Nanoscribe’s Post

🌵 Call for papers: 3D Bioprinting Tissue construction in the laboratory entailed laborious, intricate, and technically challenging processes, while the arising 3D bioprinting technology has revolutionized tissue engineering by enabling the assembly of cells, proteins, and hydrogels into living structures with 3D printers, scaling up the production and streamlining the process, as well as enhancing precision and ensuring reproducibility within defined tissue production. This collection seeks original research across diverse facets of 3D bioprinting in a broader scope, encompassing #bioprinting technique (#photoetching, deposition, and novel printer designs), evolving #biomaterial or #bioinks, demonstrable applications, pivotal analytical tools for elucidating the process, as well as the broadly defined biological and clinical applications of 3D printing. We also embraces broad applications of #biofabrication. Submit here, https://lnkd.in/e6nmn55D

Reminder: Join My Upcoming Talk This Friday about: Lattice Metamaterials Generation for Bone and Tendon Regeneration

🔬 𝗦𝘁𝗿𝗲𝗮𝗺𝗹𝗶𝗻𝗲 𝘆𝗼𝘂𝗿 𝗯𝗶𝗼𝗽𝗿𝗶𝗻𝘁𝗶𝗻𝗴 𝘄𝗶𝘁𝗵 𝗼𝘂𝗿 𝗕𝗶𝗼𝗽𝗿𝗶𝗻𝘁𝗶𝗻𝗴 𝗠𝗼𝗱𝗲𝗹 𝗟𝗶𝗯𝗿𝗮𝗿𝘆! 🔬 We are excited to introduce the Bioprinting Model Library, meticulously crafted by CELLINK and Nanoscribe for the Quantum X bio, offering the highest resolution #3DBioprinting available. Our library includes over 30 models optimized for various applications such as: 🔬 3D cell culture 💉 drug delivery 🧬 live-cell printing 🩸 vasculature fabrication 🌱 cell seeding 🧱 3D cell scaffolds This extensive selection simplifies the printing process for all users in the #LifeSciences. With ready-to-use models, researchers can focus on their core work without the initial hassle of designing their models. No more design headaches – just choose the model that suits your needs and start printing! Learn more about state-of-the-art bioprinting today and take your #research to the next level with ease 👉 https://lnkd.in/eZZh9Uta #QuantumXbio #BiomedicalResearch #ResearchMadeEasy

PART 1 Bioprinting: Transforming Modern Medicine Explore the future of healthcare with bioprinting! 🌟 This groundbreaking technology is transforming the medical field, allowing for the 3D printing of organs like kidneys and hearts. Imagine ordering a new organ with a few clicks on your healthcare portal. Let's delve into the intricacies of bioprinting and its impact on modern medicine. #Bioprinting #HealthcareInnovation #FutureOfMedicine #3DPrinting #MedicalAdvancements

Cyberbone #biomaterials #porous #implants 13 years ago Marcin Wątrobiński co-conducted clinical trials in Krakow and Bierun (Prof. Ficek) on 18 patients using microporous polylactide copolymer sponges Corbion Biomaterials. Excellent results. We now want to return to this technology. It does not give shape and more strength, but 50% microporosity is an optimal feature. Not possible to get in 3D printing from this copolymer.

📖 “Development and Prospective Applications of #3DMembranes as a #Sensor for Monitoring and Inducing #TissueRegeneration” by Pengxiang Zhao from 北京工业大学, et al. Read Paper 👉 https://lnkd.in/die4Vkfx Here, we provide an overview of the advantages of 3D printing and conventional therapies in tissue engineering. We also shed light on different types of 3D printing technology, biomaterials, and sensors to describe effective methods for use in skin and other tissue regeneration, highlighting their strengths and limitations. Finally, we highlight the value of 3D bioengineered membranes in various fields, including the modeling of disease, organ-on-a-chip, and drug development. #Biomaterials #ArtificialMembraneApplication

🌟 Breakthrough in Polymer Science: Advanced 3D Printing for Biomedical Applications! 🧬🔬 A groundbreaking development in polymer science is set to revolutionize medical implants! A new 3D printing method creates polymers that are both strong and highly elastic, perfect for applications like heart repairs, joint support, and even needle-free sutures. Inspired by the intricate structures of worms, this innovation leads to materials that conform to wet tissues and withstand dynamic forces. Plus, it's environmentally friendly, reducing the energy needed for curing. Discover more about this exciting advancement in Science https://lnkd.in/g4TjUkKT. For insights on cutting-edge research and to connect with experts, don’t miss our upcoming conference—find out more https://lnkd.in/gc-5nPWh. #PolymerScience #3DPrinting #Biomaterials #Innovation #Healthcare #MaterialScience

Revolutionizing 3D Printing with Light-Driven Chirality! Exciting news from Dr. Ji-Young Kim who’s research was published on a groundbreaking new method for 3D printing chiral plasmonic nanostructures using circularly polarized light. This innovative technique allows us to create complex 3D patterns with unique optical properties on a variety of substrates, including flexible materials. Imagine the possibilities: ·        Rapid prototyping of chiral metamaterials for advanced optical devices. ·        On-the-fly modulation of chirality for customizable functionalities. ·        Scalable production of chiroplasmonic surfaces for biosensing and optoelectronics. Read the full paper here: [https://lnkd.in/e92K3iMT] The Nanoscale-Engineering in Resonance and Dissymmetry (NeRDy)Lab at RPI's Center for Biotechnology & Interdisciplinary Studies is seeking talented researchers to join our team!  Ready to embrace your inner NeRD and make groundbreaking discoveries? Learn more and apply: [https://lnkd.in/eQVuvZYB] #Nanomaterials #Metamaterials #Chirality #Optics #PhD #RPINeRDyLab #3DPrinting #Nanotechnology #ChiralPlasmonics #Metamaterials #RPINeRDyLab #RPI #RPI_CBIS

3D printing of artificial heart valves holds immense potential to revolutionize cardiovascular treatments by offering customized, cost-effective, and efficient solutions. Companies like Edwards Lifesciences and researchers at ETH Zurich are already pioneering advancements in this space. The future of additive manufacturing in medical devices will include bioprinting, regenerative tissues, and on-demand production, fundamentally transforming how life-saving devices are produced and delivered globally. #3DPrinting #MedicalInnovation #AdditiveManufacturing #HealthcareTech #Bioprinting

#Microfluidics allows for the precise manipulation of fluids on a sub-millimeter scale, facilitating the creation of compact, efficient, and cost-effective devices for various biological and chemical applications, thanks to the benefits of miniaturization.   This fascinating study tackles a major challenge in the field: how to produce microfluidic devices in a cost-effective and efficient manner. The research, conducted by Professor Tony Jun Huang's group at Duke University, overcomes this hurdle by utilizing 3D printing to create a surface acoustic wave (SAW)-based microfluidic device. These devices were characterized at several megahertz frequencies using the Polytec VibroFlex-Compact https://lnkd.in/gt3PiyE Citation: https://lnkd.in/gESK_KnB Researchers: Joseph Rich, Brian Cole, Teng Li, Brandon Lu, Hanyu Fu, Brittany Smith, Jianping Xia, Shujie Yang, Ruoyu Zhong, James L. Doherty, Kanji Kaneko, Hiroaki Suzuki, Zhenhua Tian, Aaron Franklin #Vibrometry #VibrationMeasurement #3DPrinting #LabOnAChip #SAWTechnology