Your search keyword '"biomimetic"' showing total 5,481 results

1. 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

Published

2024

2. Speaking valve with integrated biomimetic overpressure release and acoustic warning signal.

Author

Knorr, N., Auth, P., Kruppert, S., Stahl, C. A., Lücking, K. M., Tauber, F., and Speck, T.

Abstract

Speaking valves enable tracheostomy patients to speak naturally. However, improper use may cause dangerous overpressure, leading to severe complications or even patient's death. We address this life-threatening issue by creating a biomimetic speaking valve, which incorporates an integrated overpressure valve that automatically opens when reaching critical pressure levels. To enhance safety, we integrated a whistle module to provide an audible alert for medical staff. Fundamental research on the Utricularia vulgaris trapdoor inspired our abstracted valve form. Through a comprehensive analysis using generalized linear mixed-effect models, we examined various membrane parameter effects on the function of the biomimetic overpressure valve. This enabled us to adjust the valve's opening pressure to cater to patient's unique requirements, thus potentially saving lives by applying a solution from nature. [ABSTRACT FROM AUTHOR]

Published

2024

3. Bioinspired nickel‐cysteine‐methoxy polyethylene glycol metallopolymer water solubility and electrochemical properties.

Author

Yang, Xiyue, Dong, Bowei, Zhang, Jingmei, and Wang, Yongxiang

Subjects

HYDROGEN evolution reactions, POLYETHYLENE glycol, AQUEOUS solutions, SOLUBILITY, ELECTROCHEMISTRY

Abstract

The exploitation of remarkable hydrogen evolution reaction (HER) catalysts that perform at rates comparable with that of platinum but utilize earth‐abundant metals in a green solvent (water) has garnered considerable interest. Inspired by enzymes, water‐soluble metallopolymers have recently emerged as highly promising HER catalysts, generally exhibiting high HER rates in aqueous solutions. However, challenges remain in the synthesis of metallopolymers and many artificial hydrogen evolution catalysts still rely on organic solvents. This study proposes incorporating water‐soluble methoxy polyethylene glycol at both ends of a nickel–cysteine metal complex through a classical esterification reaction. The resulting nickel metallopolymer demonstrates considerable water solubility (103.9 mg mL−1) under room temperature. Moreover, the stable metallopolymer exhibits an irreversible reduction peak between −0.6 and − 0.8 V, indicating HER activity in acidic and neutral environments. The excellent water solubility of this metallopolymer catalyst provides a basis for subsequent research and has practical applications in the field of HER catalysts. [ABSTRACT FROM AUTHOR]

Published

2024

4. Fabrication of a tri-layer scaffold with dual release of heparin and PRP for tissue engineering of small‐diameter blood vessels.

Author

Zargar Kharazi, Anousheh, Ghebleh, Aida, and Shariati, Laleh

Subjects

*FUNCTIONALLY gradient materials, *PLATELET-rich plasma, *TISSUE engineering, *HEPARIN, *ELASTIC modulus

Abstract

A tri-layer scaffold was fabricated according to functionally graded materials (FGM) theory from poly(glycerol sebcate)/poly(L-lactic acid) blend by the increasing polylactic acid ratio from the inner to the outer layer. Heparin and platelet-rich plasma were loaded in separate layers to achieve proper remodeling and patency. The scaffold showed a linear degradation trend. The elastic modulus was 13.8 ± 1.11 Mpa that was in the favorable range for constructing artificial vessels. The integrity of the layers was preserved due to its FGM structure. The scaffold showed full blood compatibility by minimal platelet adhesion and hemolysis due to relatively slow release of Heparin. [ABSTRACT FROM AUTHOR]

Published

2024

5. A digital hardware system for real-time biorealistic stimulation on in vitro cardiomyocytes.

Author

Faure, Pierre-Marie, Tixier-Mita, Agnès, and Levi, Timothée

Abstract

Every year, cardiovascular diseases cause millions of deaths worldwide. These diseases involve complex mechanisms that are difficult to study. To remedy this problem, we propose to develop a heart–brain platform capable of reproducing the mechanisms involved in generating the heartbeat. The platform will be designed to operate in real time, with the most economical and integrated design possible. To achieve this, we are implementing highly biologically coherent cellular models on FPGA, which we interconnect with in vitro cell cultures. In our case, we are using the Maltsev–Lakatta cell model, which describes the behavior of the pacemaker cells responsible for the heart rhythm, to stimulate a cardiomyocyte culture. [ABSTRACT FROM AUTHOR]

Published

2024

6. Self‐Oxygenated Biomimetic Nanozyme for Tumor Catalytic Immunotherapy.

Author

Zhang, Baohua, Yuan, Ye, Xin, Qi, Wang, Shuyu, Feng, Yiming, Yan, Xiyun, Fan, Tianli, Jiang, Bing, and Yue, Yale

Subjects

*GLUCOSE oxidase, *BIOMIMETICS, *BACTERIAL cell walls, *SYNTHETIC enzymes, *TUMOR growth

Abstract

The treatment of solid tumors remains a significant challenge due to the complex, immunosuppressive tumor microenvironment (TME). This manuscript introduces the self‐oxygenated biomimetic nanozyme system, SS‐MSN@Au‐BOM, which innovatively combines catalytic therapy with immunotherapy to modulate the TME for enhanced therapeutic efficacy. Employing mesoporous silicon nanoparticles doped with disulfide bonds, the system integrates gold nanozymes that exhibit glucose oxidase (GOx)‐like and peroxidase (POD)‐like activities, along with a catalase (CAT) function derived from bacterial outer membrane (BOM) coatings. SS‐MSN@Au‐BOM significantly disrupted tumor growth by catalyzing endogenous hydrogen peroxide to generate cytotoxic ROS and essential oxygen, enhancing intratumoral ROS levels while alleviating hypoxia. This catalytic action facilitates immunogenic cell death, enhances dendritic cell maturation, and T‐cell activation. Notably, the system shows excellent biocompatibility, effective tumor targeting, and prolonged systemic circulation. SS‐MSN@Au‐BOM offers a dual‐functional approach that effectively disrupts the TME and promotes robust antitumor immunity. This study paves the way for further clinical investigation and the development of enzyme‐based therapeutics, potentially transforming the landscape of cancer treatment. [ABSTRACT FROM AUTHOR]

Published

2024

7. Osteoinductively Functionalized 3D‐Printed Scaffold for Vertical Bone Augmentation in Beagle Dogs.

Author

Wang, Ting, Xu, Gaoli, Zhang, Chuankai, Forouzanfar, Tymour, Liang, Junwei, Pan, Yulei, Shen, Chenxi, Wu, Gang, and Lin, Haiyan

Subjects

*BEAGLE (Dog breed), *HYOID bone, *BONE density, *BONE morphogenetic proteins, *BONE grafting, *MEMBRANE filters

Abstract

ABSTRACT Objective Materials and Methods Results Conclusions To evaluate the efficacy of 3D‐printed scaffolds that were osteoinductively functionalized with a bone morphogenetic protein 2 (BMP‐2)‐incorporated biomimetic calcium phosphate particles (BMP‐2‐inc. BpNcCaP)/hyaluronic acid (HA) composite gel in vertical bone augmentation in beagle dogs.Four Beagle dogs were used in this study. Three months after the extraction of 1st, 2nd, 3rd, and 4th premolars at both sides of the lower jaws of Beagle dogs, one or two critical‐size vertical bone defects (4 mm vertical bone defect without buccal and lingual bone) on each side were surgically created. The defects were randomly subjected to the following groups: (1) Control (without bone‐defect‐filling materials); (2) 3D scaffold; (3) BMP2‐inc. BpNcCaP/HA‐functionalized 3D scaffold. Six weeks post‐surgery, samples were harvested and subjected to micro‐CT and histomorphometric analyses.The struts of the BMP2‐inc. BpNcCaP/HA‐func. 3D scaffold were covered by a thick layer of cemented irregular particles with an average pore size at 327 ± 27 μm. The BpNcCaP/HA‐func. 3D scaffold group bore significantly higher bone volume, bone volume fraction, trabecular number, trabecular thickness, bone mineral density, connectivity density, and bone volumes in three directions (mesiodistal, buccolingual, and apicocoronal) when compared with the groups of Control and 3D scaffold. Moreover, the BMP2‐inc. BpNcCaP/HA‐func. 3D scaffold group bore significantly lower trabecular separation and exhibited significantly higher bone‐to‐scaffold contact percentage and newly formed bone area percentage within pores in comparison with 3D scaffold.BMP2‐inc. BpNcCaP/HA‐func. 3D scaffold dramatically enhanced vertical alveolar bone augmentation, which suggests a promising application potential of BMP2‐inc. BpNcCaP/HA‐func. 3D scaffold in dental clinic. [ABSTRACT FROM AUTHOR]

Published

2024

8. The Clinical Efficacy and Safety of ErhBMP‐2/BioCaP/β‐TCP as a Novel Bone Substitute Using the Tooth‐Extraction‐Socket‐Healing Model: A Proof‐of‐Concept Randomized Controlled Trial.

Author

Wei, Lingfei, Sun, Yuanyuan, Yu, Dedong, Pieterse, Herman, Wismeijer, Daniel, Liu, Yuelian, and Wu, Yiqun

Subjects

*BONE morphogenetic proteins, *BONE substitutes, *BONE grafting, *DENTAL implants, *BONE density, *DENTAL extraction

Abstract

ABSTRACT Aim Materials and Methods Results Conclusion This first randomized controlled trial in humans aimed to assess the efficacy and safety of low‐dosage Escherichia coli‐derived recombinant human bone morphogenetic protein 2 (ErhBMP‐2)‐incorporated biomimetic calcium phosphate coating‐functionalized β‐TCP (ErhBMP‐2/BioCaP/β‐TCP) as a novel bone substitute using the tooth‐extraction‐socket‐healing model.Forty patients requiring dental implants after single‐root tooth extraction were enrolled in this study and randomly assigned into three groups: ErhBMP‐2/BioCaP/β‐TCP (N = 15), β‐TCP (N = 15) and natural healing (N = 10). New bone volume density from histomorphometric analyses was evaluated 6 weeks post‐operatively as the primary outcome, and other histomorphometric analyses, alveolar bone and soft‐tissue changes were the secondary outcomes. Safety parameters included adverse events, soft‐tissue healing, oral health impact profile, serum BMP‐2 concentrations and other laboratory tests.The findings revealed a significant increase in new bone volume density in patients treated with ErhBMP‐2/BioCaP/β‐TCP compared to those receiving β‐TCP alone. The required bone augmentation procedures during implant placement surgery in the ErhBMP‐2/BioCaP/β‐TCP group were significantly less than in the natural healing group. There were no significant differences in safety parameters among the three groups.This clinical trial primarily proved the safety and efficacy of ErhBMP‐2/BioCaP/β‐TCP as a promising bone substitute. [ABSTRACT FROM AUTHOR]

Published

2024

9. Breathable, Adhesive, and Biomimetic Skin‐Like Super Tattoo.

Author

Li, Chuqi, Tan, Zhiyuan, Shi, Xiaohu, Song, Dekui, Zhao, Yan, Zhang, Yan, Zhao, Zihan, Zhang, Weifeng, Qi, Jiongyang, Wang, Yifang, Wang, Xin, Tan, Zhenquan, and Liu, Nan

Subjects

*SUBSTRATES (Materials science), *TATTOOING, *ELECTROMYOGRAPHY, *DEGLUTITION disorders, *PERMEABILITY

Abstract

Electronic tattoo, capable of imperceivably acquiring bio‐electrical signals from the body, is broadly applied in healthcare and human‐machine interface. Tattoo substrate, the foundation of electronic tattoo, is expected to be mechanically mimetic to skin, adhesive, and breathable, and yet remains highly challenging to achieve. Herein, the study mimics human skin and design a breathable, adhesive, and mechanically skin‐like super tattoo substrate based on an ultra‐thin film (≈2 µm). Similar to skin, super tattoo demonstrates strain‐adaptive stiffening properties with high tear energy (5.4 kJ·m−2) and toughness (1.3 MJ·m−3). Superior to skin, it exhibits high adhesion, ionic conductivity, and permeability. A variety of conductive electrodes can be processed on it, showing the universality toward an ideal platform for electronic tattoo with stable and low contact impedance. Super tattoo‐based electrodes can imperceivably and accurately monitor weak electromyography (EMG) of swallowing on the junction, providing effective guidance for rehabilitation training of dysphagia. [ABSTRACT FROM AUTHOR]

Published

2024

10. Biomimetic Superhydrophobic Triboelectric Surface Prepared by Interfacial Self‐Assembly for Water Harvesting.

Author

Zhang, Puyang, Zhang, Song, Li, Xiuzhen, Liu, Tao, Zhao, Tong, Wang, Jinlong, Luo, Bin, Cai, Chenchen, Liu, Yanhua, Shao, Yuzheng, Du, Guoli, Wang, Shuangfei, and Nie, Shuangxi

Subjects

*WATER harvesting, *TRIBOELECTRICITY, *SUPERHYDROPHOBIC surfaces, *WATER shortages, *MASS transfer

Abstract

Extracting water from air offers a promising route to address the global challenge of water scarcity. However, bionic engineering surfaces for water harvesting often struggle with efficiently coordinating droplet nucleation and desorption. The recently emerging triboelectric effect at the liquid–solid interface offers a novel approach for developing bionic fog harvesting surfaces. In this study, inspired by Namib Desert beetles and lotus leaves, a biomimetic superhydrophobic surface with nanoscale hydrophilic domains is prepared via interfacial self‐assembly, exhibiting heterogeneous wettability for effective water harvesting. The essence of interfacial self‐assembly lies in the synergy of non‐covalent interaction forces, driving the self‐assembly of nanoparticles into surface micro‐nano hierarchical structures, thereby regulating wettability and increasing potential nucleation sites. Additionally, the triboelectric effect can directly utilize the triboelectric charges to facilitate droplet migration. The triboelectric effect can be generated by flexible mechanical input induced by walking, which enhances interfacial mass transfer, thereby rapidly improving droplet removal and achieving a 39.02% increase in water harvesting efficiency. This study has opened up a new breakthrough for the design of portable and efficient water harvesting systems. [ABSTRACT FROM AUTHOR]

Published

2024

11. A comprehensive design for biomimetic behavior of robotic head.

Author

Minh Trieu, Nguyen and Truong Thinh, Nguyen

Abstract

AbstractIn robotics and human-robot interaction, the ability to express emotions and respond accurately to human emotions is essential. An important aspect of this ability involves controlling the robot’s facial actuators in a way that resonates with human emotions. This study systematically presented the construction of a robot head based on the theoretical foundation of human sustainability. Facial landmarks are extracted for various purposes, such as to determine anthropometric metrics for robot head design, a comprehensive design for the robotic head is proposed in this study including anthropometric measurements used as a theoretical basis for the design, the calculations, and design, control system, electricity, and robot skin are presented. The robotic head with 24 degrees of freedom (DoF) aims to express all human emotions, signals are fed back from strain gauge sensors and cameras to calibrate the response of the robot’s prosthetic muscles. Strain gauge sensors are set up at locations with large deformations to double-check the functioning of prosthetic muscles. The two experiments are set up to evaluate the completeness of emotions, the results showed that both experiments achieved 93.88% and 91.85% respectively. [ABSTRACT FROM AUTHOR]

Published

2024

12. Biomimetic Modular Honeycomb with Enhanced Crushing Strength and Flexible Customizability.

Author

Shen, Lumin, Wu, Yuanzhi, Ye, Tuo, Gao, Tianyu, Zheng, Shanmei, Long, Zhihao, Ren, Xi, Zhang, Huangyou, Huang, Junwen, and Liu, Kai

Subjects

*HONEYCOMB structures, *SPECIFIC gravity, *LIMIT theorems, *MODULAR forms, *ENERGY dissipation

Abstract

The integration of biomimetic principles into the sophisticated design of honeycomb structures has gained significant traction. Inspired by the natural reinforcement mechanisms observed in tree stems, this research introduces localized thickening to the conventional honeycombs, leading to the development of variable-density honeycomb blocks. These blocks are strategically configured to form modular honeycombs. Initially, the methodology for calculating the relative density of the new design is meticulously detailed. Following this, a numerical model based on the plastic limit theorem, verified experimentally, is used to investigate the in-plane deformation models of modular honeycomb under the low- and high-velocity impact and to establish a theoretical framework for compressive strength. The results confirm that the theoretical predictions for crushing strength in the modular honeycomb align closely with numerical findings across both low- and high-velocity impacts. Further investigation into densification strain, energy absorption, and gradient strategy is conducted using both simulation and experimental approaches. The outcomes indicate that the innovative design outperforms conventional honeycombs by significantly enhancing the crushing strength under low-velocity impacts through the judicious arrangement of honeycomb blocks. Additionally, with a negligible difference in densification strains, the modular honeycomb demonstrates superior energy dissipation capabilities compared to its conventional counterparts. At a strain of 0.85, the modular honeycomb's energy absorption capacity improves by 36.68% at 1 m/s and 25.47% at 10 m/s compared to the conventional honeycomb. By meticulously engineering the arrangement of sub-honeycombs, it is possible to develop a modular honeycomb that exhibits a multi-plateau stress response under uniaxial and biaxial compression. These advancements are particularly beneficial to the development of auto crash absorption systems, high-end product transportation packaging, and personalized protective gear. [ABSTRACT FROM AUTHOR]

Published

2024

13. A Deep Learning Biomimetic Milky Way Compass.

Author

Tao, Yiting, Lucas, Michael, Perera, Asanka, Teague, Samuel, McIntyre, Timothy, Ogunwa, Titilayo, Warrant, Eric, and Chahl, Javaan

Subjects

*MILKY Way, *DEEP learning, *FIELD research, *INSECTS, *ALGORITHMS

Abstract

Moving in straight lines is a behaviour that enables organisms to search for food, move away from threats, and ultimately seek suitable environments in which to survive and reproduce. This study explores a vision-based technique for detecting a change in heading direction using the Milky Way (MW), one of the navigational cues that are known to be used by night-active insects. An algorithm is proposed that combines the YOLOv8m-seg model and normalised second central moments to calculate the MW orientation angle. This method addresses many likely scenarios where segmentation of the MW from the background by image thresholding or edge detection is not applicable, such as when the moon is substantial or when anthropogenic light is present. The proposed YOLOv8m-seg model achieves a segment mAP@0.5 of 84.7 % on the validation dataset using our own training dataset of MW images. To explore its potential role in autonomous system applications, we compare night sky imagery and GPS heading data from a field trial in rural South Australia. The comparison results show that for short-term navigation, the segmented MW image can be used as a reliable orientation cue. There is a difference of roughly 5–10° between the proposed method and GT as the path involves left or right 90° turns at certain locations. [ABSTRACT FROM AUTHOR]

Published

2024

14. Recent advances in flexible self-oscillating actuators.

Author

Jingjing Li, Wenjin Guo, Weiqiang Zhao, Yutian Zhu, Jie Bai, Zhigang Xia, Xiang Zhou, and Zunfeng Liu

Subjects

*ACTUATORS, *CHEMICAL reactions, *ROBOTICS, *ARTIFICIAL intelligence, *TECHNOLOGICAL innovations

Abstract

Soft actuators are constituted by a type of intelligent materials, and they can generate reversible mechanical motions under external stimuli. They usually achieve continuous actuation by manual turning on or off the power supply, which significantly increases the operation complexity. In contrast, self-oscillating actuators can achieve autonomous motions under constant stimuli, and have recently attained great advancements, as well as promoted the development of autonomous soft robotics. In this review, the latest achievements of soft oscillators are summarized. First, the self-oscillating mechanisms mainly including oscillating chemical reactions and self-shadowing-induced mechanical negative feedback loops are discussed. The oscillators constructed with various materials and configurations, driven by different stimuli and applied in different fields are then presented in detail. Finally, the difficulties and hopes of oscillators are presented. Overall, self-oscillating actuators are in the stage of vigorous development, and we believe that in the future, they will be used in various fields and make many scenarios more intelligent and autonomous. [ABSTRACT FROM AUTHOR]

Published

2024

15. Construction of a thermoresponsive molecularly imprinted biomimetic hydrogel-based virus sensor and non-invasive cyclable detection of EV71.

Author

Gong, Hang, Xu, Luru, Yang, Xi, Chen, Chunyan, Chen, Feng, and Cai, Changqun

Subjects

*DETECTION limit, *HYDROGELS, *IMPRINTED polymers, *MONOMERS, *DETECTORS, *EQUILIBRIUM

Abstract

A thermoresponsive molecularly imprinted hydrogel sensor was constructed for the specific selective recognition of enterovirus 71 (EV71). Due to the introduction of the thermosensitive monomer N-isopropylacrylamide (NIPAM), when the imprinted hydrogel is incubated with the virus at 37℃, the surface specific imprinting cavity will specifically recognize and capture the target virus EV71. When the temperature rises to 45℃, the combined EV71 is rapidly released due to changes in the shape and function of the imprinted sites. The MIP hydrogel-based viral sensor developed recognized, captured, and released the target virus in a non-invasive way. The imprinting factor of the target virus was 5.2, suggesting high selectivity, and the detection limit was 7.1 fM, suggesting high sensitivity. Detection was rapid, as adsorption equilibrium was achieved within 30 min. This method provides a new sustainable avenue for the simple and rapid detection of viruses. [ABSTRACT FROM AUTHOR]

Published

2024

16. 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

17. 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

18. Materials-driven strategies in bacterial engineering.

Author

Paternò, Giuseppe Maria

Subjects

MEMBRANE potential, CLEAN energy, SUSTAINABILITY, MOLECULAR spectroscopy, ENGINEERS

Abstract

This perspective article focuses on the innovative field of materials-based bacterial engineering, highlighting interdisciplinary research that employs material science to study, augment, and exploit the attributes of living bacteria. By utilizing exogenous abiotic material interfaces, researchers can engineer bacteria to perform new functions, such as enhanced bioelectric capabilities and improved photosynthetic efficiency. Additionally, materials can modulate bacterial communities and transform bacteria into biohybrid microrobots, offering promising solutions for sustainable energy production, environmental remediation, and medical applications. Finally, the perspective discusses a general paradigm for engineering bacteria through the materials-driven modulation of their transmembrane potential. This parameter regulates their ion channel activity and ultimately their bioenergetics, suggesting that controlling it could allow scientists to hack the bioelectric language bacteria use for communication, task execution, and environmental response. [ABSTRACT FROM AUTHOR]

Published

2024

19. Comparison of various chitosan-based in situ forming gels with sodium fluoride varnish for enamel biomineralization: an in-vitro pH cycling model.

Author

Rafiee, Azade, Memarpour, Mahtab, Amiri, Milad, Azadi, Amir, Fekri, Neda, Mozafari, Negin, and Razmjouei, Faranak

Subjects

*FIELD emission electron microscopy, *FLUORIDE varnishes, *DENTAL enamel, *SODIUM fluoride, *VARNISH & varnishing, *AMELOBLASTS

Abstract

This study aimed to evaluate chitosan (CS)-based formulations loaded with 5% sodium fluoride (NaF) and/or 10% nanohydroxyapatite (nHA) to remineralize the demineralized primary tooth enamel surface. Ninety enamel blocks were demineralized and were divided into six groups (n = 15): (1) CS-based hydrogel, (2) CS-based hydrogel loaded with NaF, (3) CS-based hydrogel loaded with nHA, (4) CS-based hydrogel loaded with NaF and nHA, (5) 5% NaF varnish, and (6) negative control with no intervention. After intervention, the specimens were pH cycled by 2 h immersion in demineralizing solution and 22 h immersion in remineralizing solution for 8 days. The remineralization effects were evaluated by Vickers microhardness measurements and field emission scanning electron microscopy coupled with energy-dispersive X-ray spectrometry (FESEM-EDS). The best mean ± SD percentage microhardness recovery in remineralized enamel (%REMH) was found in group 4 (56.90 ± 5.49). The %REMH of groups 2 (30.74 ± 3.51) and 5 (29.23 ± 5.65) were statistically the same (p = 0.943). FESEM images confirmed partial coverage of the porous demineralized enamel with a newly formed mineralized layer. Based on EDS findings, the Ca/P ratio values of the treated enamel surfaces with CS-based hydrogels ranged between 1.71 and 1.87, and the highest F content was noticed in group 2 (1.02 ± 0.03). Although, all tested CS-based hydrogels demonstrated the potential to repair demineralized enamel, nHA- and NaF-containing CS-based hydrogel showed the highest remineralization effect. We infer that this new hybrid hydrogel is a potentially useful dental material for tooth biomineralization. [ABSTRACT FROM AUTHOR]

Published

2024

20. Revolutionizing electrospinning: Sustainable solutions through deep eutectic solvents in biopolymer processing.

Author

Frąckowiak, Patrycja, Jędrzejczak, Eryk, Kaspryszyn, Filip, Jesionowski, Teofil, and Wysokowski, Marcin

Abstract

Electrospinning is currently one of the most used techniques for obtaining various types of nanofibers. In the era of sustainable development, it is essential to utilize environmentally friendly raw materials and solvents. This review summarizes the current state of the art in biopolymer electrospinning using deep eutectic solvents. To date, there have not been too many studies on the simultaneous application of these mixtures and biopolymers in the electrospinning process. Nevertheless, the use of natural origin raw materials and the replacement of conventional organic solvents with deep eutectic solvents appear promising in this technique due to many attractive properties of both the mixtures and biopolymers. This article aims to inspire scientists to further research in this direction, related to the development of electrospinning techniques aimed at reducing the negative environmental impact. [ABSTRACT FROM AUTHOR]

Published

2024

21. Antimicrobial, anti‐inflammatory, and antioxidant evaluations of ammonium and phosphonium salts based on poly(vinylbenzyl chloride‐co‐acrylonitrile).

Author

Kenawy, El‐Refaie, Azaam, Mohamed M., Kamoun, Elbadawy A., Khattab, Samar A., Kemell, Marianna, EL‐Moslamy, Shahira H., and Tenhu, Heikki

Abstract

Polymers with ammonium or phosphonium salts have been known to possess antimicrobial activity. Herein, synthesis of poly(vinylbenzyl chloride‐co‐acrylonitrile) (P(VBC‐co‐AN)) is reported via a free radical polymerization by employing AIBN as initiator. The copolymer was then quaternized using triethylamine, triphenylphosphine, and tributylphosphine. The triphenylphosphonium salt was selected for further modification, on which the polyacrylonitrile chains were reacted with two different amines: tris (2‐aminoethylamine) and diethylenetriamine. The copolymerization, quaternization, and amination reactions were confirmed by spectroscopic and morphologic analysis besides the thermal features. The water uptake of modified polymers was investigated, where tributylphosphonium salt (KH4) showed the highest water uptake capacity (41 g/g). The antimicrobial assay findings demonstrated that all the evaluated copolymers displayed a wide range of antimicrobial activity against different multidrug resistant human pathogens, for example polymer coded KH4 containing tributylphosphonium salt showed the highest growth inhibition rates against Staphylococcus aureus and Staphylococcus epidermidis populations, recorded 87% and 72%; respectively. The anti‐inflammatory activity revealed that all the quaternized copolymers have a protection effect of human erythrocyte membrane against lysis. Antioxidant results revealed that all quaternized copolymers displayed 1,1‐diphenyl‐2‐picryl hydrazyl scavenging activities. Among the studied copolymers, aminated copolymer coded (KH6) exhibited the highest scavenging activity, with IC50 ~ 120 μg/mL. [ABSTRACT FROM AUTHOR]

Published

2024

22. A Super‐Foldable Lithium‐Ion Full Battery.

Author

Dong, Kangze, Zan, Guangtao, Zhou, Junchen, Manshaii, Farid, Pu, Shu, Chai, Shanshan, Baik, Jeong Min, Wu, Qingsheng, Wen, Ming, Wu, Tong, and Chen, Jun

Subjects

*BIOELECTRONICS, *CATHODES, *ANODES, *ELECTRODES, *STORAGE batteries

Abstract

Developing foldable power sources with simple transport and storage remains a significant challenge and an urgent need for the advancement of next‐generation wearable bioelectronics. In this study, super‐foldable lithium‐ion batteries are developed by integrating biomimetic methods, which effectively address the challenges of stress dispersion and mark a breakthrough in the field of super‐foldable devices. A synchronous three‐level biomimetic coupling technology is introduced and employed a strategy of radial compounding, gel‐electrostatic molding, and temperature‐programmed co‐pyrolysis. This approach allows us to simultaneously prepare a super‐foldable multi‐level “lotus structure” cathode and a highly compatible super‐foldable “peapods” structure anode. Remarkably, even after 500 000 cycles of repeated folding tests, the full battery maintains a high level of capacity stability, and the galvanostatic charge/discharge curves also exhibit a high degree of consistency. Furthermore, this battery can power an LED clock for over 2870 continuous minutes while undergoing in situ dynamic reciprocating folding, highlighting its substantial promise for practical applications. The super‐foldable battery represents a full‐chain innovation, extending from the super‐foldable substrate to the super‐foldable electrodes, and culminating in a super‐foldable full battery. [ABSTRACT FROM AUTHOR]

Published

2024

23. Frictional Properties of Biomimetic Micro-Hexagonal-Textured Surfaces Interacting with Soft Counterfaces under Dry and Wet Conditions.

Author

Qatmeera, Zain Eldin, Bajjaly, Agnes, and Kasem, Haytam

Subjects

*SLIDING friction, *TECHNOLOGICAL innovations, *STATIC friction, *CHICKENS, *BIOMATERIALS

Abstract

Biomimetic micro-hexagonal-textured surfaces have sparked interest for their application in fields that demand high friction and adhesion, such as micro-robotics and biomedicine. Despite extensive research conducted on this specific microstructure, its friction behavior against soft counterfaces remains a topic that has not been fully investigated yet. This study examines how micro-hexagon textures behave when they come into contact with engineered and biological materials like gelatin and chicken skin in dry and wet conditions. The results show clearly that under dry contact conditions, flat surfaces generate higher friction compared to hexagon micropattern surfaces. Under wet conditions, hexagon micropattern surfaces generate higher friction compared to flat surfaces. In wet conditions specifically, the static coefficient of friction is up to 13 times greater than that of a flat specimen against glass, up to 11 times greater against gelatin, and up to 6 times greater against chicken skin. For the dynamic coefficient of friction, the patterned surface demonstrates a maximum increase by a factor of 28 against glass, 11 against gelatin, and 5 against chicken skin. These results further develop our knowledge of these hexagon micropattern surfaces and pave the way for their utilization in future technological advancements in which soft and wet counterfaces are to be considered, such as in biomedical applications that can benefit from increased friction in wet conditions for better control and stability. [ABSTRACT FROM AUTHOR]

Published

2024

24. Developing New Peptides and Peptide–Drug Conjugates for Targeting the FGFR2 Receptor-Expressing Tumor Cells and 3D Spheroids.

Author

Biggs, Mary A., Das, Amrita, Goncalves, Beatriz G., Murray, Molly E., Frantzeskos, Sophia A., Hunt, Hannah L., Phan, Chau Ahn N., and Banerjee, Ipsita A.

Subjects

*FIBROBLAST growth factor receptors, *FIBROBLAST growth factor 2, *SURFACE plasmon resonance, *BIOMIMETICS, *MOLECULAR docking

Abstract

In this work, we utilized a biomimetic approach for targeting KATO (III) tumor cells and 3D tumoroids. Specifically, the binding interactions of the bioactive short peptide sequences ACSAG (A-pep) and LPHVLTPEAGAT (L-pep) with the fibroblast growth factor receptor (FGFR2) kinase domain was investigated for the first time. Both peptides have been shown to be derived from natural resources previously. We then created a new fusion trimer peptide ACSAG-LPHVLTPEAGAT-GASCA (Trimer-pep) and investigated its binding interactions with the FGFR2 kinase domain in order to target the fibroblast growth factor receptor 2 (FGFR2), which is many overexpressed in tumor cells. Molecular docking and molecular dynamics simulation studies revealed critical interactions with the activation loop, hinge and glycine-rich loop regions of the FGFR2 kinase domain. To develop these peptides for drug delivery, DOX (Doxorubicin) conjugates of the peptides were created. Furthermore, the binding of the peptides with the kinase domain was further confirmed through surface plasmon resonance studies. Cell studies with gastric cancer cells (KATO III) revealed that the conjugates and the peptides induced higher cytotoxicity in the tumor cells compared to normal cells. Following confirmation of cytotoxicity against tumor cells, the ability of the conjugates and the peptides to penetrate 3D spheroids was investigated by evaluating their permeation in co-cultured spheroids grown with KATO (III) and colon tumor-associated fibroblasts (CAFs). Results demonstrated that Trimer-pep conjugated with DOX showed the highest permeation, while the ACSAG conjugate also demonstrated reasonable permeation of the drug. These results indicate that these peptides may be further explored and potentially utilized to create drug conjugates for targeting tumor cells expressing FGFR2 for developing therapeutics. [ABSTRACT FROM AUTHOR]

Published

2024

25. Experimental and Theoretical Investigation of the Coordination of 8-Hydroxquinoline Inhibitors to Biomimetic Zinc Complexes and Histone Deacetylase 8 (HDAC8).

Author

Baudino, Anthony M., Ciaccio, Harris F., Turski, Michael J., Akins, Xavier A., Sun Cao, Phoebus, Morales, Elisa, Sommer, Roger D., Johnson, Adam R., Wink, Donald J., Grice, Kyle A., and Stone, Kari L.

Subjects

CUTANEOUS T-cell lymphoma, ZINC enzymes, HISTONE deacetylase, ZINC compounds, X-ray crystallography

Abstract

Zinc is integral to diverse biological functions, acting catalytically, structurally, and supportively in essential enzyme cycles, despite its limited amounts in the body. Targeting zinc enzymes with potent drugs, such as Vorinostat, demonstrates the therapeutic efficacy of zinc-binding ligands, notably in cutaneous T-cell lymphoma treatments. Our study merges experimental and theoretical approaches to analyze the coordination of 8-hydroxylquinoline (8HQ) inhibitors with biomimetic zinc complexes and human histone deacetylase 8 (HDAC8), a monozinc hydrolase enzyme. Assessing 10 8HQ derivatives for structural and electronic characteristics against these models, we observe minimal inhibition efficacy, corroborated through protein–ligand docking analyses, highlighting the complexities of inhibitor–zinc enzyme interactions and suggesting intricate noncovalent interactions that are important for ligand binding to enzymes not accounted for in model zinc hydrolase mimics. [ABSTRACT FROM AUTHOR]

Published

2024

26. Biomimetic 3D printing of composite structures with decreased cracking.

Author

Du, Fan, Li, Kai, Li, Mingzhen, Fang, Junyang, Sun, Long, Wang, Chao, Wang, Yexin, Liu, Maiqi, Li, Jinbang, and Wang, Xiaoying

Subjects

COMPOSITE structures, BIOMIMETIC materials, BONE grafting, THREE-dimensional printing, TISSUE engineering, TISSUE scaffolds, POLYCAPROLACTONE

Abstract

The development of tissue engineering and regeneration research has created new platforms for bone transplantation. However, the preparation of scaffolds with good fiber integrity is challenging, because scaffolds prepared by traditional printing methods are prone to fiber cracking during solvent evaporation. Human skin has an excellent natural heat-management system, which helps to maintain a constant body temperature through perspiration or blood-vessel constriction. In this work, an electrohydrodynamic-jet 3D-printing method inspired by the thermal-management system of skin was developed. In this system, the evaporation of solvent in the printed fibers can be adjusted using the temperature-change rate of the substrate to prepare 3D structures with good structural integrity. To investigate the solvent evaporation and the interlayer bonding of the fibers, finite-element analysis simulations of a three-layer microscale structure were carried out. The results show that the solvent-evaporation path is from bottom to top, and the strain in the printed structure becomes smaller with a smaller temperature-change rate. Experimental results verified the accuracy of these simulation results, and a variety of complex 3D structures with high aspect ratios were printed. Microscale cracks were reduced to the nanoscale by adjusting the temperature-change rate from 2.5 to 0.5 °C s−1. Optimized process parameters were selected to prepare a tissue engineering scaffold with high integrity. It was confirmed that this printed scaffold had good biocompatibility and could be used for bone-tissue regeneration. This simple and flexible 3D-printing method can also help with the preparation of a wide range of micro- and nanostructured sensors and actuators. ARTICLE HIGHLIGHTS: • A controllable and cost-effective high-resolution E-jet 3d-printing fabrication technology inspired by skin thermal management was developed. • The solvent-evaporation path in the printed structure and its stress–strain development under the influence of temperature were obtained. • High-aspect-ratio 3D structures with good structural integrity were prepared by adjusting the evaporation of the solvent using the temperature-change rate. • A PCL/PVP scaffold with fiber diameters close to the size of living cells was printed, which exhibited high biocompatibility for bone-tissue regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

27. The variable response to the environment of plant stems as an example of natural intelligence.

Author

Santulli, Carlo

Subjects

PLANT stems, SHEARING force, PLANT species, XYLEM, PHLOEM

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

28. 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

29. A Novel Nano-Hydroxyapatite Agarose-Based Hydrogel for Biomimetic Remineralization of Demineralized Human Enamel: An in-vitro Study

Author

El Moshy S, Radwan IA, Matoug-Elwerfelli M, Abdou A, and Abbass MM

Subjects

agarose hydrogel, biomimetic, enamel matrix derivatives, nano-hydroxy apatite, remineralization, Dentistry, RK1-715

Abstract

Sara El Moshy,1 Israa Ahmed Radwan,1 Manal Matoug-Elwerfelli,2 Ahmed Abdou,3 Marwa MS Abbass1 1Oral Biology Department, Faculty of Dentistry, Cairo University, Cairo, Egypt; 2Pre-clinical Oral Sciences Department, College of Dental Medicine, QU Health, Qatar University, Doha, Qatar; 3Department of Restorative Dentistry, Faculty of Dentistry, Universiti Malaya, Kuala Lumpur, MalaysiaCorrespondence: Manal Matoug-Elwerfelli, College of Dental Medicine, QU Health, Qatar University, Doha, Qatar, Tel +974 44037316, Email melwerfelli@qu.edu.qaPurpose: This study aims to investigate the biomimetic effect of agarose hydrogel loaded with enamel matrix derivative (EMD-agarose) alone or in combination with nano-hydroxyapatite (n-HA-EMD-agarose) on the remineralization of human demineralized enamel.Methods: Extracted human mandibular third molars were sectioned into 54 buccal and lingual halves. Acid-resistant nail varnish was applied to each half, except for two enamel windows. Enamel surface microhardness, energy-dispersive X-ray spectroscopy (EDX), and scanning electron microscopy (SEM) analyses were conducted to evaluate enamel surfaces at baseline, following demineralization with 37% phosphoric acid, and after each hydrogel application and remineralization for two, four, and six days. Remineralization was performed using a phosphate solution at 37°C.Results: At day 6 following remineralization, a statistically significant higher mean microhardness was recorded in n-HA-EMD-agarose hydrogel (260.87 ± 3.52) as compared to EMD-agarose hydrogel (244.63 ± 2.76) (p = 0.027). Similarly, n-HA-EMD-agarose hydrogel showed a higher mean calcium (46.31 ± 2.78), phosphorous (24.92 ± 0.826), and fluoride (0.909 ± 0.053) weight percentage compared to EMD-agarose hydrogel calcium (19.64 ± 1.092), phosphorous (19.64 ± 1.092), and fluoride (0.7033 ± 0.0624) weight percentage (p < 0.05). Further, SEM analysis revealed a substantial deposition of n-HA following the application of the n-HA-EMD-agarose hydrogel, whereas the EMD-agarose exhibited a relatively smooth enamel surface with less visible enamel rods due to mineral deposition.Conclusion: The combined n-HA-EMD-agarose hydrogel demonstrated improved surface microhardness of the remineralized enamel and enhanced mineral content deposition, indicating its potential as a biomimetic approach for dental enamel repair.Keywords: agarose hydrogel, biomimetic, enamel matrix derivatives, nano-hydroxy apatite, remineralization

Published

2024

30. Comparison of various chitosan-based in situ forming gels with sodium fluoride varnish for enamel biomineralization: an in-vitro pH cycling model

Author

Azade Rafiee, Mahtab Memarpour, Milad Amiri, Amir Azadi, Neda Fekri, Negin Mozafari, and Faranak Razmjouei

Subjects

Enamel, Biomimetic, Fluoride, Hydroxyapatites, Chitosan, Remineralization, Medicine, Science

Abstract

Abstract This study aimed to evaluate chitosan (CS)-based formulations loaded with 5% sodium fluoride (NaF) and/or 10% nanohydroxyapatite (nHA) to remineralize the demineralized primary tooth enamel surface. Ninety enamel blocks were demineralized and were divided into six groups (n = 15): (1) CS-based hydrogel, (2) CS-based hydrogel loaded with NaF, (3) CS-based hydrogel loaded with nHA, (4) CS-based hydrogel loaded with NaF and nHA, (5) 5% NaF varnish, and (6) negative control with no intervention. After intervention, the specimens were pH cycled by 2 h immersion in demineralizing solution and 22 h immersion in remineralizing solution for 8 days. The remineralization effects were evaluated by Vickers microhardness measurements and field emission scanning electron microscopy coupled with energy-dispersive X-ray spectrometry (FESEM-EDS). The best mean ± SD percentage microhardness recovery in remineralized enamel (%REMH) was found in group 4 (56.90 ± 5.49). The %REMH of groups 2 (30.74 ± 3.51) and 5 (29.23 ± 5.65) were statistically the same (p = 0.943). FESEM images confirmed partial coverage of the porous demineralized enamel with a newly formed mineralized layer. Based on EDS findings, the Ca/P ratio values of the treated enamel surfaces with CS-based hydrogels ranged between 1.71 and 1.87, and the highest F content was noticed in group 2 (1.02 ± 0.03). Although, all tested CS-based hydrogels demonstrated the potential to repair demineralized enamel, nHA- and NaF-containing CS-based hydrogel showed the highest remineralization effect. We infer that this new hybrid hydrogel is a potentially useful dental material for tooth biomineralization.

Published

2024

31. The role of neuromorphic and biomimetic sensors

Author

Bogue, Rob

Published

2024

32. Evaluation of tribological performance in contact pairs by implementing the biomimetic surface textures with lubricant flow using CFD techniques

Author

Abhilash, Madaparthi, Ramkumar, Penchaliah, and Vengadesan, Sankaranarayanan

Published

2024

33. Study of impact resistance of a novel bio-inspired ceramic-composite structure using finite element simulations.

Author

Feng, Xiangyu and Zhu, Pengzhe

Abstract

The multi-layer armor shell structure of the scaly-foot snail has been proven to be resistant to penetration and perforation. Inspired by the special structure, a novel ceramic-composite impact-resistant structure was proposed. We developed a user-defined subroutine (VUMAT) of the finite element software ABQUS to analyze the progressive damage process and energy dissipation mechanism under impact. It is found that the novel structure features rigid-flexible coupling, both soft and hard layers play a key role in the impact resistance process. Compared with the traditional sandwich structure, the novel structure has better impact resistance under the impact energy of 20 J–80 J. [ABSTRACT FROM AUTHOR]

Published

2024

34. The first composite increment: Dependency on placement technique for interaction behavior with maturing dentin-adhesive bond at pulpal floors in deep occlusal cavities – A comprehensive review

Author

Khamis A. Hassan and Salwa E. Khier

Subjects

behavior, biomimetic, composite resins, debonding, decoupling, dependency, diagonal gap, displacement, dynamics, fiber-insert, first layer, hierarchy, increment-split, occlusal, polymerization shrinkage, postoperative sensitivity, pulpal floor, stress relief, technique, tooth pain, Dentistry, RK1-715

Abstract

Introduction: When the traditional incremental technique is used for direct placement of composite resin in a deep occlusal cavity, each increment (2 mm or thicker) is individually cured where it undergoes hardening and shrinkage. As increments are bonded to all cavity walls, a constrained shrinkage develops in tooth, composite, and/or interfaces. In the first composite increment, this constrained shrinkage generates tensile stresses which are distributed in a nonuniform pattern within that increment, resulting in premature stressing of the dentin bond of the hybrid layer at the pulpal floor before it reaches full maturation. This premature stressing leads to initiation of interfacial debonding and propagation to form a microgap. This behavior is associated with persistent postoperative sensitivity and tooth pain, over the time, which subsequently results in restoration failure. Aims: This paper provides a comprehensive review on the first composite increment and its dependency on placement technique for the interaction behavior with the maturing dentin-adhesive bond at pulpal floors in deep occlusal cavities. Materials and Methods: The dental database was searched, and 59 articles were collected and included in this review, spanning the years from 1984 to 2023. Results and Discussion: Three biomimetic direct restorative techniques were reported in the literature for incrementally restoring large occlusal cavities. These techniques are the decoupling with time, the decoupling with fiber, and the decoupling with split-increment. They all aim at minimizing the generated shrinkage stresses in the first composite increment for protecting the developing dentin bond of the hybrid layer until it reaches full maturation and thus preventing the initiation and propagation of interfacial defects at pulpal floors of deep occlusal cavities. Finally, the restoration is completed by placing and curing successive increments of 1.5 mm each to fill the cavity; their number depends on the cavity depth. These increments can each be cured immediately following placement. Conclusions: In deep occlusal cavities, the interaction behavior between the first composite increment and the maturing dentin-adhesive bond at the pulpal floor depends on the technique used for the increment placement. This behavior is either favorable with the direct biomimetic techniques or unfavorable with the traditional incremental technique. With the direct biomimetic techniques, no premature shrinkage stressing of the dentin bond is induced at the pulpal floor. This prevents the initiation of interfacial debonding and propagation to form microgaps and results in the absence of postoperative sensitivity and persistent tooth pain.

Published

2024

35. Experimental and Theoretical Investigation of the Coordination of 8-Hydroxquinoline Inhibitors to Biomimetic Zinc Complexes and Histone Deacetylase 8 (HDAC8)

Author

Anthony M. Baudino, Harris F. Ciaccio, Michael J. Turski, Xavier A. Akins, Phoebus Sun Cao, Elisa Morales, Roger D. Sommer, Adam R. Johnson, Donald J. Wink, Kyle A. Grice, and Kari L. Stone

Subjects

zinc hydrolases, biomimetic, HDAC, zinc coordination, protein–ligand docking, DFT, Mathematics, QA1-939

Abstract

Zinc is integral to diverse biological functions, acting catalytically, structurally, and supportively in essential enzyme cycles, despite its limited amounts in the body. Targeting zinc enzymes with potent drugs, such as Vorinostat, demonstrates the therapeutic efficacy of zinc-binding ligands, notably in cutaneous T-cell lymphoma treatments. Our study merges experimental and theoretical approaches to analyze the coordination of 8-hydroxylquinoline (8HQ) inhibitors with biomimetic zinc complexes and human histone deacetylase 8 (HDAC8), a monozinc hydrolase enzyme. Assessing 10 8HQ derivatives for structural and electronic characteristics against these models, we observe minimal inhibition efficacy, corroborated through protein–ligand docking analyses, highlighting the complexities of inhibitor–zinc enzyme interactions and suggesting intricate noncovalent interactions that are important for ligand binding to enzymes not accounted for in model zinc hydrolase mimics.

Published

2024

36. A structured biomimetic nanoparticle as inflammatory factor sponge and autophagy-regulatory agent against intervertebral disc degeneration and discogenic pain

Author

Kanglu Li, Wenbo Yang, Xuanzuo Chen, Yihan Yu, Yiran Liu, Feifei Ni, Yan Xiao, Xiangcheng Qing, Sheng Liu, YuXin He, Baichuan Wang, Li Xu, Zengwu Shao, Lei Zhao, Yizhong Peng, and Hui Lin

Subjects

Intervertebral disc degeneration, Targeting nanoparticle, Biomimetic, Discogenic pain, Innervation, Biotechnology, TP248.13-248.65, Medical technology, R855-855.5

Abstract

Abstract Lower back pain (LBP) is a common condition closely associated with intervertebral disc degeneration (IDD), causing a significant socioeconomic burden. Inflammatory activation in degenerated discs involves pro-inflammatory cytokines, dysregulated regulatory cytokines, and increased levels of nerve growth factor (NGF), leading to further intervertebral disc destruction and pain sensitization. Macrophage polarization is closely related to autophagy. Based on these pathological features, a structured biomimetic nanoparticle coated with TrkA-overexpressing macrophage membranes (TMNP@SR) with a rapamycin-loaded mesoporous silica core is developed. TMNP@SR acted like sponges to adsorbe inflammatory cytokines and NGF and delivers the autophagy regulator rapamycin (RAPA) into macrophages through homologous targeting effects of the outer engineered cell membrane. By regulating autophagy activation, TMNP@SR promoted the M1-to-M2 switch of macrophages to avoid continuous activation of inflammation within the degenerated disc, which prevented the apoptosis of nucleus pulposus cells. In addition, TMNP@SR relieved mechanical and thermal hyperalgesia, reduced calcitonin gene-related peptide (CGRP) and substance P (SP) expression in the dorsal root ganglion, and downregulated GFAP and c-FOS signaling in the spinal cord in the rat IDD model. In summary, TMNP@SR spontaneously inhibits the aggravation of disc inflammation to alleviate disc degeneration and reduce the ingress of sensory nerves, presenting a promising treatment strategy for LBP induced by disc degeneration. Graphical Abstract

Published

2024

37. Unveiling the antibacterial potential of nature-inspired material for designing food-related coatings

Author

Yen Dang, Khuong Ba Dinh, Tien Thanh Nguyen, and The Hy Duong

Subjects

antibacterial, antimicrobial, hierarchical structures, bio-inspired, biomimetic, Technology

Abstract

The escalating challenge of antibiotic resistance has driven the innovation of new antibacterial and antifouling materials. Recent developments focus on nature-inspired topographical engineering and nanostructured surfaces to combat resistant bacteria. This review discusses these advances, emphasizing the potential of nanoantibiotics and biopolymers. Nanoantibiotics revitalize drug effectiveness by encapsulating them in nanoparticles, presenting a new strategy to fight pathogens. Biopolymers, eco-friendly and biodegradable, emerge as a sustainable alternative, with applications in food safety and beyond. The exploration of these materials signifies a leap in design, fabrication, and the possibility of cost-effective, large-scale production, highlighting a promising avenue for commercial applications to tackle antibiotic resistance and biofouling effectively.

Published

2024

38. Optimizing alkaline hydrothermal treatment for biomimetic smart metallic orthopedic and dental implants

Author

Hanieh Hadady, Arefin Alam, Indu Khurana, Isha Mutreja, Dhiraj Kumar, Mamilla Ravi Shankar, and Rupak Dua

Subjects

Biomimetic, Orthopedic, Dental, Implants, Nanotechnology, Surface modification., Materials of engineering and construction. Mechanics of materials, TA401-492, Medical technology, R855-855.5

Abstract

Abstract Orthopedic and dental implant failure continues to be a significant concern due to localized bacterial infections. Previous studies have attempted to improve implant surfaces by modifying their texture and roughness or coating them with antibiotics to enhance antibacterial properties for implant longevity. However, these approaches have demonstrated limited effectiveness. In this study, we attempted to engineer the titanium (Ti) alloy surface biomimetically at the nanometer scale, inspired by the cicada wing nanostructure using alkaline hydrothermal treatment (AHT) to simultaneously confer antibacterial properties and support the adhesion and proliferation of mammalian cells. The two modified Ti surfaces were developed using a 4 h and 8 h AHT process in 1 N NaOH at 230 °C, followed by a 2-hour post-calcination at 600 °C. We found that the control plates showed a relatively smooth surface, while the treatment groups (4 h & 8 h AHT) displayed nanoflower structures containing randomly distributed nano-spikes. The results demonstrated a statistically significant decrease in the contact angle of the treatment groups, which increased wettability characteristics. The 8 h AHT group exhibited the highest wettability and significant increase in roughness 0.72 ± 0.08 µm (P

Published

2024

39. Effects of bone surface topography and chemistry on macrophage polarization

Author

Birgün Özcolak, Berkay Erenay, Sedat Odabaş, Klaus D. Jandt, and Bora Garipcan

Subjects

Biomimetic, Bone surface topography, Soft lithography, Surface modification osteoimmunomodulation, Macrophages, Macrophage polarization, Medicine, Science

Abstract

Abstract Surface structure plays a crucial role in determining cell behavior on biomaterials, influencing cell adhesion, proliferation, differentiation, as well as immune cells and macrophage polarization. While grooves and ridges stimulate M2 polarization and pits and bumps promote M1 polarization, these structures do not accurately mimic the real bone surface. Consequently, the impact of mimicking bone surface topography on macrophage polarization remains unknown. Understanding the synergistic sequential roles of M1 and M2 macrophages in osteoimmunomodulation is crucial for effective bone tissue engineering. Thus, exploring the impact of bone surface microstructure mimicking biomaterials on macrophage polarization is critical. In this study, we aimed to sequentially activate M1 and M2 macrophages using Poly-l-Lactic acid (PLA) membranes with bone surface topographical features mimicked through the soft lithography technique. To mimic the bone surface topography, a bovine femur was used as a model surface, and the membranes were further modified with collagen type-I and hydroxyapatite to mimic the bone surface microenvironment. To determine the effect of these biomaterials on macrophage polarization, we conducted experimental analysis that contained estimating cytokine release profiles and characterizing cell morphology. Our results demonstrated the potential of the hydroxyapatite-deposited bone surface-mimicked PLA membranes to trigger sequential and synergistic M1 and M2 macrophage polarizations, suggesting their ability to achieve osteoimmunomodulatory macrophage polarization for bone tissue engineering applications. Although further experimental studies are required to completely investigate the osteoimmunomodulatory effects of these biomaterials, our results provide valuable insights into the potential advantages of biomaterials that mimic the complex microenvironment of bone surfaces.

Published

2024

40. Unicellular Organisms with Versatile Solutions at the Micro‐Scale: Functional Materials and Principles in Ciliates.

Author

Dörr, Lennart, Kohl, Jana, Schweikert, Michael, and Lemloh, Marie‐Louise

Subjects

*BIOMIMETIC materials, *UNICELLULAR organisms, *MANUFACTURING processes, *SUSTAINABLE development, *EUKARYOTES

Abstract

Nature's diversity offers an abundance of promising solutions for novel bioinspired functional materials and systems. In particular, single‐celled organisms exhibit solutions and material properties that are realized at the nano‐ and micro‐scales. Ciliates are ubiquitous unicellular eukaryotes that are well‐adapted to a wide range of environmental conditions. They have developed a large variety of interesting and highly specialized characteristics with unique properties and design. In this review, the background of selected ciliate characteristics is highlighted with respect to material properties and structure‐function relationships. Hierarchically complex mineralized structures, highly efficient sensors for movement and protection, shape‐memory structures, as well as survival and detoxification strategies are to be emphasized. Proposed future bioinspired applications of these properties of ciliates expand the possibilities to more sustainable materials and development processes. [ABSTRACT FROM AUTHOR]

Published

2024

41. Artificial Channels Based on Bottlebrush Polymers: Enhanced Ion Transport Through Polymer Topology Control.

Author

Lin, Yangyang, Wu, Bei, Zeng, Yi, Yuan, Haoxuan, Ji, Changxing, Liu, Ziqi, Sui, Yan, Yin, Tingting, Kong, Xian, Zhu, Yuting, Chen, Jie, and Lang, Chao

Subjects

*POLYMERS, *ION channels, *BILAYER lipid membranes, *BINDING sites, *POLYMER clay

Abstract

Synthetic structures mimicking the transport function of natural ion channel proteins have a wide range of applications, including therapeutic treatments, separation membranes, sensing, and biotechnologies. However, the development of polymer‐based artificial channels has been hampered due to the limitation on available models. In this study, we demonstrate the great potential of bottlebrush polymers as accessible and versatile molecular scaffolds for developing efficient artificial ion channels. Adopting the bottlebrush configuration enhanced ion transport activity of the channels compared to their linear analogs. Matching the structure of lipid bilayers, the bottlebrush channel with a hydrophilic‐hydrophobic‐hydrophilic triblock architecture exhibited the highest activity among the series. Functionalized with urea groups, these channels displayed high anion selectivity. Additionally, we illustrated that the transport properties could be fine‐tuned by modifying the chemistry of ion binding sites. This work not only highlights the importance of polymer topology control in channel design, but also reveals the great potential for further developing bottlebrush channels with customized features and diverse functionalities. [ABSTRACT FROM AUTHOR]

Published

2024

42. Leveraging Senescent Cancer Cell Membrane to Potentiate Cancer Immunotherapy Through Biomimetic Nanovaccine.

Author

Yang, Chao, Chen, Yinglu, Liu, Jie, Zhang, Wensheng, He, Yan, Chen, Fangman, Xie, Xiaochun, Tang, Jie, Guan, Shan, Shao, Dan, Wang, Zheng, and Wang, Liang

Subjects

*TREATMENT effectiveness, *CANCER vaccines, *BIOMIMETICS, *CANCER cells, *DENDRITIC cells

Abstract

Senescent cancer cells are endowed with high immunogenic potential that has been leveraged to elicit antitumor immunity and potentially complement anticancer therapies. However, the efficacy of live senescent cancer cell‐based vaccination is limited by interference from immunosuppressive senescence‐associated secretory phenotype and pro‐tumorigenic capacity of senescent cells. Here, a senescent cancer cell‐based nanovaccine with strong immunogenicity and favorable potential for immunotherapy is reported. The biomimetic nanovaccine integrating a senescent cancer cell membrane‐coated nanoadjuvant outperforms living senescent cancer cells in enhancing dendritic cells (DCs) internalization, improving lymph node targeting, and enhancing immune responses. In contrast to nanovaccines generated from immunogenic cell death‐induced tumor cells, senescent nanovaccines facilitate DC maturation, eliciting superior antitumor protection and improving therapeutic outcomes in melanoma‐challenged mice with fewer side effects when combined with αPD‐1. The study suggests a versatile biomanufacturing approach to maximize immunogenic potential and minimize adverse effects of senescent cancer cell‐based vaccination and advances the design of biomimetic nanovaccines for cancer immunotherapy. [ABSTRACT FROM AUTHOR]

Published

2024

43. A structured biomimetic nanoparticle as inflammatory factor sponge and autophagy-regulatory agent against intervertebral disc degeneration and discogenic pain.

Author

Li, Kanglu, Yang, Wenbo, Chen, Xuanzuo, Yu, Yihan, Liu, Yiran, Ni, Feifei, Xiao, Yan, Qing, Xiangcheng, Liu, Sheng, He, YuXin, Wang, Baichuan, Xu, Li, Shao, Zengwu, Zhao, Lei, Peng, Yizhong, and Lin, Hui

Subjects

*INTERVERTEBRAL disk, *CALCITONIN gene-related peptide, *NERVE growth factor, *NUCLEUS pulposus, *DORSAL root ganglia

Abstract

Lower back pain (LBP) is a common condition closely associated with intervertebral disc degeneration (IDD), causing a significant socioeconomic burden. Inflammatory activation in degenerated discs involves pro-inflammatory cytokines, dysregulated regulatory cytokines, and increased levels of nerve growth factor (NGF), leading to further intervertebral disc destruction and pain sensitization. Macrophage polarization is closely related to autophagy. Based on these pathological features, a structured biomimetic nanoparticle coated with TrkA-overexpressing macrophage membranes (TMNP@SR) with a rapamycin-loaded mesoporous silica core is developed. TMNP@SR acted like sponges to adsorbe inflammatory cytokines and NGF and delivers the autophagy regulator rapamycin (RAPA) into macrophages through homologous targeting effects of the outer engineered cell membrane. By regulating autophagy activation, TMNP@SR promoted the M1-to-M2 switch of macrophages to avoid continuous activation of inflammation within the degenerated disc, which prevented the apoptosis of nucleus pulposus cells. In addition, TMNP@SR relieved mechanical and thermal hyperalgesia, reduced calcitonin gene-related peptide (CGRP) and substance P (SP) expression in the dorsal root ganglion, and downregulated GFAP and c-FOS signaling in the spinal cord in the rat IDD model. In summary, TMNP@SR spontaneously inhibits the aggravation of disc inflammation to alleviate disc degeneration and reduce the ingress of sensory nerves, presenting a promising treatment strategy for LBP induced by disc degeneration. [ABSTRACT FROM AUTHOR]

Published

2024

44. Bioinspired chitin/gelatin composites with enhanced mechanical property.

Author

Wang, Chong, Xie, Xiuling, Chen, Zheng, Fang, Luxin, and Lu, Ang

Subjects

CHITIN, BIOPOLYMERS, GELATIN, COATING processes, TENSILE strength

Abstract

The defensive tissues such as insect epidermis and crustacean exoskeleton in nature displayed characteristics of high strength and high toughness via multi‐level structure, which shed light on the designation of natural polymer‐based composites with enhanced mechanical property. Herein, a bioinspired strategy was used to prepare chitin/gelatin composite with improved mechanical property. Chitin hydrogels were first prepared by dissolution in NaOH/urea via freezing–thawing and then regeneration in sodium propionate, to form a heterogeneous nanofibrous structure. After coating gelatin on the chitin nanofibers, a hierarchical structure was obtained, leading to more compact and homogenous morphology. The coating process significantly strengthened the chitin nanofibrous structure and reduced the weak defect, which enhanced the tensile strength and toughness of the composite. The present work not only supplies a chitin/gelatin composite with high mechanical property but also offers a facile approach to prepare strengthening and toughening materials based on natural polymers. [ABSTRACT FROM AUTHOR]

Published

2024

45. Polyurethane nanofibers incorporated magnesium hydroxide followed by hydrothermal treatment using chitosan and silver nanoparticles to improve the biological properties.

Author

Rather, Anjum Hamid, Khan, Rumysa Saleem, Rafiq, Muheeb, Tripathi, Ravi Mani, and Sheikh, Faheem A.

Subjects

MAGNESIUM hydroxide, FIELD emission electron microscopes, CHITOSAN, FOURIER transform infrared spectroscopy, POLYURETHANES, RAMAN scattering, BIOACTIVE glasses

Abstract

The study aimed to explore the potential of magnesium hydroxide (Mg[OH]₂) nanoparticles (NPs) incorporated into polyurethane (PU) fibers, which were further coated with chitosan and silver (Ag) NPs. The hydrothermal approach was adopted to add the properties of chitosan and Ag NPs to the as‐spun fibers. These samples were characterized by field emission scanning electron microscope (FE‐SEM), EDS, Fourier transform infrared spectroscopy, thermogravimetric analysis, and contact angle measurements. The diameter of concocted fibers was found to be 0.79 ± 0.31 μm to 2.5 ± 0.9 μm. The presence of Mg(OH)2 decreased the fiber diameter from 2.05 ± 1.2 μm to 0.79 ± 0.31 μm; however, after hydrothermal coating, the diameter increased from 0.79 ± 0.31 μm to 2.5 ± 0.9 μm. The contact angle on pristine PU showed 105.53 ± 0.8°, that is, hydrophobicity, which was diminished to 9.3 ± 0.8° by the reorientation of PU with Mg(OH)2, chitosan and Ag NPs, that is, indicative of hydrophilic character. Biomineralization was evaluated by incubating in simulated body fluid, and the EDS and FE‐SEM indicated that composite fibers could induce apatite formation. Cell viability was measured using MTT assay, and cell adhesion/proliferation was confirmed by DAPI staining and FE‐SEM. The composite scaffolds promoted 3T3‐L1 to grow confluently. [ABSTRACT FROM AUTHOR]

Published

2024

46. Enhanced osteogenesis and antibacterial activity of dual-functional PEEK implants via biomimetic polydopamine modification with chondroitin sulfate and levofloxacin.

Author

Li, Mengjue, Liu, Junyan, Li, Yutong, Chen, Wenyu, Yang, Zhou, Zou, Yayu, Liu, Yi, Lu, Yue, and Cao, Jianfei

Subjects

*CHONDROITIN sulfates, *BONE substitutes, *CELL adhesion, *TITANIUM alloys, *ANTIBACTERIAL agents

Abstract

AbstractPolyetheretherketone (PEEK) implants have emerged as a clinically favored alternative to titanium alloy implants for cranial bone substitutes due to their excellent mechanical properties and biocompatibility. However, the biological inertness of PEEK has hindered its clinical application. To address this issue, we developed a dual-functional surface modification method aimed at enhancing both osteogenesis and antibacterial activity, which was achieved through the sustained release of chondroitin sulfate (CS) and levofloxacin (LVFX) from a biomimetic polydopamine (PDA) coating on the PEEK surface. CS was introduced to promote cell adhesion and osteogenic differentiation. Meanwhile, incorporation of antibiotic LVFX was essential to prevent infections, which are a critical concern in bone defect repairing. To our delight, experiment results demonstrated that the SPKD/CS-LVFX specimen exhibited enhanced hydrophilicity and sustained drug release profiles. Furthermore, in vitro experiments showed that cell growth and adhesion, cell viability, and osteogenic differentiation of mouse calvaria-derived osteoblast precursor (MC3T3-E1) cells were significantly improved on the SPKD/CS-LVFX coating. Antibacterial assays also confirmed that the SPKD/CS-LVFX specimen effectively inhibited the growth of Escherichia coli and Staphylococcus aureus, attributable to the antibiotic LVFX released from the PDA coating. To sum up, this dual-functional PEEK implant showed a promising potential for clinical application in bone defects repairing, providing excellent osteogenic and antibacterial properties through a synergistic approach. [ABSTRACT FROM AUTHOR]

Published

2024

47. Synthetic Biomimetic Liposomes Harness Efferocytosis Machinery for Highly Efficient Macrophages‐Targeted Drug Delivery to Alleviate Inflammation.

Author

Han, Run, Ren, Zhengyu, Wang, Qi, Zha, Haidong, Wang, Erjin, Wu, Mingyue, Zheng, Ying, and Lu, Jia‐Hong

Subjects

*INFLAMMATORY bowel diseases, *ERYTHROCYTES, *BIOMIMETICS, *ANNEXINS, *LABORATORY mice, *LIPOSOMES

Abstract

Macrophages play pivotal roles in the regulation of inflammatory responses and tissue repair, making them a prime target for inflammation alleviation. However, the accurate and efficient macrophages targeting is still a challenging task. Motivated by the efficient and specific removal of apoptotic cells by macrophages efferocytosis, a novel biomimetic liposomal system called Effero‐RLP (Efferocytosis‐mediated Red blood cell hybrid Liposomes) is developed which incorporates the membrane of apoptotic red blood cells (RBCs) with liposomes for the purpose of highly efficient macrophages targeting. Rosiglitazone (ROSI), a PPARγ agonist known to attenuate macrophage inflammatory responses, is encapsulated into Effero‐RLP as model drug to regulate macrophage functions in DSS‐induced colitis mouse model. Intriguingly, the Effero‐RLP exhibits selective and efficient uptake by macrophages, which is significantly inhibited by the efferocytosis blocker Annexin V. In animal models, the Effero‐RLP demonstrates rapid recognition by macrophages, leading to enhanced accumulation at inflammatory sites. Furthermore, ROSI‐loaded Effero‐RLP effectively alleviates inflammation and protects colon tissue from injury in the colitis mouse model, which is abolished by deletion of macrophages from mice model. In conclusion, the study highlights the potential of macrophage targeting using efferocytosis biomimetic liposomes. The development of Effero‐RLP presents novel and promising strategies for alleviating inflammation. [ABSTRACT FROM AUTHOR]

Published

2024

48. Cobalt Tetracationic 3,4‐Pyridinoporphyrazine for Direct CO2 to Methanol Conversion Escaping the CO Intermediate Pathway.

Author

Zhang, Chanjuan, Follana‐Berná, Jorge, Dragoe, Diana, Halime, Zakaria, Gotico, Philipp, Sastre‐Santos, Ángela, and Aukauloo, Ally

Abstract

Molecular catalysts offer a unique opportunity to implement different chemical functionalities to steer the efficiency and selectivity for the CO2 reduction for instance. Metalloporphyrins and metallophthalocyanines are under high scrutiny since their most classic derivatives the tetraphenylporphyrin (TPP) and parent phthalocyanine (Pc), have been used as the molecular platform to install, hydrogen bonds donors, proton relays, cationic fragments, incorporation in MOFs and COFs, to enhance the catalytic power of these catalysts. Herein, we examine the electrocatalytic properties of the tetramethyl cobalt (II) tetrapyridinoporphyrazine (CoTmTPyPz) for the reduction of CO2 in heterogeneous medium when adsorbed on carbon nanotubes (CNT) at a carbon paper (CP) electrode. Unlike reported electrocatalysis with cobalt based phthalocyanine where CO was advocated as the two electron and two protons reduced intermediate on the way to the formation of methanol, we found here that CoTmTPyPz does not reduce CO to methanol. Henceforth, ruling out a mechanistic pathway where CO is a reaction intermediate. [ABSTRACT FROM AUTHOR]

Published

2024

49. Biomimetic Based Underground Digging Robot Design.

Author

Doğu, Ceyda and Akkurt, Adnan

Subjects

*BIOMIMETICS, *ROBOT design & construction, *BIOENGINEERING, *NEW product development, *TECHNOLOGICAL innovations

Abstract

The field of robotics has long been inspired by notable adaptations and functionalities found in nature, leading to the development of biomimetic designs that mimic the abilities of living organisms. The design of underground excavation robots and various applications has been approached with a biomimetic perspective, offering numerous alternatives for innovation and new product development. These robots draw inspiration from a wide range of animals, including mammals, insects, and crustaceans, to develop effective excavation techniques and adaptability to complex underground environments. In this study, solutions for excavation tasks are presented, drawing inspiration from the armadillo. The robot mimics the unique anatomical structure of the armadillo and its digging function to perform effective and efficient excavation. The armadillo's ability to move rapidly and effectively underground serves as a primary inspiration for the robot's design. This study provides a detailed look into the design principles and methodologies used in the development of biomimetic underground excavation robots, demonstrating their potential utility in underground exploration, mining, and various other subterranean activities. [ABSTRACT FROM AUTHOR]

Published

2024

50. Bioarchitectonic Nanophotonics by Replication and Systolic Miniaturization of Natural Forms.

Author

Papachristopoulou, Konstantina and Vainos, Nikolaos A.

Subjects

*NANOPHOTONICS, *FOCAL length, *FUSED silica, *VISIBLE spectra, *REFRACTIVE index

Abstract

The mimesis of biological mechanisms by artificial devices constitutes the modern, rapidly expanding, multidisciplinary biomimetics sector. In the broader bioinspiration perspective, however, bioarchitectures may perform independent functions without necessarily mimicking their biological generators. In this paper, we explore such Bioarchitectonic notions and demonstrate three-dimensional photonics by the exact replication of insect organs using ultra-porous silica aerogels. The subsequent conformal systolic transformation yields their miniaturized affine 'clones' having higher mass density and refractive index. Focusing on the paradigms of ommatidia, the compound eye of the hornet Vespa crabro flavofasciata and the microtrichia of the scarab Protaetia cuprea phoebe, we fabricate their aerogel replicas and derivative clones and investigate their photonic functionalities. Ultralight aerogel microlens arrays are proven to be functional photonic devices having a focal length f ~ 1000 μm and f-number f/30 in the visible spectrum. Stepwise systolic transformation yields denser and affine functional elements, ultimately fused silica clones, exhibiting strong focusing properties due to their very short focal length of f ~ 35 μm and f/3.5. The fabricated transparent aerogel and xerogel replicas of microtrichia demonstrate a remarkable optical waveguiding performance, delivering light to their sub-100 nm nanotips. Dense fused silica conical clones deliver light through sub-50 nm nanotips, enabling nanoscale light–matter interactions. Super-resolution bioarchitectonics offers new and alternative tools and promises novel developments and applications in nanophotonics and other nanotechnology sectors. [ABSTRACT FROM AUTHOR]

Published

2024