Your search keyword '"Biomimetics methods"' showing total 72 results

1. Sono-Triggered Biomimetically Nanoantibiotics Mediate Precise Sequential Therapy of MRSA-Induced Lung Infection.

Author

Ding L, Liang X, Ma J, Liu X, Zhang Y, Long Q, Wen Z, Teng Z, Jiang L, and Liu G

Subjects

Animals, Mice, Biomimetic Materials chemistry, Biomimetic Materials pharmacology, Staphylococcal Infections drug therapy, Penicillin-Binding Proteins metabolism, Biomimetics methods, Lung pathology, Lung microbiology, Methicillin-Resistant Staphylococcus aureus drug effects, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents pharmacology, Nanoparticles chemistry, Ciprofloxacin pharmacology, Ciprofloxacin chemistry

Abstract

Bacterial-induced lower respiratory tract infections are a growing global health concern, exacerbated by the inefficacy of conventional antibiotics and delivery methods to effectively target the lower respiratory tract, leading to suboptimal therapeutic outcomes. To address this challenge, this work engineers PBP2a antibody-presenting membrane nanovesicles (AMVs) specifically designed to target the penicillin-binding protein variant on the surface of methicillin-resistant Staphylococcus aureus (MRSA). Concurrently, this work develops pure ciprofloxacin nanoparticles (NanoCip) that, for the first time, exhibits exceptional self-generated sonodynamic properties, attributed to hydrogen-bond-driven self-assembly, while maintaining their inherent pharmacological efficacy. These NanoCip particles are integrated with AMVs to create a novel biomimetic nanomedicine, AMV@NanoCip. This formulation demonstrated remarkable MRSA-targeting affinity in both in vitro and in vivo models, significantly enhancing antibacterial activity. Upon ultrasound stimulation, AMV@NanoCip achieves over 99.99% sterilization of MRSA in vitro, with a reduction exceeding 5.14 Log CFU. Prokaryotic transcriptomic analysis further elucidates the synergistic mechanisms by which AMV@NanoCip, coupled with ultrasound, disrupts the MRSA exoskeleton. In a MRSA-induced pneumonia animal model, AMV@NanoCip+US results in a substantial bacterial load reduction in the lungs (99.99%, 4.02 Log CFU). This sequential treatment strategy (adhesion-membrane disruption-synergistic therapy) offers significant promise as an innovative therapeutic approach for combating bacterial infections., (© 2024 Wiley‐VCH GmbH.)

Published

2024

2. A Biomimetic Autophagosomes-Based Nanovaccine Boosts Anticancer Immunity.

Author

Qu L, Cui G, Sun Y, Ye R, Sun Y, Meng F, Wang S, and Zhong Z

Subjects

Animals, Mice, Cell Line, Tumor, Humans, Immunotherapy, Female, Antigens, Neoplasm immunology, Nanoparticles chemistry, Adjuvants, Immunologic chemistry, Biomimetics methods, Nanovaccines, Cancer Vaccines immunology, Cancer Vaccines chemistry, Cancer Vaccines administration & dosage, Biomimetic Materials chemistry, Autophagosomes metabolism

Abstract

Personalized cancer vaccines based on tumor cell lysates offer promise for cancer immunotherapy yet fail to elicit a robust therapeutic effect due to the weak immunogenicity of tumor antigens. Autophagosomes, obtained from pleural effusions and ascites of cancer patients, have been identified as abundant reservoirs of tumor neoantigens that exhibit heightened immunogenicity. However, their potential as personalized cancer vaccines have been constrained by suboptimal lymphatic-targeting performances and challenges in antigen-presenting cell endocytosis. Here,a reinforced biomimetic autophagosome-based (BAPs) nanovaccine generated by precisely amalgamating autophagosome-derived neoantigens and two types of adjuvants capable of targeting lymph nodes is developed to potently elicit antitumor immunity. The redox-responsive BAPs facilitate cytosolic vaccine opening within antigen-presenting cells, thereby exposing adjuvants and antigens to stimulate a strong immune response. BAPs evoke broad-spectrum T-cell responses, culminating in the effective eradication of 71.4% of established tumors. Notably, BAPs vaccination triggers enduring T-cell responses that confer robust protection, with 100% of mice shielded against tumor rechallenge and a significant reduction in tumor incidence by 87.5%. Furthermore, BAPs synergize with checkpoint blockade therapy to inhibit tumor growth in the poorly immunogenic breast cancer model. The biomimetic approach presents a powerful nanovaccine formula with high versatility for personalized cancer immunotherapy., (© 2024 Wiley‐VCH GmbH.)

Published

2024

3. Human Circulatory/Respiratory-Inspired Comprehensive Air Purification System.

Author

Jeong S, Shin J, Kim J, Kim H, Lee JG, Min J, Hong S, and Ko SH

Subjects

Humans, Animals, Mice, Volatile Organic Compounds isolation & purification, Volatile Organic Compounds chemistry, Biomimetics methods, Biomimetics instrumentation, Particulate Matter, Microbubbles, Carbon Dioxide chemistry

Abstract

The circulatory and respiratory systems in humans are marvels of biological engineering that exhibit competence in maintaining homeostasis. These systems not only shield the organism from external contaminants but also orchestrate the vital gases via the bloodstream to sustain cellular respiration and metabolic processes across diverse tissues. It is noticed that spaces inhabited encounter challenges akin to those of the human body: protecting the indoor air from external pollutants while removing anthropogenic byproducts like carbon dioxide (CO 2 ), particulate matters (PM), and volatile organic compounds (VOCs) tooutside. A biomimetic approach, composed of a microbubble-based gas exchanger and circulating liquid inspired by alveoli, capillary beds, and bloodstream of the human circulatory/respiratory system, offer an innovative solution for comprehensive air purification of hermetic spaces. Circulatory/respiratory-inspired air purification system (CAPS) ensure both continuous removal of PM and exchange of gas species between indoor and outdoor environments to maintain homeostasis. The effectiveness of this system is also supported by animal behavior experiments with and without CAPS, showing an effect of reducing CO 2 concentration by 30% and increasing mice locomotor activity by 53%. CAPS is expected to evolve into robust and comprehensive air purification schemes through the networked integration of plural internal and external environments., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

4. Embedding Biomimetic Vascular Networks via Coaxial Sacrificial Writing into Functional Tissue.

Author

Stankey PP, Kroll KT, Ainscough AJ, Reynolds DS, Elamine A, Fichtenkort BT, Uzel SGM, and Lewis JA

Subjects

Humans, Alginates chemistry, Induced Pluripotent Stem Cells cytology, Hydrogels chemistry, Tissue Scaffolds chemistry, Biomimetics methods, Collagen chemistry, Myocytes, Smooth Muscle cytology, Blood Vessels cytology, Blood Vessels physiology, Human Umbilical Vein Endothelial Cells, Animals, Spheroids, Cellular cytology, Biomimetic Materials chemistry, Bioprinting methods, Tissue Engineering methods

Abstract

Printing human tissues and organs replete with biomimetic vascular networks is of growing interest. While it is possible to embed perfusable channels within acellular and densely cellular matrices, they do not currently possess the biomimetic architectures found in native vessels. Here, coaxial sacrificial writing into functional tissues (co-SWIFT) is developed, an embedded bioprinting method capable of generating hierarchically branching, multilayered vascular networks within both granular hydrogel and densely cellular matrices. Coaxial printheads are designed with an extended core-shell configuration to facilitate robust core-core and shell-shell interconnections between printed branching vessels during embedded bioprinting. Using optimized core-shell ink combinations, biomimetic vessels composed of a smooth muscle cell-laden shell that surrounds perfusable lumens are coaxially printed into granular matrices composed of: 1) transparent alginate microparticles, 2) sacrificial microparticle-laden collagen, or 3) cardiac spheroids derived from human induced pluripotent stem cells. Biomimetic blood vessels that exhibit good barrier function are produced by seeding these interconnected lumens with a confluent layer of endothelial cells. Importantly, it is found that co-SWIFT cardiac tissues mature under perfusion, beat synchronously, and exhibit a cardio-effective drug response in vitro. This advance opens new avenues for the scalable biomanufacturing of vascularized organ-specific tissues for drug testing, disease modeling, and therapeutic use., (© 2024 Wiley‐VCH GmbH.)

Published

2024

5. Light-Driven Multidirectional Bending in Artificial Muscles.

Author

Madani Z, Silva PES, Baniasadi H, Vaara M, Das S, Arias JC, Seppälä J, Sun Z, and Vapaavuori J

Subjects

Robotics, Muscles physiology, Textiles, Polymers chemistry, Biomimetic Materials chemistry, Biomimetic Materials radiation effects, Biomimetics methods, Artificial Organs, Light

Abstract

Using light to drive polymer actuators can enable spatially selective complex motions, offering a wealth of opportunities for wireless control of soft robotics and active textiles. Here, the integration of photothermal components is reported into shape memory polymer actuators. The fabricated twist-coiled artificial muscles show on-command multidirectional bending, which can be controlled by both the illumination intensity, as well as the chirality, of the prepared artificial muscles. Importantly, the direction in which these artificial muscles bend does not depend on intrinsic material characteristics. Instead, this directionality is achieved by localized untwisting of the actuator, driven by selective irradiation. The reaction times of this bending system are significantly - at least two orders of magnitude - faster than heliotropic biological systems, with a response time up to one second. The programmability of the artificial muscles is further demonstrated for selective, reversible, and sustained actuation when integrated in butterfly-shaped textiles, along with the capacity to autonomously orient toward a light source. This functionality is maintained even on a rotating platform, with angular velocities of 6°/s, independent of the rotation direction. These attributes collectively represent a breakthrough in the field of artificial muscles, intended to adaptive shape-changing soft systems and biomimetic technologies., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

6. Unveiling Gating Behavior in Piezoionic Effect: toward Neuromimetic Tactile Sensing.

Author

Wang S, Yang T, Zhang D, Hua Q, and Zhao Y

Subjects

Humans, Biomimetics methods, Robotics, Touch physiology, Hydrogels chemistry

Abstract

The human perception system's information processing is intricately linked to the nonlinear response and gating effect of neurons. While piezoionics holds potential in emulating the pressure sensing capability of biological skin, the incorporation of information processing functions seems neglected. Here, ionic gating behavior in piezoionic hydrogels is uncovered as a notable extension beyond the previously observed linear responses. The hydrogel can generate remarkably high voltages (700 mV) and currents (7 mA) when indentation forces surpass the threshold. Through a comprehensive analysis involving simulations and experimental investigations, it is proposed that the gating behavior emerges due to significant diffusion differences between cations and anions. To showcase the practical implications of this breakthrough, the piezoionic hydrogels are successfully integrated with prostheses and robot hands, demonstrating that the gating effect enables accurate discrimination between gentle and harsh touch. The advancement in neuromimetic tactile sensing has significant potential for emerging applications such as humanoid robotics and biomedical engineering, offering valuable opportunities for further development of embodied neuromorphic intelligence., (© 2024 Wiley‐VCH GmbH.)

Published

2024

7. Bioinspired Liquid Metal Based Soft Humanoid Robots.

Author

Li N, Yuan X, Li Y, Zhang G, Yang Q, Zhou Y, Guo M, and Liu J

Subjects

Humans, Biomimetic Materials chemistry, Biomimetics methods, Robotics, Metals chemistry

Abstract

The pursuit of constructing humanoid robots to replicate the anatomical structures and capabilities of human beings has been a long-standing significant undertaking and especially garnered tremendous attention in recent years. However, despite the progress made over recent decades, humanoid robots have predominantly been confined to those rigid metallic structures, which however starkly contrast with the inherent flexibility observed in biological systems. To better innovate this area, the present work systematically explores the value and potential of liquid metals and their derivatives in facilitating a crucial transition towards soft humanoid robots. Through a comprehensive interpretation of bionics, an overview of liquid metals' multifaceted roles as essential components in constructing advanced humanoid robots-functioning as soft actuators, sensors, power sources, logical devices, circuit systems, and even transformable skeletal structures-is presented. It is conceived that the integration of these components with flexible structures, facilitated by the unique properties of liquid metals, can create unexpected versatile functionalities and behaviors to better fulfill human needs. Finally, a revolution in humanoid robots is envisioned, transitioning from metallic frameworks to hybrid soft-rigid structures resembling that of biological tissues. This study is expected to provide fundamental guidance for the coming research, thereby advancing the area., (© 2024 Wiley‐VCH GmbH.)

Published

2024

8. Nanozybiotics: Advancing Antimicrobial Strategies Through Biomimetic Mechanisms.

Author

Zhou C, Wang Q, Cao H, Jiang J, and Gao L

Subjects

Humans, Animals, Biomimetic Materials chemistry, Biomimetic Materials pharmacology, Nanostructures chemistry, Anti-Bacterial Agents pharmacology, Anti-Bacterial Agents chemistry, Nanoparticles chemistry, Anti-Infective Agents pharmacology, Anti-Infective Agents chemistry, Biomimetics methods

Abstract

Infectious diseases caused by bacterial, viral, and fungal pathogens present significant global health challenges. The rapid emergence of antimicrobial resistance exacerbates this issue, leading to a scenario where effective antibiotics are increasingly scarce. Traditional antibiotic development strategies are proving inadequate against the swift evolution of microbial resistance. Therefore, there is an urgent need to develop novel antimicrobial strategies with mechanisms distinct from those of existing antibiotics. Nanozybiotics, which are nanozyme-based antimicrobials, mimic the catalytic action of lysosomal enzymes in innate immune cells to kill infectious pathogens. This review reinforces the concept of nanozymes and provides a comprehensive summary of recent research advancements on potential antimicrobial candidates. Initially, nanozybiotics are categorized based on their activities, mimicking either oxidoreductase-like or hydrolase-like functions, thereby highlighting their superior mechanisms in combating antimicrobial resistance. The review then discusses the progress of nanozybiotics in treating bacterial, viral, and fungal infections, confirming their potential as novel antimicrobial candidates. The translational potential of nanozybiotic-based products, including hydrogels, nanorobots, sprays, bandages, masks, and protective clothing, is also considered. Finally, the current challenges and future prospects of nanozybiotic-related products are explored, emphasizing the design and antimicrobial capabilities of nanozybiotics for future applications., (© 2024 Wiley‐VCH GmbH.)

Published

2024

9. Brain Delivery of Protein Therapeutics by Cell Matrix-Inspired Biomimetic Nanocarrier.

Author

Huang J, Fu Y, Wang A, Shi K, Peng Y, Yi Y, Yu R, Gao J, Feng J, Jiang G, Song Q, Jiang J, Chen H, and Gao X

Subjects

Animals, Mice, Nanoparticles chemistry, Protamines chemistry, Amyotrophic Lateral Sclerosis drug therapy, Disease Models, Animal, Humans, Brain Injuries drug therapy, Brain Injuries metabolism, Biomimetics methods, Biomimetic Materials chemistry, Drug Carriers chemistry, Blood-Brain Barrier metabolism, Hyaluronic Acid chemistry, Catalase metabolism, Catalase chemistry, Brain metabolism

Abstract

Protein therapeutics are anticipated to offer significant treatment options for central nervous system (CNS) diseases. However, the majority of proteins are unable to traverse the blood-brain barrier (BBB) and reach their CNS target sites. Inspired by the natural environment of active proteins, the cell matrix components hyaluronic acid (HA) and protamine (PRTM) are used to self-assemble with proteins to form a protein-loaded biomimetic core and then incorporated into ApoE3-reconstituted high-density lipoprotein (rHDL) to form a protein-loaded biomimetic nanocarrier (Protein-HA-PRTM-rHDL). This cell matrix-inspired biomimetic nanocarrier facilitates the penetration of protein therapeutics across the BBB and enables their access to intracellular target sites. Specifically, CAT-HA-PRTM-rHDL facilitates rapid intracellular delivery and release of catalase (CAT) via macropinocytosis-activated membrane fusion, resulting in improved spatial learning and memory in traumatic brain injury (TBI) model mice (significantly reduces the latency of TBI mice and doubles the number of crossing platforms), and enhances motor function and prolongs survival in amyotrophic lateral sclerosis (ALS) model mice (extended the median survival of ALS mice by more than 10 days). Collectively, this cell matrix-inspired nanoplatform enables the efficient CNS delivery of protein therapeutics and provides a novel approach for the treatment of CNS diseases., (© 2024 Wiley‐VCH GmbH.)

Published

2024

10. Knotted Artificial Muscles for Bio-Mimetic Actuation under Deepwater.

Author

Chen W, Tong D, Meng L, Tan B, Lan R, Zhang Q, Yang H, Wang C, and Liu K

Subjects

Muscles, Printing, Three-Dimensional, Robotics, Artificial Organs, Animals, Elastomers chemistry, Biomimetics methods, Liquid Crystals chemistry, Humans, Biomimetic Materials chemistry, Water chemistry

Abstract

Muscles featuring high frequency and high stroke linear actuation are essential for animals to achieve superior maneuverability, agility, and environmental adaptability. Artificial muscles are yet to match their biological counterparts, due to inferior actuation speed, magnitude, mode, or adaptability. Inspired by the hierarchical structure of natural muscles, artificial muscles are created that are powerful, responsive, robust, and adaptable. The artificial muscles consist of knots braided from 3D printed liquid crystal elastomer fibers and thin heating threads. The unique hierarchical, braided knot structure offers amplified linear stroke, force rate, and damage-tolerance, as verified by both numerical simulations and experiments. In particular, the square knotted artificial muscle shows reliable cycles of actuation at 1Hz in 3000m depth underwater. Potential application is demonstrated by propelling a model boat. Looking ahead, the knotted artificial muscles can empower novel biomedical devices and soft robots to explore various environments, from inside human body to the mysterious deep sea., (© 2024 Wiley‐VCH GmbH.)

Published

2024

11. Activating Macrophage Continual Efferocytosis via Microenvironment Biomimetic Short Fibers for Reversing Inflammation in Bone Repair.

Author

Wang H, Zhang Y, Zhang Y, Li C, Zhang M, Wang J, Zhang Y, Du Y, Cui W, and Chen W

Subjects

Animals, Rats, Mice, Indoles chemistry, Indoles pharmacology, Phagocytosis drug effects, RAW 264.7 Cells, Bone Regeneration drug effects, Macrophage Activation drug effects, Oxidative Stress drug effects, Biomimetics methods, Osteogenesis drug effects, Cellular Microenvironment drug effects, Efferocytosis, Cerium chemistry, Cerium pharmacology, Biomimetic Materials chemistry, Biomimetic Materials pharmacology, Inflammation drug therapy, Macrophages metabolism, Macrophages drug effects, Polymers chemistry, Polymers pharmacology, Apoptosis drug effects

Abstract

Efferocytosis-mediated inflammatory reversal plays a crucial role in bone repairing process. However, in refractory bone defects, the macrophage continual efferocytosis may be suppressed due to the disrupted microenvironment homeostasis, particularly the loss of apoptotic signals and overactivation of intracellular oxidative stress. In this study, a polydopamine-coated short fiber matrix containing biomimetic "apoptotic signals" to reconstruct the microenvironment and reactivate macrophage continual efferocytosis for inflammatory reversal and bone defect repair is presented. The "apoptotic signals" (AM/CeO 2 ) are prepared using CeO 2 nanoenzymes with apoptotic neutrophil membrane coating for macrophage recognition and oxidative stress regulation. Additionally, a short fiber "biomimetic matrix" is utilized for loading AM/CeO 2 signals via abundant adhesion sites involving π-π stacking and hydrogen bonding interactions. Ultimately, the implantable apoptosis-mimetic nanoenzyme/short-fiber matrixes (PFS@AM/CeO 2 ), integrating apoptotic signals and biomimetic matrixes, are constructed to facilitate inflammatory reversal and reestablish the pro-efferocytosis microenvironment. In vitro and in vivo data indicate that the microenvironment biomimetic short fibers can activate macrophage continual efferocytosis, leading to the suppression of overactivated inflammation. The enhanced repair of rat femoral defect further demonstrates the osteogenic potential of the pro-efferocytosis strategy. It is believed that the regulation of macrophage efferocytosis through microenvironment biomimetic materials can provide a new perspective for tissue repair., (© 2024 Wiley‐VCH GmbH.)

Published

2024

12. Accelerated Engineering of ELP-Based Materials through Hybrid Biomimetic-De Novo Predictive Molecular Design.

Author

Laakko T, Korkealaakso A, Yildirir BF, Batys P, Liljeström V, Hokkanen A, Nonappa, Penttilä M, Laukkanen A, Miserez A, Södergård C, and Mohammadi P

Subjects

Peptides chemistry, Biomimetics methods, Models, Molecular, Elastin chemistry, Elastin genetics, Protein Engineering methods, Biomimetic Materials chemistry

Abstract

Efforts to engineer high-performance protein-based materials inspired by nature have mostly focused on altering naturally occurring sequences to confer the desired functionalities, whereas de novo design lags significantly behind and calls for unconventional innovative approaches. Here, using partially disordered elastin-like polypeptides (ELPs) as initial building blocks this work shows that de novo engineering of protein materials can be accelerated through hybrid biomimetic design, which this work achieves by integrating computational modeling, deep neural network, and recombinant DNA technology. This generalizable approach involves incorporating a series of de novo-designed sequences with α-helical conformation and genetically encoding them into biologically inspired intrinsically disordered repeating motifs. The new ELP variants maintain structural conformation and showed tunable supramolecular self-assembly out of thermal equilibrium with phase behavior in vitro. This work illustrates the effective translation of the predicted molecular designs in structural and functional materials. The proposed methodology can be applied to a broad range of partially disordered biomacromolecules and potentially pave the way toward the discovery of novel structural proteins., (© 2024 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

13. Revolutionizing Neurocare: Biomimetic Nanodelivery Via Cell Membranes.

Author

Liao J, Gong L, Xu Q, Wang J, Yang Y, Zhang S, Dong J, Lin K, Liang Z, Sun Y, Mu Y, Chen Z, Lu Y, Zhang Q, and Lin Z

Subjects

Humans, Animals, Biomimetics methods, Nanoparticles chemistry, Drug Delivery Systems methods, Drug Carriers chemistry, Brain Diseases drug therapy, Brain Diseases metabolism, Blood-Brain Barrier metabolism, Cell Membrane metabolism, Cell Membrane chemistry, Biomimetic Materials chemistry

Abstract

Brain disorders represent a significant challenge in medical science due to the formidable blood-brain barrier (BBB), which severely limits the penetration of conventional therapeutics, hindering effective treatment strategies. This review delves into the innovative realm of biomimetic nanodelivery systems, including stem cell-derived nanoghosts, tumor cell membrane-coated nanoparticles, and erythrocyte membrane-based carriers, highlighting their potential to circumvent the BBB's restrictions. By mimicking native cell properties, these nanocarriers emerge as a promising solution for enhancing drug delivery to the brain, offering a strategic advantage in overcoming the barrier's selective permeability. The unique benefits of leveraging cell membranes from various sources is evaluated and advanced technologies for fabricating cell membrane-encapsulated nanoparticles capable of masquerading as endogenous cells are examined. This enables the targeted delivery of a broad spectrum of therapeutic agents, ranging from small molecule drugs to proteins, thereby providing an innovative approach to neurocare. Further, the review contrasts the capabilities and limitations of these biomimetic nanocarriers with traditional delivery methods, underlining their potential to enable targeted, sustained, and minimally invasive treatment modalities. This review is concluded with a perspective on the clinical translation of these biomimetic systems, underscoring their transformative impact on the therapeutic landscape for intractable brain diseases., (© 2024 Wiley‐VCH GmbH.)

Published

2024

14. Piezocatalytic Schottky Junction Treats Atherosclerosis by a Biomimetic Trojan Horse Strategy.

Author

Cheng J, Pan W, Zheng Y, Zhang J, Chen L, Huang H, Chen Y, and Wu R

Subjects

Animals, Mice, RAW 264.7 Cells, Macrophages metabolism, Humans, Metal Nanoparticles chemistry, Catalysis, Biomimetics methods, Apoptosis drug effects, Plaque, Atherosclerotic pathology, Atherosclerosis therapy, Atherosclerosis diagnostic imaging, Atherosclerosis metabolism, Gold chemistry, Biomimetic Materials chemistry, Reactive Oxygen Species metabolism, Zinc Oxide chemistry

Abstract

The atherosclerotic vulnerable plaque is characterized by the foamy macrophage burden, involving impaired cholesterol efflux and deficient efferocytosis. Correspondingly, piezocatalytic therapy is an emerging solution for eliminating the foamy macrophage burden with satisfactory spatiotemporal controllability and deep penetration depth. Herein, a biomimetic Trojan horse (Au-ZnO@MM) is engineered by coating the macrophage membrane (MM) onto the surface of a rod-like Au-ZnO Schottky Junction to effectively relieve the atherosclerotic progression. These Trojan horses with the coating of MM are actively transported into subsistent foamy macrophages and generate abundant reactive oxygen species (ROS) via ultrasound-activated piezocatalysis. ROS-initiated autophagy and mitochondrial dysfunction induce substantial cell apoptosis, alleviating the burden of subsistent foamy macrophages. The resulting apoptotic fragments further significantly facilitate cholesterol excretion and trigger efferocytosis of intraplaque fresh macrophages. Ultimately, the biomimetic Au-ZnO@MM piezocatalyst not only inhibits the foaming capacity of macrophages, but also improves the function of removing cell debris, which can stabilize atherosclerotic vulnerable plaque. Meanwhile, the plasmon resonance effect of integrated gold nanoparticles enables favorable photoacoustic molecular imaging for real-time image-guided atherosclerotic therapy. This proposed biomimetic Trojan horse strategy provides the paradigm of employing ultrasound-activated piezocatalytic methodology for enhanced atherosclerotic theranostics., (© 2024 Wiley‐VCH GmbH.)

Published

2024

15. Biomimetic Multimodal Receptors for Comprehensive Artificial Human Somatosensory System.

Author

Chen C, Xu JL, Wang Q, Li XL, Xu FQ, Gao YC, Zhu YB, Wu HA, and Liu JW

Subjects

Humans, Wearable Electronic Devices, Temperature, Biomimetics methods, Humidity, Skin, Artificial, Pressure, Receptors, Artificial chemistry, Biomimetic Materials chemistry

Abstract

Electronic skin (e-skin) capable of acquiring environmental and physiological information has attracted interest for healthcare, robotics, and human-machine interaction. However, traditional 2D e-skin only allows for in-plane force sensing, which limits access to comprehensive stimulus feedback due to the lack of out-of-plane signal detection caused by its 3D structure. Here, a dimension-switchable bioinspired receptor is reported to achieve multimodal perception by exploiting film kirigami. It offers the detection of in-plane (pressure and bending) and out-of-plane (force and airflow) signals by dynamically inducing the opening and reclosing of sensing unit. The receptor's hygroscopic and thermoelectric properties enable the sensing of humidity and temperature. Meanwhile, the thermoelectric receptor can differentiate mechanical stimuli from temperature by the voltage. The development enables a wide range of sensory capabilities of traditional e-skin and expands the applications in real life., (© 2024 Wiley‐VCH GmbH.)

Published

2024

16. Fabrication and Functionality Integration Technologies for Small-Scale Soft Robots.

Author

Zhang S, Ke X, Jiang Q, Chai Z, Wu Z, and Ding H

Subjects

Equipment Design, Mechanical Phenomena, Printing, Three-Dimensional, Biomimetics methods, Robotics methods

Abstract

Small-scale soft robots are attracting increasing interest for visible and potential applications owing to their safety and tolerance resulting from their intrinsic soft bodies or compliant structures. However, it is not sufficient that the soft bodies merely provide support or system protection. More importantly, to meet the increasing demands of controllable operation and real-time feedback in unstructured/complicated scenarios, these robots are required to perform simplex and multimodal functionalities for sensing, communicating, and interacting with external environments during large or dynamic deformation with the risk of mismatch or delamination. Challenges are encountered during fabrication and integration, including the selection and fabrication of composite/materials and structures, integration of active/passive functional modules with robust interfaces, particularly with highly deformable soft/stretchable bodies. Here, methods and strategies of fabricating structural soft bodies and integrating them with functional modules for developing small-scale soft robots are investigated. Utilizing templating, 3D printing, transfer printing, and swelling, small-scale soft robots can be endowed with several perceptual capabilities corresponding to diverse stimulus, such as light, heat, magnetism, and force. The integration of sensing and functionalities effectively enhances the agility, adaptability, and universality of soft robots when applied in various fields, including smart manufacturing, medical surgery, biomimetics, and other interdisciplinary sciences., (© 2022 Wiley-VCH GmbH.)

Published

2022

17. Biomineralized Materials as Model Systems for Structural Composites: 3D Architecture.

Author

Jia Z, Deng Z, and Li L

Subjects

Biomimetics methods, Models, Biological, Tomography, X-Ray Computed, Biomimetic Materials chemistry, Nacre

Abstract

Biomineralized materials are sophisticated material systems with hierarchical 3D material architectures, which are broadly used as model systems for fundamental mechanical, materials science, and biomimetic studies. The current knowledge of the structure of biological materials is mainly based on 2D imaging, which often impedes comprehensive and accurate understanding of the materials' intricate 3D microstructure and consequently their mechanics, functions, and bioinspired designs. The development of 3D techniques such as tomography, additive manufacturing, and 4D testing has opened pathways to study biological materials fully in 3D. This review discusses how applying 3D techniques can provide new insights into biomineralized materials that are either well known or possess complex microstructures that are challenging to understand in the 2D framework. The diverse structures of biomineralized materials are characterized based on four universal structural motifs. Nacre is selected as an example to demonstrate how the progression of knowledge from 2D to 3D can bring substantial improvements to understanding the growth mechanism, biomechanics, and bioinspired designs. State-of-the-art multiscale 3D tomographic techniques are discussed with a focus on their integration with 3D geometric quantification, 4D in situ experiments, and multiscale modeling. Outlook is given on the emerging approaches to investigate the synthesis-structure-function-biomimetics relationship., (© 2022 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2022

18. Multifunctional Biomimetic Nanovaccines Based on Photothermal and Weak-Immunostimulatory Nanoparticulate Cores for the Immunotherapy of Solid Tumors.

Author

Li J, Huang D, Cheng R, Figueiredo P, Fontana F, Correia A, Wang S, Liu Z, Kemell M, Torrieri G, Mäkilä EM, Salonen JJ, Hirvonen J, Gao Y, Li J, Luo Z, Santos HA, and Xia B

Subjects

Animals, Biomimetics methods, Immunotherapy, Mice, Tumor Microenvironment, Nanocomposites, Nanoparticles therapeutic use, Neoplasms therapy

Abstract

An alternative strategy of choosing photothermal and weak-immunostimulatory porous silicon@Au nanocomposites as particulate cores to prepare a biomimetic nanovaccine is reported to improve its biosafety and immunotherapeutic efficacy for solid tumors. A quantitative analysis method is used to calculate the loading amount of cancer cell membranes onto porous silicon@Au nanocomposites. Assisted with foreign-body responses, these exogenous nanoparticulate cores with weak immunostimulatory effect can still efficiently deliver cancer cell membranes into dendritic cells to activate them and the downstream antitumor immunity, resulting in no occurrence of solid tumors and the survival of all immunized mice during 55 day observation. In addition, this nanovaccine, as a photothermal therapeutic agent, synergized with additional immunotherapies can significantly inhibit the growth and metastasis of established solid tumors, via the initiation of the antitumor immune responses in the body and the reversion of their immunosuppressive microenvironments. Considering the versatile surface engineering of porous silicon nanoparticles, the strategy developed here is beneficial to construct multifunctional nanovaccines with better biosafety and more diagnosis or therapeutic modalities against the occurrence, recurrence, or metastasis of solid tumors in future clinical practice., (© 2022 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2022

19. A Bioinspired Stretchable Sensory-Neuromorphic System.

Author

Kim SH, Baek GW, Yoon J, Seo S, Park J, Hahm D, Chang JH, Seong D, Seo H, Oh S, Kim K, Jung H, Oh Y, Baac HW, Alimkhanuly B, Bae WK, Lee S, Lee M, Kwak J, Park JH, and Son D

Subjects

Biomimetic Materials chemistry, Biomimetics methods, Humans, Mechanoreceptors physiology, Quantum Dots chemistry, Electronics, Synapses physiology, Equipment Design, Wearable Electronic Devices, Neural Networks, Computer

Abstract

Conventional stretchable electronics that adopt a wavy design, a neutral mechanical plane, and conformal contact between abiotic and biotic interfaces have exhibited diverse skin-interfaced applications. Despite such remarkable progress, the evolution of intelligent skin prosthetics is challenged by the absence of the monolithic integration of neuromorphic constituents into individual sensing and actuating components. Herein, a bioinspired stretchable sensory-neuromorphic system, comprising an artificial mechanoreceptor, artificial synapse, and epidermal photonic actuator is demonstrated; these three biomimetic functionalities correspond to a stretchable capacitive pressure sensor, a resistive random-access memory, and a quantum dot light-emitting diode, respectively. This system features a rigid-island structure interconnected with a sinter-free printable conductor, which is optimized by controlling the evaporation rate of solvent (≈160% stretchability and ≈18 550 S cm -1 conductivity). Devised design improves both areal density and structural reliability while avoiding the thermal degradation of heat-sensitive stretchable electronic components. Moreover, even in the skin deformation range, the system accurately recognizes various patterned stimuli via an artificial neural network with training/inferencing functions. Therefore, the new bioinspired system is expected to be an important step toward implementing intelligent wearable electronics., (© 2021 Wiley-VCH GmbH.)

Published

2021

20. An Optogenetics-Inspired Flexible van der Waals Optoelectronic Synapse and its Application to a Convolutional Neural Network.

Author

Seo S, Lee JJ, Lee RG, Kim TH, Park S, Jung S, Lee HK, Andreev M, Lee KB, Jung KS, Oh S, Lee HJ, Kim KS, Yeom GY, Kim YH, and Park JH

Subjects

Biomimetics instrumentation, Biomimetics methods, Electric Conductivity, Light, Rhenium chemistry, Sulfides chemistry, Synapses physiology, Electronics, Neural Networks, Computer, Optogenetics

Abstract

Optogenetics refers to a technique that uses light to modulate neuronal activity with a high spatiotemporal resolution, which enables the manipulation of learning and memory functions in the human brain. This strategy of controlling neuronal activity using light can be applied for the development of intelligent systems, including neuromorphic and in-memory computing systems. Herein, a flexible van der Waals (vdW) optoelectronic synapse is reported, which is a core component of optogenetics-inspired intelligent systems. This synapse is fabricated on 2D vdW layered rhenium disulfide (ReS 2 ) that features an inherent photosensitive memory nature derived from the persistent photoconductivity (PPC) effect, successfully mimicking the dynamics of biological synapses. Based on first-principles calculations, the PPC effect is identified to originate from sulfur vacancies in ReS 2 that have an inherent tendency to form shallow defect states near the conduction band edges and under optical excitation lead to large lattice relaxation. Finally, the feasibility of applying the synapses in optogenetics-inspired intelligent systems is demonstrated via training and inference tasks for the CIFAR-10 dataset using a convolutional neural network composed of vdW optoelectronic synapse devices., (© 2021 Wiley-VCH GmbH.)

Published

2021

21. Biomimetic Hairy Whiskers for Robotic Skin Tactility.

Author

An J, Chen P, Wang Z, Berbille A, Pang H, Jiang Y, Jiang T, and Wang ZL

Subjects

Animals, Mechanoreceptors physiology, Humans, Skin metabolism, Hair chemistry, Robotics instrumentation, Biomimetic Materials chemistry, Vibrissae physiology, Touch, Biomimetics methods, Biomimetics instrumentation

Abstract

Touch sensing is among the most important sensing capabilities of a human, and the same is true for smart robotics. Current research on tactile sensors is mainly concentrated on electronic skin (e-skin), but e-skin is prone to be easily dirtied, damaged, and disturbed after repeated usage, which greatly limits its practical applications in robotics. Here, by mimicking the way that animals explore the environment using hair-based sensors, a bendable biomimetic whisker mechanoreceptor (BWMR) is designed for robotic tactile sensing. Owing to the advantages of triboelectric nanogenerator technology, the BWMR can convert external mechanical stimuli into electrical signals without a power supply, which is conducive to its widespread applications in robots. Because of the leverage effect of the whisker, the BWMR can distinguish an exciting force of 1.129 μN by amplifying external weak signals, which can be further improved by increasing the whisker length. Real-time sensing is demonstrated using a BWMR, exhibiting its potential for robotic tactile systems., (© 2021 Wiley-VCH GmbH.)

Published

2021

22. HASEL Artificial Muscles for a New Generation of Lifelike Robots-Recent Progress and Future Opportunities.

Author

Rothemund P, Kellaris N, Mitchell SK, Acome E, and Keplinger C

Subjects

Static Electricity, Humans, Artificial Organs, Muscles physiology, Biomimetic Materials chemistry, Equipment Design, Animals, Biomimetics methods, Robotics instrumentation

Abstract

Future robots and intelligent systems will autonomously navigate in unstructured environments and closely collaborate with humans; integrated with our bodies and minds, they will allow us to surpass our physical limitations. Traditional robots are mostly built from rigid, metallic components and electromagnetic motors, which make them heavy, expensive, unsafe near people, and ill-suited for unpredictable environments. By contrast, biological organisms make extensive use of soft materials and radically outperform robots in terms of dexterity, agility, and adaptability. Particularly, natural muscle-a masterpiece of evolution-has long inspired researchers to create "artificial muscles" in an attempt to replicate its versatility, seamless integration with sensing, and ability to self-heal. To date, natural muscle remains unmatched in all-round performance, but rapid advancements in soft robotics have brought viable alternatives closer than ever. Herein, the recent development of hydraulically amplified self-healing electrostatic (HASEL) actuators, a new class of high-performance, self-sensing artificial muscles that couple electrostatic and hydraulic forces to achieve diverse modes of actuation, is discussed; current designs match or exceed natural muscle in many metrics. Research on materials, designs, fabrication, modeling, and control systems for HASEL actuators is detailed. In each area, research opportunities are identified, which together lays out a roadmap for actuators with drastically improved performance. With their unique versatility and wide potential for further improvement, HASEL actuators are poised to play an important role in a paradigm shift that fundamentally challenges the current limitations of robotic hardware toward future intelligent systems that replicate the vast capabilities of biological organisms., (© 2020 The Authors. Published by Wiley-VCH GmbH.)

Published

2021

23. Shape Changing Robots: Bioinspiration, Simulation, and Physical Realization.

Author

Shah D, Yang B, Kriegman S, Levin M, Bongard J, and Kramer-Bottiglio R

Subjects

Biomimetics methods, Biomimetic Materials chemistry, Animals, Algorithms, Computer Simulation, Robotics

Abstract

One of the key differentiators between biological and artificial systems is the dynamic plasticity of living tissues, enabling adaptation to different environmental conditions, tasks, or damage by reconfiguring physical structure and behavioral control policies. Lack of dynamic plasticity is a significant limitation for artificial systems that must robustly operate in the natural world. Recently, researchers have begun to leverage insights from regenerating and metamorphosing organisms, designing robots capable of editing their own structure to more efficiently perform tasks under changing demands and creating new algorithms to control these changing anatomies. Here, an overview of the literature related to robots that change shape to enhance and expand their functionality is presented. Related grand challenges, including shape sensing, finding, and changing, which rely on innovations in multifunctional materials, distributed actuation and sensing, and somatic control to enable next-generation shape changing robots are also discussed., (© 2020 Wiley-VCH GmbH.)

Published

2021

24. Programmable Design and Performance of Modular Magnetic Microswimmers.

Author

Pauer C, du Roure O, Heuvingh J, Liedl T, and Tavacoli J

Subjects

Biomimetic Materials chemistry, Swimming, Biomimetics methods, Biomimetics instrumentation, Magnetic Phenomena, Equipment Design

Abstract

Synthetic biomimetic microswimmers are promising agents for in vivo healthcare and important frameworks to advance the understanding of locomotion strategies and collective motion at the microscopic scale. Nevertheless, constructing these devices with design flexibility and in large numbers remains a challenge. Here, a step toward meeting this challenge is taken by assembling such swimmers via the programmed shape and arrangement of superparamagnetic micromodules. The method's capacity for design flexibility is demonstrated through the assembly of a variety of swimmer architectures. On their actuation, strokes characterized by a balance of viscous and magnetic forces are found in all cases, but swimmers formed from a series of size-graded triangular modules swim quicker than more traditional designs comprising a circular "head" and a slender tail. Linking performance to design, rules are extracted informing the construction of a second-generation swimmer with a short tail and an elongated head optimized for speed. Its fast locomotion is attributed to a stroke that better breaks beating symmetry and an ability to beat fully with flex at high frequencies. Finally, production at scale is demonstrated through the assembly and swimming of a flock of the triangle-based architectures to reveal four types of swimmer couplings., (© 2021 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2021

25. Hierarchically Molecular Imprinted Porous Particles for Biomimetic Kidney Cleaning.

Author

Chen H, Bian F, Sun L, Zhang D, Shang L, and Zhao Y

Subjects

Porosity, Adsorption, Kidney, Humans, Biomimetics methods, Kidneys, Artificial, Biomimetic Materials chemistry, Molecular Imprinting methods

Abstract

Blood purification by adsorption of excessive biomolecules is vital for maintaining human health. Here, inspired by kidney self-purification, which removes a number of biomolecules with different sizes simultaneously, hierarchical molecular-imprinted inverse opal particles integrated with a herringbone microfluidic chip for efficient biomolecules cleaning are presented. The particle possesses combinative porous structure with both surface and interior imprints for the specific recognition of small molecules and biomacromolecules. Additionally, the presence of the herringbone mixer largely improve the adsorption efficiency due to enhanced mixing. Moreover, the inverse opal framework of the particles give rise to optical sensing ability for self-reporting of the adsorption states. These features, together with its reusability, biosafety, and biocompatibility, make the platform highly promising for clinical blood purification and artificial kidney construction., (© 2020 Wiley-VCH GmbH.)

Published

2020

26. ATP-Responsive and ATP-Fueled Self-Assembling Systems and Materials.

Author

Deng J and Walther A

Subjects

Animals, Humans, Adenosine Triphosphate metabolism, Biomimetics methods

Abstract

Adenosine triphosphate (ATP) is a central metabolite that plays an indispensable role in various cellular processes, from energy supply to cell-to-cell signaling. Nature has developed sophisticated strategies to use the energy stored in ATP for many metabolic and non-equilibrium processes, and to sense and bind ATP for biological signaling. The variations in the ATP concentrations from one organelle to another, from extracellular to intracellular environments, and from normal cells to cancer cells are one motivation for designing ATP-triggered and ATP-fueled systems and materials, because they show great potential for applications in biological systems by using ATP as a trigger or chemical fuel. Over the last decade, ATP has been emerging as an attractive co-assembling component for man-made stimuli-responsive as well as for fuel-driven active systems and materials. Herein, current advances and emerging concepts for ATP-triggered and ATP-fueled self-assemblies and materials are discussed, shedding light on applications and highlighting future developments. By bringing together concepts of different domains, that is from supramolecular chemistry to DNA nanoscience, from equilibrium to non-equilibrium self-assembly, and from fundamental sciences to applications, the aim is to cross-fertilize current approaches with the ultimate aim to bring synthetic ATP-dependent systems closer to living systems., (© 2020 The Authors. Published by Wiley-VCH GmbH.)

Published

2020

27. Bioinspired Soft Microrobots with Precise Magneto-Collective Control for Microvascular Thrombolysis.

Author

Xie M, Zhang W, Fan C, Wu C, Feng Q, Wu J, Li Y, Gao R, Li Z, Wang Q, Cheng Y, and He B

Subjects

Animals, Biocompatible Materials chemistry, Biocompatible Materials pharmacology, Biomimetics instrumentation, Cell Survival drug effects, Coculture Techniques, Ferric Compounds chemistry, Fibrinolytic Agents chemistry, Fibrinolytic Agents metabolism, Fibrinolytic Agents therapeutic use, Humans, Magnetic Fields, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells metabolism, Metal Nanoparticles chemistry, Neutrophils cytology, Neutrophils metabolism, Rats, Thromboembolism drug therapy, Tissue Plasminogen Activator chemistry, Tissue Plasminogen Activator metabolism, Tissue Plasminogen Activator therapeutic use, Umbilical Cord cytology, Biomimetics methods, Magnetosomes chemistry, Robotics

Abstract

New-era soft microrobots for biomedical applications need to mimic the essential structures and collective functions of creatures from nature. Biocompatible interfaces, intelligent functionalities, and precise locomotion control in a collective manner are the key parameters to design soft microrobots for the complex bio-environment. In this work, a biomimetic magnetic microrobot (BMM) inspired by magnetotactic bacteria (MTB) with speedy motion response and accurate positioning is developed for targeted thrombolysis. Similar to the magnetosome structure in MTB, the BMM is composed of aligned iron oxide nanoparticle (MNP) chains embedded in a non-swelling microgel shell. Linear chains in BMMs are achieved due to the interparticle dipolar interactions of MNPs under a static magnetic field. Simulation results show that, the degree and speed of assembly is proportional to the field strength. The BMM achieves the maximum speed of 161.7 µm s -1 and accurate positioning control under a rotating magnetic field with less than 4% deviation. Importantly, the locomotion analyses of BMMs demonstrate the frequency-dependent synchronization under 8 Hz and asynchronization at higher frequencies due to the increased drag torque. The BMMs can deliver and release thrombolytic drugs via magneto-collective control, which is promising for ultra-minimal invasive thrombolysis., (© 2020 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

28. Viewpoint: Pavlovian Materials-Functional Biomimetics Inspired by Classical Conditioning.

Author

Zhang H, Zeng H, Priimagi A, and Ikkala O

Subjects

Mechanical Phenomena, Biomimetics methods, Conditioning, Classical

Abstract

Herein, it is discussed whether the complex biological concepts of (associative) learning can inspire responsive artificial materials. It is argued that classical conditioning, being one of the most elementary forms of learning, inspires algorithmic realizations in synthetic materials, to allow stimuli-responsive materials that learn to respond to a new stimulus, to which they are originally insensitive. Two synthetic model systems coined as "Pavlovian materials" are described, whose stimuli-responsiveness algorithmically mimics programmable associative learning, inspired by classical conditioning. The concepts minimally need a stimulus-triggerable memory, in addition to two stimuli, i.e., the unconditioned and the originally neutral stimuli. Importantly, the concept differs conceptually from the classic stimuli-responsive and shape-memory materials, as, upon association, Pavlovian materials obtain a given response using a new stimulus (the originally neutral one); i.e., the system evolves to a new state. This also enables the functionality to be described by a logic diagram. Ample room for generalization to different stimuli and memory combinations is foreseen, and opportunities to develop future adaptive materials with ever-more intelligent functions are expected., (© 2020 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

29. Advanced Actuator Materials Powered by Biomimetic Helical Fiber Topologies.

Author

Spinks GM

Subjects

Mechanical Phenomena, Biomimetics methods, Smart Materials

Abstract

Helical constructs are ubiquitous in nature at all size domains, from molecular to macroscopic. The helical topology confers unique mechanical functions that activate certain phenomena, such as twining vines and vital cellular functions like the folding and packing of DNA into chromosomes. The understanding of active mechanical processes in plants, certain musculature in animals, and some biochemical processes in cells provides insight into the versatility of the helix. Most of these natural systems consist of helically oriented filaments embedded in a compliant matrix. In some cases, the matrix can change volume and in others the filaments can contract and the matrix is passive. In both cases, the helically arranged fibers determine the overall shape change with a great variety of responses involving length contraction/elongation, twisting, bending, and coiling. Synthetic actuator materials and systems that employ helical topologies have been described recently and demonstrate many fascinating and complex shape changes. However, significant new opportunities exist to mimic some of the most remarkable actions in nature, including the Vorticella's coiling stalk and DNA's supercoils, in the quest for superior artificial muscles., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

30. When Flexible Organic Field-Effect Transistors Meet Biomimetics: A Prospective View of the Internet of Things.

Author

Shi W, Guo Y, and Liu Y

Subjects

Biomimetics instrumentation, Biosensing Techniques, Glucose analysis, Humans, Information Storage and Retrieval, Internet of Things, Skin chemistry, Skin metabolism, Wearable Electronic Devices, Biomimetics methods, Transistors, Electronic

Abstract

The emergence of flexible organic electronics that span the fields of physics and biomimetics creates the possibility for increasingly simple and intelligent products for use in everyday life. Organic field-effect transistors (OFETs), with their inherent flexibility, light weight, and biocompatibility, have shown great promise in the field of biomimicry. By applying such biomimetic OFETs for the internet of things (IoT) makes it possible to imagine novel products and use cases for the future. Recent advances in flexible OFETs and their applications in biomimetic systems are reviewed. Strategies to achieve flexible OFETs are individually discussed and recent progress in biomimetic sensory systems and nervous systems is reviewed in detail. OFETs are revealed to be one of the best systems for mimicking sensory and nervous systems. Additionally, a brief discussion of information storage based on OFETs is presented. Finally, a personal view of the utilization of biomimetic OFETs in the IoT and future challenges in this research area are provided., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

31. Flexible Neuromorphic Electronics for Computing, Soft Robotics, and Neuroprosthetics.

Author

Park HL, Lee Y, Kim N, Seo DG, Go GT, and Lee TW

Subjects

Artificial Organs, Biomimetics instrumentation, Neural Networks, Computer, Neuronal Plasticity, Synapses physiology, Biomimetics methods, Electronics, Robotics

Abstract

Flexible neuromorphic electronics that emulate biological neuronal systems constitute a promising candidate for next-generation wearable computing, soft robotics, and neuroprosthetics. For realization, with the achievement of simple synaptic behaviors in a single device, the construction of artificial synapses with various functions of sensing and responding and integrated systems to mimic complicated computing, sensing, and responding in biological systems is a prerequisite. Artificial synapses that have learning ability can perceive and react to events in the real world; these abilities expand the neuromorphic applications toward health monitoring and cybernetic devices in the future Internet of Things. To demonstrate the flexible neuromorphic systems successfully, it is essential to develop artificial synapses and nerves replicating the functionalities of the biological counterparts and satisfying the requirements for constructing the elements and the integrated systems such as flexibility, low power consumption, high-density integration, and biocompatibility. Here, the progress of flexible neuromorphic electronics is addressed, from basic backgrounds including synaptic characteristics, device structures, and mechanisms of artificial synapses and nerves, to applications for computing, soft robotics, and neuroprosthetics. Finally, future research directions toward wearable artificial neuromorphic systems are suggested for this emerging area., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

32. Biohybrid Design Gets Personal: New Materials for Patient-Specific Therapy.

Author

Raman R and Langer R

Subjects

Animals, Biocompatible Materials chemistry, Biocompatible Materials therapeutic use, Biomimetic Materials chemistry, Humans, Hydrogels chemistry, Hydrogels therapeutic use, Prostheses and Implants, Biomimetic Materials therapeutic use, Biomimetics methods, Precision Medicine methods

Abstract

Precision medicine requires materials and devices that can sense and adapt to dynamic physiological and pathological conditions. This motivates the design and manufacture of biohybrid materials that mimic the responsive behaviors demonstrated by natural biological systems. Two parallel approaches to biohybrid design are presented-biomimetics and biointegration. Biohybrid hydrogels that mimic the form and function of natural materials, or that integrate living cells or bioactive moieties, can respond to a range of environmental stimuli in parallel, including heat, light, pH, hydration, enzymes, and electric, mechanical, and magnetic forces. A range of examples that illustrate the tremendous potential of this nascent discipline are presented, and ongoing technical challenges related to manufacturing, storage, transport, and external noninvasive control of these materials that will need to be overcome in the coming years are outlined. The ethical, educational, and regulatory challenges that will govern translation of biohybrid design into medical applications are also discussed. Personalized medical therapies that target the precise needs of patients are a critically needed and expanding market. Biohybrid design offers the unique ability to manufacture materials and devices that match the dynamic and patient-specific in vivo environment, promising to generate more effective and safe therapies that enable personalized care., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

33. Biomimetic Nanotechnology toward Personalized Vaccines.

Author

Zhou J, Kroll AV, Holay M, Fang RH, and Zhang L

Subjects

Animals, Bacterial Infections prevention & control, Bacterial Vaccines administration & dosage, Bacterial Vaccines therapeutic use, Biomimetic Materials chemistry, Biomimetics methods, Cancer Vaccines administration & dosage, Cancer Vaccines therapeutic use, Drug Delivery Systems methods, Humans, Nanoparticles chemistry, Nanotechnology methods, Neoplasms prevention & control, Nanomedicine methods, Precision Medicine methods, Vaccination methods

Abstract

While traditional approaches for disease management in the era of modern medicine have saved countless lives and enhanced patient well-being, it is clear that there is significant room to improve upon the current status quo. For infectious diseases, the steady rise of antibiotic resistance has resulted in super pathogens that do not respond to most approved drugs. In the field of cancer treatment, the idea of a cure-all silver bullet has long been abandoned. As a result of the challenges facing current treatment and prevention paradigms in the clinic, there is an increasing push for personalized therapeutics, where plans for medical care are established on a patient-by-patient basis. Along these lines, vaccines, both against bacteria and tumors, are a clinical modality that could benefit significantly from personalization. Effective vaccination strategies could help to address many challenging disease conditions, but current vaccines are limited by factors such as a lack of potency and antigenic breadth. Recently, researchers have turned toward the use of biomimetic nanotechnology as a means of addressing these hurdles. Recent progress in the development of biomimetic nanovaccines for antibacterial and anticancer applications is discussed, with an emphasis on their potential for personalized medicine., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

34. Water Oxidation Catalysts for Artificial Photosynthesis.

Author

Ye S, Ding C, Liu M, Wang A, Huang Q, and Li C

Subjects

Catalysis, Oxidation-Reduction, Biomimetics methods, Photosynthesis, Water chemistry

Abstract

Water oxidation is the primary reaction of both natural and artificial photosynthesis. Developing active and robust water oxidation catalysts (WOCs) is the key to constructing efficient artificial photosynthesis systems, but it is still facing enormous challenges in both fundamental and applied aspects. Here, the recent developments in molecular catalysts and heterogeneous nanoparticle catalysts are reviewed with special emphasis on biomimetic catalysts and the integration of WOCs into artificial photosystems. The highly efficient artificial photosynthesis depends largely on active WOCs integrated into light harvesting materials via rational interface engineering based on in-depth understanding of charge dynamics and the reaction mechanism., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

35. Living Materials Herald a New Era in Soft Robotics.

Author

Appiah C, Arndt C, Siemsen K, Heitmann A, Staubitz A, and Selhuber-Unkel C

Subjects

Animals, Biomimetics instrumentation, Equipment Design, Humans, Robotics instrumentation, Biomimetics methods, Mechanical Phenomena, Robotics methods

Abstract

Living beings have an unsurpassed range of ways to manipulate objects and interact with them. They can make autonomous decisions and can heal themselves. So far, a conventional robot cannot mimic this complexity even remotely. Classical robots are often used to help with lifting and gripping and thus to alleviate the effects of menial tasks. Sensors can render robots responsive, and artificial intelligence aims at enabling autonomous responses. Inanimate soft robots are a step in this direction, but it will only be in combination with living systems that full complexity will be achievable. The field of biohybrid soft robotics provides entirely new concepts to address current challenges, for example the ability to self-heal, enable a soft touch, or to show situational versatility. Therefore, "living materials" are at the heart of this review. Similarly to biological taxonomy, there is a recent effort for taxonomy of biohybrid soft robotics. Here, an expansion is proposed to take into account not only function and origin of biohybrid soft robotic components, but also the materials. This materials taxonomy key demonstrates visually that materials science will drive the development of the field of soft biohybrid robotics., (© 2019 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

36. Grow with the Flow: When Morphogenesis Meets Microfluidics.

Author

Samal P, van Blitterswijk C, Truckenmüller R, and Giselbrecht S

Subjects

Biomimetics methods, Cell Culture Techniques, Cell Differentiation, Cell Membrane enzymology, Cell Membrane metabolism, Humans, Organogenesis, Polymers chemistry, Surface Properties, Tissue Scaffolds chemistry, Microfluidics methods, Morphogenesis drug effects, Pluripotent Stem Cells enzymology, Pluripotent Stem Cells metabolism

Abstract

Developmental biology has advanced the understanding of the intricate and dynamic processes involved in the formation of an organism from a single cell. However, many gaps remain in the knowledge of embryonic development, especially regarding tissue morphogenesis. A possible approach to mimic such phenomena uses pluripotent stem cells in in vitro morphogenetic models. Herein, these systems are summarized with emphasis on the ability to better manipulate and control cellular interfaces with either liquid or solid materials using microengineered tools, which is critical for attaining deeper insights into pattern formation and stem cell differentiation during organogenesis. The role of conventional and customized cell-culture systems in supporting important advances in the field of morphogenesis is discussed, and the fascinating role that material sciences and microengineering currently play and are expected to play in the future is highlighted. In conclusion, it is proffered that continued microfluidics innovations when applied to morphogenesis promise to provide important insights to advance many multidisciplinary fields, including regenerative medicine., (© 2019 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

37. Additive Manufacturing as a Method to Design and Optimize Bioinspired Structures.

Author

Velasco-Hogan A, Xu J, and Meyers MA

Subjects

Animals, Biomimetics methods, Biomimetic Materials, Printing, Three-Dimensional

Abstract

Additive manufacturing (AM) is a current technology undergoing rapid development that is utilized in a wide variety of applications. In the field of biological and bioinspired materials, additive manufacturing is being used to generate intricate prototypes to expand our understanding of the fundamental structure-property relationships that govern nature's spectacular mechanical performance. Herein, recent advances in the use of AM for improving the understanding of the structure-property relationship in biological materials and for the production of bioinspired materials are reviewed. There are four essential components to this work: a) extracting defining characteristics of biological designs, b) designing 3D-printed prototypes, c) performing mechanical testing on 3D-printed prototypes to understand fundamental mechanisms at hand, and d) optimizing design for tailorable performance. It is intended to highlight how the various types of additive manufacturing methods are utilized, to unravel novel discoveries in the field of biological materials. Since AM processing techniques have surpassed antiquated limitations, especially with respect to spatial scales, there has been a surge in their demand as an integral tool for research. In conclusion, current challenges and the technical perspective for further development of bioinspired materials using AM are discussed., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

38. Bacteria-Based Materials for Stem Cell Engineering.

Author

Hay JJ, Rodrigo-Navarro A, Petaroudi M, Bryksin AV, García AJ, Barker TH, Dalby MJ, and Salmeron-Sanchez M

Subjects

Biomimetics methods, Bone Morphogenetic Protein 2 genetics, Bone Morphogenetic Protein 2 metabolism, Cell Adhesion physiology, Fibronectins genetics, Fibronectins metabolism, Humans, Hydrogels, Lactococcus lactis growth & development, Mesenchymal Stem Cells cytology, Osteogenesis physiology, Tissue Scaffolds microbiology, Biomimetic Materials, Cell Engineering methods, Lactococcus lactis genetics, Lactococcus lactis metabolism, Mesenchymal Stem Cells physiology

Abstract

Materials can be engineered to deliver specific biological cues that control stem cell growth and differentiation. However, current materials are still limited for stem cell engineering as stem cells are regulated by a complex biological milieu that requires spatiotemporal control. Here a new approach of using materials that incorporate designed bacteria as units that can be engineered to control human mesenchymal stem cells (hMSCs), in a highly dynamic-temporal manner, is presented. Engineered Lactococcus lactis spontaneously colonizes a variety of material surfaces (e.g., polymers, metals, and ceramics) and is able to maintain growth and induce differentiation of hMSCs in 2D/3D surfaces and hydrogels. Controlled, dynamic, expression of fibronectin fragments supports stem cell growth, whereas inducible-temporal regulation of secreted bone morphogenetic protein-2 drives osteogenesis in an on-demand manner. This approach enables stem cell technologies using material systems that host symbiotic interactions between eukaryotic and prokaryotic cells., (© 2018 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

39. Fibrous Protein Self-Assembly in Biomimetic Materials.

Author

Mason TO and Shimanovich U

Subjects

Animals, Biomimetic Materials chemical synthesis, Biomimetics methods, Biomimetic Materials chemistry, Proteins chemistry

Abstract

Protein self-assembly processes, by which polypeptides interact and independently form multimeric structures, lead to a wide array of different endpoints. Structures formed range from highly ordered molecular crystals to amorphous aggregates. Order arises in the system from a balance between many low-energy processes occurring due to a set of interactions between residues in a chain, between residues in different chains, and between solute and solvent. In Nature, self-assembling protein systems have evolved over millions of years to organize into supramolecular structures, optimized for specific functions, with this propensity determined by the sequence of their constituent amino acids, of which only 20 are encoded in DNA. The structural materials that arise from biological self-assembly can display remarkable mechanical properties, often as a result of hierarchical structure on the nano- and microscales, and much research has been devoted to mimicking and exploiting these properties for a variety of end uses. This work presents a review of a range of studies in which biological functions are effectively reproduced through the design of self-assembling fibrous protein systems., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

40. Combining In Silico Design and Biomimetic Assembly: A New Approach for Developing High-Performance Dynamic Responsive Bio-Nanomaterials.

Author

Ling S, Jin K, Qin Z, Li C, Zheng K, Zhao Y, Wang Q, Kaplan DL, and Buehler MJ

Subjects

Animals, Durapatite chemistry, Materials Testing, Models, Molecular, Nacre chemistry, Silk chemistry, Biomimetic Materials chemical synthesis, Biomimetic Materials chemistry, Biomimetics methods, Computer Simulation, Nanostructures chemistry

Abstract

Major challenge remains in the design and fabrication of artificial hierarchical materials that mimic the structural and functional features of these natural materials. Here, a novel biomimetic strategy to assemble hierarchical materials from biological nanobuilding blocks is demonstrated. The constituents and structures of the materials are designed by multiscale modeling and then experimentally constructed by multiscale self-assembly. The resultant materials that consist of silk nanofibrils (SNFs), hydroxyapatite (HAP), and chitin nanofibrils (CNFs) show nacre-like structures with mechanical strength and toughness better than most natural nacre and nacre-like nanocomposites. In addition, these SNF/HAP:CNF nanocomposites can be programmed into "grab-and-release" actuators due to the gradient structure of the nanocomposites as well as the high water sensitivity of each of the components, and thusshow potential applications in the design of novel third-generation biomaterials for potential clinical applications. In addition, this "in silico design and biomimetic assembly" route represents a rational, low-cost, and efficient strategy for the design and preparation of robust, hierarchical, and functional nanomaterials to meet a variety of application requirements in bio-nanotechnologies., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

41. Biomineralization: From Material Tactics to Biological Strategy.

Author

Yao S, Jin B, Liu Z, Shao C, Zhao R, Wang X, and Tang R

Subjects

Animals, Biological Evolution, Biomimetics methods, Humans, Biomimetic Materials chemical synthesis, Biomimetic Materials chemistry, Calcification, Physiologic, Minerals chemistry

Abstract

Biomineralization is an important tactic by which biological organisms produce hierarchically structured minerals with marvellous functions. Biomineralization studies typically focus on the mediation function of organic matrices on inorganic minerals, which helps scientists to design and synthesize bioinspired functional materials. However, the presence of inorganic minerals may also alter the native behaviours of organic matrices and even biological organisms. This progress report discusses the latest achievements relating to biomineralization mechanisms, the manufacturing of biomimetic materials and relevant applications in biological and biomedical fields. In particular, biomineralized vaccines and algae with improved thermostability and photosynthesis, respectively, demonstrate that biomineralization is a strategy for organism evolution via the rational design of organism-material complexes. The successful modification of biological systems using materials is based on the regulatory effect of inorganic materials on organic organisms, which is another aspect of biomineralization control. Unlike previous studies, this study integrates materials and biological science to achieve a more comprehensive view of the mechanisms and applications of biomineralization., (© 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

42. Nano/Micro-Manufacturing of Bioinspired Materials: a Review of Methods to Mimic Natural Structures.

Author

Zhang C, Mcadams DA 2nd, and Grunlan JC

Subjects

Adhesives, Animals, Biomimetic Materials chemistry, Bone and Bones chemistry, Eye, Lizards anatomy & histology, Nacre chemistry, Photons, Biomimetic Materials chemical synthesis, Biomimetics methods, Nanostructures chemistry

Abstract

Through billions of years of evolution and natural selection, biological systems have developed strategies to achieve advantageous unification between structure and bulk properties. The discovery of these fascinating properties and phenomena has triggered increasing interest in identifying characteristics of biological materials, through modern characterization and modeling techniques. In an effort to produce better engineered materials, scientists and engineers have developed new methods and approaches to construct artificial advanced materials that resemble natural architecture and function. A brief review of typical naturally occurring materials is presented here, with a focus on chemical composition, nano-structure, and architecture. The critical mechanisms underlying their properties are summarized, with a particular emphasis on the role of material architecture. A review of recent progress on the nano/micro-manufacturing of bio-inspired hybrid materials is then presented in detail. In this case, the focus is on nacre and bone-inspired structural materials, petals and gecko foot-inspired adhesive films, lotus and mosquito eye inspired superhydrophobic materials, brittlestar and Morpho butterfly-inspired photonic structured coatings. Finally, some applications, current challenges and future directions with regard to manufacturing bio-inspired hybrid materials are provided., (© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

43. Structural Design Elements in Biological Materials: Application to Bioinspiration.

Author

Naleway SE, Porter MM, McKittrick J, and Meyers MA

Subjects

Animals, Biomimetic Materials, Humans, Mechanical Phenomena, Biomimetics methods

Abstract

Eight structural elements in biological materials are identified as the most common amongst a variety of animal taxa. These are proposed as a new paradigm in the field of biological materials science as they can serve as a toolbox for rationalizing the complex mechanical behavior of structural biological materials and for systematizing the development of bioinspired designs for structural applications. They are employed to improve the mechanical properties, namely strength, wear resistance, stiffness, flexibility, fracture toughness, and energy absorption of different biological materials for a variety of functions (e.g., body support, joint movement, impact protection, weight reduction). The structural elements identified are: fibrous, helical, gradient, layered, tubular, cellular, suture, and overlapping. For each of the structural design elements, critical design parameters are presented along with constitutive equations with a focus on mechanical properties. Additionally, example organisms from varying biological classes are presented for each case to display the wide variety of environments where each of these elements is present. Examples of current bioinspired materials are also introduced for each element., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

44. Biomimetic Approach for Ion Channels Based on Surfactant Encapsulated Spherical Porous Metal-Oxide Capsules.

Author

Mahon E, Garai S, Müller A, and Barboiu M

Subjects

Capsules, Hydrophobic and Hydrophilic Interactions, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Models, Molecular, Molecular Conformation, Porosity, Unilamellar Liposomes chemistry, Unilamellar Liposomes metabolism, Biomimetics methods, Ion Channels metabolism, Metals chemistry, Oxides chemistry, Surface-Active Agents chemistry

Abstract

Distinguished hybrid clusters with hydrophilic and hydrophobic interiors embedded within cationic surfactant shells are spontaneously inserted into lipid bilayers, showing well-defined ionic conductance behaviors. The transport via the narrow pore gates acting as selectivity filters is controlled by the dehydration energy of the cations., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

45. Bioinspired gas bubble spontaneous and directional transportation effects in an aqueous medium.

Author

Ma R, Wang J, Yang Z, Liu M, Zhang J, and Jiang L

Subjects

Copper chemistry, Hydrophobic and Hydrophilic Interactions, Motion, Porosity, Surface Properties, Biomimetics methods, Gases chemistry, Water chemistry

Abstract

A series of well-ordered, 3D gradient porous interconnected network surfaces composed of micro-nano hierarchical geometries is constructed on a copper wire. A continuous gas film can be trapped around its interface in an aqueous medium acting as an effective channel for gas transportation. Driving by the difference of the Laplace pressure, gas bubbles can be transported spontaneously and directionally., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

46. Biomimetic microfingerprints for anti-counterfeiting strategies.

Author

Bae HJ, Bae S, Park C, Han S, Kim J, Kim LN, Kim K, Song SH, Park W, and Kwon S

Subjects

Humans, Mechanical Phenomena, Microspheres, Silicon Dioxide, Biomimetics methods, Dermatoglyphics, Fraud prevention & control

Abstract

An unclonable, fingerprint-mimicking anti-counterfeiting strategy is presented that encrypts polymeric particles with randomly generated silica film wrinkles. The generated wrinkle codes are as highly unique as human fingerprints and are technically irreproducible. Superior to previous physical unclonable functions, codes are tunable on demand and generable on various geometries. Reliable authentication of real-world products that have these microfingerprints is demonstrated using optical decoding methods., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

47. Bioinspired engineering of thermal materials.

Author

Tao P, Shang W, Song C, Shen Q, Zhang F, Luo Z, Yi N, Zhang D, and Deng T

Subjects

Animals, Humans, Biomimetic Materials chemistry, Biomimetics methods, Temperature

Abstract

In the development of next-generation materials with enhanced thermal properties, biological systems in nature provide many examples that have exceptional structural designs and unparalleled performance in their thermal or nonthermal functions. Bioinspired engineering thus offers great promise in the synthesis and fabrication of thermal materials that are difficult to engineer through conventional approaches. In this review, recent progress in the emerging area of bioinspired advanced materials for thermal science and technology is summarized. State-of-the-art developments of bioinspired thermal-management materials, including materials for efficient thermal insulation and heat transfer, and bioinspired materials for thermal/infrared detection, are highlighted. The dynamic balance of bioinspiration and practical engineering, the correlation of inspiration approaches with the targeted applications, and the coexistence of molecule-based inspiration and structure-based inspiration are discussed in the overview of the development. The long-term outlook and short-term focus of this critical area of advanced materials engineering are also presented., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

48. Bioinspired materials: from low to high dimensional structure.

Author

Zhao N, Wang Z, Cai C, Shen H, Liang F, Wang D, Wang C, Zhu T, Guo J, Wang Y, Liu X, Duan C, Wang H, Mao Y, Jia X, Dong H, Zhang X, and Xu J

Subjects

Animals, Humans, Molecular Conformation, Biomimetic Materials chemistry, Biomimetics methods

Abstract

The surprising properties of biomaterials are the results of billions of years of evolution. Generally, biomaterials are assembled under mild conditions with very limited supply of constituents available for living organism, and their amazing properties largely result from the sophisticated hierarchical structures. Following the biomimetic principles to prepare manmade materials has drawn great research interests in materials science and engineering. In this review, we summarize the recent progress in fabricating bioinspired materials with the emphasis on mimicking the structure from one to three dimensions. Selected examples are described with a focus on the relationship between the structural characters and the corresponding functions. For one-dimensional materials, spider fibers, polar bear hair, multichannel plant roots and so on have been involved. Natural structure color and color shifting surfaces, and the antifouling, antireflective coatings of biomaterials are chosen as the typical examples of the two-dimensional biomimicking. The outstanding protection performance, and the stimuli responsive and self-healing functions of biomaterials based on the sophisticated hierarchical bulk structures are the emphases of the three-dimensional mimicking. Finally, a summary and outlook are given., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

49. A biomimetic multi-stimuli-response ionic gate using a hydroxypyrene derivation-functionalized asymmetric single nanochannel.

Author

Xiao K, Xie G, Li P, Liu Q, Hou G, Zhang Z, Ma J, Tian Y, Wen L, and Jiang L

Subjects

Hydrogen-Ion Concentration, Models, Molecular, Protein Conformation, Rhodopsin chemistry, Rhodopsin metabolism, Arylsulfonates chemistry, Biomimetics methods, Ion Channel Gating, Light, Nanotechnology methods

Abstract

A highly efficient multi-stimuli-response ionic gate that can be activated separately or cooperatively by pH and UV light has been demonstrated by modifying the environmental stimuli-responsive molecule 8-hydroxypyrene-1,3,6-trisulfonate into a track-etched single conical nanochannel. Such a multi-response ionic gate can find applications in areas such as electronics, actuators, and biosensors., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

50. Bioinspired multicompartmental microfibers from microfluidics.

Author

Cheng Y, Zheng F, Lu J, Shang L, Xie Z, Zhao Y, Chen Y, and Gu Z

Subjects

Equipment Design, Equipment Failure Analysis, Materials Testing, Miniaturization, Biomimetic Materials chemical synthesis, Biomimetics instrumentation, Biomimetics methods, Microfluidics instrumentation, Microfluidics methods, Textiles

Abstract

Bioinspired multicompartmental microfibers are generated by novel capillary microfluidics. The resultant microfibers possess multicompartment body-and-shell compositions with specifically designed geometries. Potential use of these microfibers for tissue-engineering applications is demonstrated by creating multifunctional fibers with a spatially controlled encapsulation of cells., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014