Vital3D Technologies’ Post

🔎 Novel Medial Research 🔍 Researchers have developed a resilient, flexible, material that can act as an adhesive for healing soft tissue and cartilage. With the next step of understanding biocompatible interactions, this technology could be an innovative step in clinical options of helping patients. What do you think of the potential applications of this technology? #medicalresearch #medicaldevices #3dprinting

The Assembly line of #3DPrinted Tissues: Considerations for Automating #TissueFabrication #Biofabrication #3DTissue #tissueengineering https://bit.ly/3nLQQZ5

The Assembly line of #3DPrinted Tissues: Considerations for Automating #TissueFabrication #Biofabrication #3DTissue #tissueengineering https://lnkd.in/df3W7H3M

The Assembly line of #3DPrinted Tissues: Considerations for Automating #TissueFabrication #Biofabrication #3DTissue #tissueengineering https://lnkd.in/df3W7H3M

Dear All, Please find our latest  published work: "Fabrication of 3D chitosan/polyvinyl alcohol/brushite nanofibrous scaffold for bone tissue engineering by electrospinning using a novel falling film collector"

At ELK3D, we find the breakthrough in using two-photon polymerization for creating 3D human tissue models both fascinating and crucial for advancing #biomedicalresearch. Two-photon polymerization enables fabrication of intricate 3D structures mimicking human tissue at cellular scale, precise to <1 micrometer. Utilizing gelatin methacryloyl for muscle-like consistency and OrmoComp for structural integrity, this method supports cell growth and simulates tissue deformation. Breakthrough offers enhanced accuracy in cellular research, promising insights into aging, disease, and organ function. Future work aims to replicate dynamic tissues and improve biological study statistics with complex organ-mimicking structures. #TwoPhotonPolymerization #3DPrinting #TissueEngineering #CellularResearch #BiomedicalInnovation #Aging #DiseaseResearch #OrganSimulation #ELK3D https://lnkd.in/eby6VFNu

PUBLICATION ALERT 📣 Excited to share my first review article titled "Magnetic Alignment of Collagen: Principles, Methods, Applications, and Fiber Alignment Analyses" published in Tissue Engineering Part B: Reviews. Read it, cite it, share it: https://lnkd.in/eZGhJg93 The review delves into various collagen alignment techniques, with a special focus on magnetic alignment, exploring its working principles, advantages, and limitations, and fiber alignment analyses techniques. A key takeaway is the renewed interest in using magnetic particles and low-level magnetic fields over the last decade, and I am currently working on optimizing this technique in a 4D printing setup towards my dissertation project. As always, I am grateful to my advisor, Vipuil Kishore, for the opportunity to contribute to field via this review and to learn more! 📚🔬 #biomedicalengineering #tissueengineering #collagenalignment #researchpublication #magenticalignment

Bioprinting: The Future of Medicine is Here! #Bioprinting #HealthcareInnovation Imagine 3D printed organs and personalized tissues for transplants and regeneration. Bioprinting is making this a reality! This article dives deep into the fascinating world of bioprinting, exploring its potential to revolutionize medicine. We explore: * The science behind bioprinting and its recent advancements * How bioprinting could address organ shortages and tissue damage * The possibilities for personalized medicine using bioprinted tissues Join us in exploring the future of healthcare: https://lnkd.in/gYCfb_f8 #3DPrinting #TissueEngineering #PersonalizedMedicine #MedicalBreakthrough #MedTech #FutureofHealth

🦴 Unlocking new possibilities for treating osteoporosis and enhancing quality of life with additive manufacturing. A collaborative effort between scientists from Tomsk State University and Sharif University of Technology enables personalised implants and targeted drug delivery systems. With patients receiving tailored care that addresses their specific needs, the new treatment for osteoporosis will effectively restore bone tissue. 🔗 Dive into the article for all the details below. #3dprinting #personalisedmedicine #additivemanufacturing #medical #regenerativemedicine

Great to see Mateo Dallos Ortega's first paper published from his PhD work in Royal Society of Chemistry journal Materials Advances. In this paper, we report on the development of gelatin biomaterial inks loaded with the antimicrobial peptide, nisin, for extrusion-based 3D printing to produce scaffolds with controlled porosity, high shape fidelity, and structural stability. The 3D printed scaffolds fabricated from the gelatin/nisin inks demonstrated excellent antimicrobial efficacy (complete kill) against Gram positive bacteria methicillin-resistant Staphylococcus aureus (MRSA). Overall, this ink's has the potential to fabricate customisable regenerative medicine implants that can effectively combat infection without contributing to the development of multidrug resistant bacteria. https://lnkd.in/evhFEc-p