Smart Multi-Responsive Biomaterials and Their Applications for 4D Bioprinting

Biomimetics, Год журнала: 2024, Номер 9(8), С. 484 - 484

Опубликована: Авг. 11, 2024

The emergence of 4D printing has become a pivotal tool to produce complex structures in biomedical applications such as tissue engineering and regenerative medicine. This chapter provides concise overview the current state field its immense potential better understand involved technologies build sophisticated 4D-printed structures. These have capability sense respond diverse range stimuli, which include changes temperature, humidity, or electricity/magnetics. First, we describe technologies, extrusion-based inkjet printing, light-based droplet-based methods including selective laser sintering (SLS). Several types biomaterials for can undergo structural various external stimuli over time were also presented. hold promise revolutionizing fields that require adaptable intelligent materials. Moreover, smart highlighted, spanning wide spectrum intended from drug delivery Finally, address number challenges associated with touching upon ethical regulatory aspects along need standardized protocols both vitro well vivo testing structures, are crucial steps toward eventual clinical realization.

Язык: Английский

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Revolutionizing healthcare: Emerging frontiers in 3D bioprinting of tissues and organs

European Polymer Journal, Год журнала: 2024, Номер 217, С. 113210 - 113210

Опубликована: Июль 18, 2024

Язык: Английский

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Smart biomaterials in healthcare: Breakthroughs in tissue engineering, immunomodulation, patient-specific therapies, and biosensor applications

Applied Physics Reviews, Год журнала: 2025, Номер 12(1)

Опубликована: Март 1, 2025

Smart biomaterials have significantly impacted human healthcare by advancing the development of medical devices designed to function within tissue, mimicking behavior natural tissues. While intelligence has evolved from inert active over past few decades, smart take this a step further making their surfaces or bulk respond based on interactions with surrounding tissues, imparting outcomes similar tissue functions. This interaction helps in creating stimuli-responsive biomaterials, which can be useful engineering, regenerative medicine, autonomous drug delivery, orthopedics, and much more. Traditionally, material engineering focused refining static properties accommodate them body without evoking an immune response, was major obstacle unrestricted operation. review highlights explains various approaches currently under research for developing that tune responses bodily factors like temperature, pH, ion concentration external magnetism, light, conductivity. Applications soft hard 4D printing, scaffold design are also discussed. The advanced application microfluidics, organ-on-a-chip models, extensively benefits intrinsic discussed below. elaborates how biomaterial could revolutionize biosensor applications, thereby improving patient care quality. We delineate limitations key challenges associated providing insights into path forward outlining future directions next-generation will facilitate clinical translation.

Язык: Английский

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4D Bioprinting for Personalized Medicine, Innovations in Implant Fabrication and Regenerative Therapies

Polymer-Plastics Technology and Materials, Год журнала: 2025, Номер unknown, С. 1 - 26

Опубликована: Март 30, 2025

Язык: Английский

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Advances in 4D Bioprinting: The Next Frontier in Regenerative Medicine and Tissue Engineering Applications

Advanced Healthcare Materials, Год журнала: 2024, Номер 14(4)

Опубликована: Дек. 29, 2024

4D bioprinting is a critical advancement in tissue engineering and regenerative medicine (TERM), enabling the creation of structures that dynamically respond to environmental stimuli over time. This review investigates various fabrication techniques responsive materials are central these fields. It underscores integration multi-material biocomposite approaches bioprinting, which crucial for fabricating complex functional constructs with heterogeneous properties. Using enhances mimicry natural characteristics, offering tailored responses improved biological systems. Furthermore, this study highlights synergy between demonstrates technology's potential developing tissues organs. In medicine, bioprinting's applications extend creating smart implants advanced drug delivery systems adapt body's changes, promoting healing regeneration. Finally, challenges future directions also explored emphasize its transformative impact on biomedical healthcare.

Язык: Английский

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Pilot Evaluation of Silicone Surrogates for Oral Mucosa Simulation in Craniofacial Surgical Training

Опубликована: Июнь 24, 2024

Surgical simulators are crucial in early craniofacial and plastic surgical training, necessitating synthetic materials that accurately replicate tissue properties. Recent critiques of our lab’s currently deployed silicone surrogate have highlighted numerous areas for improvement. To further refine models, group's objective is to find a composition closest fidelity native oral mucosa during rehearsal by expert surgeons. Fifteen platinum silicone-based samples were constructed with variable hardness slacker percentages. These underwent evaluation tactile sensation, hardness, needle puncture, cut resistance, suture retention, defect repair, tensile elasticity. Expert surgeon evaluators provided focused qualitative feedback on selected top-performing assessment statistical comparisons. Evaluation revealed characteristics satisfactory good performance. Sample 977 exhibited the highest performance, comparison original (sample 810) demonstrated significant improvements critical areas, emphasizing efficacy refined composition. The study identified directly addresses received team’s surrogate. underscores delicate balance between biofidelity practicality simulation. need ongoing refinement evident optimize training experiences learners.

Язык: Английский

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Pilot Evaluation of Silicone Surrogates for Oral Mucosa Simulation in Craniofacial Surgical Training

Опубликована: Июль 16, 2024

Surgical simulators are crucial in early craniofacial and plastic surgical training, necessitating synthetic materials that accurately replicate tissue properties. Recent critiques of our lab’s currently deployed silicone surrogate have highlighted numerous areas for improvement. To further refine models, group's objective is to find a composition closest fidelity native oral mucosa during rehearsal by expert surgeons. Fifteen platinum silicone-based samples were constructed with variable hardness slacker percentages. These underwent evaluation tactile sensation, hardness, needle puncture, cut resistance, suture retention, defect repair, tensile elasticity. Expert surgeon evaluators provided focused qualitative feedback on selected top-performing assessment statistical comparisons. Evaluation revealed characteristics satisfactory good performance. Sample 977 exhibited the highest performance, comparison original (sample 810) demonstrated significant improvements critical areas, emphasizing efficacy refined composition. The study identified directly addresses received team’s surrogate. underscores delicate balance between biofidelity practicality simulation. need ongoing refinement evident optimize training experiences learners.

Язык: Английский

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Pilot Evaluation of Silicone Surrogates for Oral Mucosa Simulation in Craniofacial Surgical Training

Biomimetics, Год журнала: 2024, Номер 9(8), С. 464 - 464

Опубликована: Авг. 1, 2024

Surgical simulators are crucial in early craniofacial and plastic surgical training, necessitating synthetic materials that accurately replicate tissue properties. Recent critiques of our lab’s currently deployed silicone surrogate have highlighted numerous areas for improvement. To further refine models, group’s objective is to find a composition closest fidelity native oral mucosa during rehearsal by expert surgeons. Fifteen platinum silicone-based samples were constructed with variable hardness slacker percentages. These underwent evaluation tactile sensation, hardness, needle puncture, cut resistance, suture retention, defect repair, tensile elasticity. Expert surgeon evaluators provided focused qualitative feedback on selected top-performing assessment statistical comparisons. An revealed characteristics satisfactory exhibited good performance. Sample 977 the highest performance, comparison original (sample 810) demonstrated significant improvements critical areas, emphasizing efficacy refined composition. The study identified directly addresses received team’s surrogate. underscores delicate balance between biofidelity practicality simulation. need ongoing refinement evident optimize training experiences learners.

Язык: Английский

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The Role of Cartilage Tissue Engineering in Osteoarthritis Treatment: The Bench to Bedside Translation

Journal of Polymer Science, Год журнала: 2024, Номер unknown

Опубликована: Окт. 31, 2024

ABSTRACT Cartilage tissue engineering holds huge promise for joint defects and osteoarthritis (OA) conditions which otherwise have limited treatment options due to cartilage's inherent inability self‐repair. Chemical cues play a pivotal role in regulating chondrocyte behavior matrix synthesis. Strategies utilizing growth factors, small molecules, biomaterial‐based delivery systems aim modulate chondrogenic differentiation, proliferation, deposition, while recent insights emphasize the significance of mimicking native gradients optimal regeneration outcomes. Mechanical stimuli profoundly influence phenotype function, necessitating precise control mechanical microenvironment strategies. Advances biomaterial design, scaffold fabrication, bioreactor facilitate tailored modulation cues, including substrate stiffness, topography, dynamic loading regimes. This review showcases latest advancements both chemical enhance regeneration. Furthermore, exploring synergistic effects combining underscores importance multifaceted approaches promoting robust The also addresses challenges future directions field, such as achieving spatially organized architecture integrating patient‐specific propel cartilage engineering. We conducted comprehensive enlistment clinical trials engineering‐based marketed products OA therapy.

Язык: Английский

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On-demand beamforming and wide dynamic power range for WPT and EH applications

International Journal of Microwave and Wireless Technologies, Год журнала: 2024, Номер 16(6), С. 903 - 918

Опубликована: Июль 1, 2024

Abstract This work delves into advancements in wireless power transfer (WPT) and radiofrequency (RF) energy harvesting (EH), focusing on on-demand beamforming wide-dynamic range technologies. These innovations promise significant improvements efficiency adaptability for systems. For transmitting RF power, enhances delivery precision by accurately targeting specific devices, minimizing waste, maximizing received power. technology is particularly useful dynamic environments with constantly changing device positions, ensuring stable levels effective real-time transfer, such as mobile charging. receiving implementation allows EH WPT systems to adjust output across a broad spectrum, optimizing use extending lifespan. capability supports scalability, accommodating devices varied needs, also enabling new applications consumer electronics, healthcare, smart homes, cities, enhancing management infrastructures. Additionally, this study explores three-dimensional (3D)-printable antennas circuitries battery-free applications. The versatility of 3D printing the creation complex, efficient, customizable components, fostering innovative solutions. Integrating technologies improved efficiencies, reduced losses, sustainable, cost-effective

Язык: Английский

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