Emerging Health Care Applications from Bench to Bedside.

Author

Ahuja, Rishabh, Shivhare, Vaibhav, and Konar, Anita Dutt

Subjects

SMART materials, BIOMIMETICS, TRANSLATIONAL research, BIOMEDICAL materials, WOUND healing

Abstract

Stimuli‐responsive low molecular weight hydrogel interventions for Biomedical challenges are a rapidly evolving paradigm in the bottom‐up approach recently. Peptide‐based self‐assembled nano biomaterials present safer alternatives to their non‐degradable counterparts as demanded for today's most urged clinical needs.Although a plethora of work has already been accomplished, programming hydrogelators with appropriate functionalities requires a better understanding as the impact of the macromolecular structure of the peptides and subsequently, their self‐assembled nanostructures remain unidentified. Henceforth this review focuses on two aspects: Firstly, the underlying guidelines for building biomimetic strategies to tailor scaffolds leading to hydrogelation along with the role of non‐covalent interactions that are the key components of various self‐assembly processes. In the second section, it is aimed to bring together the recent achievements with designer assembly concerning their self‐aggregation behaviour and applications mainly in the biomedical arena like drug delivery carrier design, antimicrobial, anti‐inflammatory as well as wound healing materials. Furthermore, it is anticipated that this article will provide a conceptual demonstration of the different approaches taken towards the construction of these task‐specific designer hydrogels. Finally, a collective effort among the material scientists is required to pave the path for the entrance of these intelligent materials into medicine from bench to bedside. [ABSTRACT FROM AUTHOR]

Published

2024

42. Investigating the nonlinear dynamics of photosensitive Belousov–Zhabotinsky gels via bifurcation analyses.

Author

Rajput, Vandana and Dayal, Pratyush

Subjects

MECHANICAL oscillations, FREQUENCIES of oscillating systems, BELOUSOV-Zhabotinskii reaction, RUTHENIUM catalysts, BIOMIMETICS, OSCILLATING chemical reactions

Abstract

Controlling the dynamics of active stimuli-responsive smart materials is essential to replicate the biomimetic functionalities at different length scales for a variety of biological systems-based applications. Photosensitive Belousov–Zhabotinsky (BZ) gels, powered by a nonlinear chemical oscillator, called a BZ reaction are one of the stimuli-responsive smart materials in demand due to their ability to continuously transduce chemical oscillations into mechanical deformations. The chemical oscillations in a BZ reaction and subsequent mechanical oscillations in photosensitive BZ gels occur due to the redox cycle of photosensitive ruthenium complex-based catalysts. In this work, our objective is to identify how the behavior of photosensitive BZ gels can be tuned and used for biomimetic applications by investigating its dynamical characteristics using bifurcation analyses. Specifically, we use the normal form approach and perform linear and nonlinear stability analyses to identify high-order bifurcations by computing higher-order Lyapunov and frequency coefficients. We revealed the existence of domains that encompass coexisting stable and unstable limit cycles (LCs), which merge to form a semi-stable LC at the limit point of cycle (LPC). Their existence shows how a slight variation in the BZ gel recipe can significantly alter its dynamics. Subsequently, we quantify the amplitude and frequency of oscillations in different domains under the effect of variation of BZ reaction formulations. We believe that the outcomes of our work serve as an efficient template for the design and control of BZ gel-based applications. The usage of a normal form and a systematic representation of nonlinear dynamics allow our framework to be extended for other nonlinear dynamical systems. [ABSTRACT FROM AUTHOR]

Published

2024

43. Flow field characteristics and drag reduction performance of high–low velocity stripes on the biomimetic imbricated fish scale surfaces.

Author

Chen, Dengke, Cui, XianXian, and Chen, Huawei

Subjects

FISHES, FLUID dynamics, DRAG reduction, BIOMIMETICS, BIOLOGICAL systems

Abstract

Improving energy efficiency and cost reduction is a perennial challenge in engineering. Natural biological systems have evolved unique functional surfaces or special physiological functions over centuries to adapt to their complex environments. Among these biological wonders, fish, one of the oldest vertebrate groups, has garnered significant attention due to its exceptional fluid dynamics capabilities. Researchers are actively exploring the potential of fish skin's distinctive structural and material characteristics in reducing resistance. In this study, models of biomimetic imbricated fish scale are established, and the evolution characteristics of the flow field and drag reduction performance on these bionic surfaces are investigated. The results showed a close relationship between the high–low velocity stripes generated and the fluid motion by the imbricated fish scale surface. The stripes' prominence increases with the spacing of the adjacent scales and tilt angle of the fish scale, and the velocity amplitude of the stripes decreases as the exposed length of the imbricated fish scale surface increases. Moreover, the biomimetic imbricated fish scale surface can decrease the velocity gradient and thereby reduce the wall shear stress. The insights gained from the fish skin‐inspired imbricated fish surface provide valuable perspectives for an in‐depth analysis of fish hydrodynamics and offer fresh inspiration for drag reduction and antifouling strategies in engineering applications. [ABSTRACT FROM AUTHOR]

Published

2024

44. Functional Conception of Biomimetic Artificial Reefs Using Parametric Design and Modular Construction.

Author

Maslov, Dmytro, Cruz, Fabio, Pinheiro, Marisa, Miranda, Tiago, Valente, Isabel Brito, Ferreira, Vasco, and Pereira, Eduardo

Subjects

ARTIFICIAL reefs, BIOMIMETICS, SUBMERGED structures, MODULAR construction, MARINE ecology, MARINE biodiversity

Abstract

Artificial reefs featuring different shapes and functions have been deployed around the world, causing impacts on marine ecosystems. However, the approaches typically used to deliver topological complexity, flexibility and expanding requirements to prospective structures during the initial design stages are not well established. The aim of this study was to highlight the advantages and provide evidence on how modularity and parametric design can holistically leverage the performance of multifunctional artificial reefs (MFARs). In particular, the goal was to develop a parametric design for MFAR and establish a direct relationship between specific design parameters and the MFAR target functions or design requirements. The idea of implementing the parametric design for generating the initial biomimetic geometry of the individual modular unit was explored. Furthermore, possible ways of manipulating the geometric parameters of the individual module and the whole assembly were proposed. The findings suggest that, by adopting the developed procedure and the examples studied, several functions may be reached within a single assembly: the promotion of marine biodiversity restoration, the support of scientific platforms with various sensors, as well as the development of recreational diving and of touristic attraction areas. Acquired knowledge suggests that the concept of a nature-like design approach was developed for artificial reefs with varying scales, complexity and functions, which widens the range of possibilities of how smart design of human-made underwater structures may contribute to benefiting the near shore ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

45. Biomimetic design to encourage children's aptitude for reading and counteract attention deficit.

Author

Amato, Camilla

Subjects

ATTENTION-deficit hyperactivity disorder, BIOMIMETICS, ARCHITECTURAL design, SEA urchins, CULTURE media (Biology), HABIT

Abstract

Copyright of Cuadernos del Centro de Estudios de Diseño y Comunicación is the property of Cuadernos del Centro de Estudios de Diseno y Comunicacion 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

46. Communicative intelligence: from biology to design perspectives.

Author

Langella, Carla, Borghese, Flavia, and Perricone, Valentina

Subjects

ANIMAL communication, SOCIAL hierarchies, COMMUNICATION models, BIOMIMETICS, HUMAN-animal communication

Abstract

Copyright of Cuadernos del Centro de Estudios de Diseño y Comunicación is the property of Cuadernos del Centro de Estudios de Diseno y Comunicacion 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

47. The use of artificial intelligence as a strategy for natural mimicry in design artifacts.

Author

Silva Nogueira, Antônio Henrique and Vieira de Arruda, Amilton José

Subjects

ARTIFICIAL intelligence, BIOMIMETICS, BOTANY, PHILOSOPHERS, NINETEEN sixties

Abstract

Copyright of Cuadernos del Centro de Estudios de Diseño y Comunicación is the property of Cuadernos del Centro de Estudios de Diseno y Comunicacion 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

48. Adaptive façades bioinspired by the nastic movements of plants.

Author

Andrade, Tarciana, Nuno Beirão, José, Vieira de Arruda, Amilton José, Santos, Hilma, and Costa, Jullyene

Subjects

SHAPE memory alloys, SMART materials, BIOMIMETICS, AIR flow, LAMINATED metals

Abstract

Copyright of Cuadernos del Centro de Estudios de Diseño y Comunicación is the property of Cuadernos del Centro de Estudios de Diseno y Comunicacion 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

49. Comparison of Biomechanical and Microstructural Properties of Aortic Graft Materials in Aortic Repair Surgeries.

Author

Sun, Haoliang, Cheng, Zirui, Guo, Xiaoya, Gu, Hongcheng, Tang, Dalin, and Wang, Liang

Subjects

POLYETHYLENE fibers, ULTIMATE strength, SCANNING electron microscopes, BIOMIMETICS, MECHANICAL failures, PERICARDIUM

Abstract

Mechanical mismatch between native aortas and aortic grafts can induce graft failure. This study aims to compare the mechanical and microstructural properties of different graft materials used in aortic repair surgeries with those of normal and dissected human ascending aortas. Five types of materials including normal aorta (n = 10), dissected aorta (n = 6), human pericardium (n = 8), bovine pericardium (n = 8) and Dacron graft (n = 5) were collected to perform uniaxial tensile testing to determine their material stiffness, and ultimate strength/stretch. The elastin and collagen contents in four tissue groups except for Dacron were quantified by histological examinations, while the material ultrastructure of five material groups was visualized by scanning electron microscope. Statistical results showed that three graft materials including Dacron, human pericardium and bovine pericardium had significantly higher ultimate strength and stiffness than both normal and dissected aortas. Human and bovine pericardia had significantly lower ultimate stretch than native aortas. Histological examinations revealed that normal and diseased aortic tissues had a significantly higher content of elastic fiber than two pericardial tissues, but less collagen fiber content. All four tissue groups exhibited lamellar fiber ultrastructure, with aortic tissues possessing thinner lamella. Dacron was composed of densely coalesced polyethylene terephthalate fibers in thick bundles. Aortic graft materials with denser fiber ultrastructure and/or higher content of collagen fiber than native aortic tissues, exhibited higher ultimate strength and stiffness. This information provides a basis to understand the mechanical failure of aortic grafts, and inspire the design of biomimetic aortic grafts. [ABSTRACT FROM AUTHOR]

Published

2024

50. 与蝠永相伴.

Author

杨德红, 刘少康, 王坤, 秦琦, 范文捷, 焦明立, and 杨本勇

Subjects

NIGHT vision, SEED dispersal, BIOMIMETICS, POISONS, CRITICAL thinking, ECHOLOCATION (Physiology)

Abstract

Copyright of University Chemistry is the property of Peking University, College of Chemistry & Molecular Engineering 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