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Thrilled to share the latest publication by DTU - Technical University of Denmark, Shiraz University of Medical Sciences, UMC Utrecht and Eindhoven University of Technology. The multicentric group, led by Professor Alireza Dolatshahi-Pirouz, developed a novel bacteria-derived polysaccharide hydrogel, coined Pantoan Methacrylate, to be used as a smart functional bioink for tissue engineering applications. The novel ink was proven to be suitable for 3D bioprinting applications and successfully processed using a REGENHU platform for muscle tissue engineering applications, targeting Volumetric Muscle Loss (VML) injury treatment. The research study highlighted the biomimetic properties of the novel biomaterial formulation, and its capability to guide muscle progenitor cells into fused, aligned tubes, facilitating their transition into functional muscle tissue. As stated by the authors this novel, sustainable, and cost-effective material may hold great promises for more efficient therapeutic treatments for VML as well as the fabrication of in-vitro models for drug screening and disease modeling applications   Interested in more details? Reference article: https://lnkd.in/dywpMkeC REGENHU bioprinting solutions: www.regenhu.com #3DBioprinting #Bioprinting #Bioinks #VolumetricMuscleLoss #TissueEngineering #SustainableBioinks #SmartBioinks #Bacteria #Pantoan

Tissue engineering is emerging as a significant potential alternative or complementary solution, whereby tissue and organ failure is addressed by implanting natural, synthetic, or semisynthetic tissue and organ mimics that are fully functional from the start, or that grow into the required functionality. Initial efforts have focused on skin equivalents for treating burns, but an increasing number of tissue types are now being engineered, as well as biomaterials and scaffolds used as delivery systems. Visit us for more information : https://lnkd.in/gHHWFg4m Submissions are Open in the broad scope of the Journal of Regenerative Biology and Medicine [ISSN: 2582-385X]. Authors can directly submit their manuscripts to [email protected] Source: Internet. #tissues #regeneration #research #tissueengineering

📢 A new Special Issue "Fabrication of Biomaterials to Develop Tissue Engineering Scaffolds and Medical Devices" is now open for submissions! 🥼 This Special Issue is guest edited by Dr. Iruthaya Pandi Selestin Raja, from Pusan National University, Republic of Korea. 💡 This Special Issue aims to provide readers with an innovative platform to better understand the most recent research developments and challenges in preparing inspiring biomaterials for diverse biomaterial scaffolds and medical devices within the biomedical sector. 🔗 Click the link to access more details about the Special Issue: https://lnkd.in/gkmGyPKk. 🕑 Deadline for manuscript submissions is 31 October 2024. 🎉 Welcome to join us as authors and reviewers! 👏 And welcome to follow our LinkedIn account: https://lnkd.in/grPNkBrg. #tissue_engineering #biocompatible #polymers #nanomaterials #biofabrication #bioprinting #photobiomodulation #medical_devices #cell_biomaterial_interaction

In this article we delve into the world of biomaterials and their transformative impact on healthcare. https://bit.ly/3P6MtoX Join us to uncover the potential of bioactive scaffolds, bioresorbable implants, injectable hydrogels, organs-on-a-chip, and self-healing biomaterials in revolutionizing life sciences research. We're advancing biomedical innovation through curiosity and shared knowledge. Be curious.

In this article we delve into the world of biomaterials and their transformative impact on healthcare. https://bit.ly/45GNxae Join us to uncover the potential of bioactive scaffolds, bioresorbable implants, injectable hydrogels, organs-on-a-chip, and self-healing biomaterials in revolutionizing life sciences research. We're advancing biomedical innovation through curiosity and shared knowledge. Be curious.

Check out our new manuscript! Excited to contribute to the 'Hydrogels in the Clinic' series in Bioengineering & Translational Medicine journal with with Samir Mitragotri, John Clegg, and Zongmin Zhao. We cover the impact of injectable and non-injectable hydrogels and highlight opportunities for future impact. We hope that consolidating this information will advance the clinical translation of new technologies to improve human health. https://lnkd.in/eQR_x4EN

Title: Polycaprolactone/graphene oxide/acellular matrix nanofibrous scaffolds with antioxidant and promyelinating features for the treatment of peripheral demyelinating diseases. Author: Dr. Goutam Thakur Department Name: Biomedical Engineering Journal Name: J MATER SCI-MATER M Published –October 2023, Publication: International Congratulations to Dr. Goutam Thakur from the Department of Biomedical Engineering on the remarkable publication of your article, "Polycaprolactone/Graphene Oxide/Acellular Matrix Nanofibrous Scaffolds with Antioxidant and Promyelinating Features for the Treatment of Peripheral Demyelinating Diseases," in J MATER SCI-MATER M (October 2023 issue). It showcases your groundbreaking work at biomedical engineering and the intersection of materials science. The development of nanofibrous scaffolds with specific features for treating demyelinating diseases marks significant progress in regenerative medicine. Well done. #Research #BiomedicalEngineering #MaterialsScience #RegenerativeMedicine #ScientificInnovation. DOI: https://lnkd.in/gnJhP4Xv -Cdr.Dr.Anil Rana, Director-MIT Manipal

🔬 Are you interested in the latest advances in biomedical research? Look no further than the #BIOMET4D project! 👨🔬 In this video, get to know BIOMET4D researcher, Blanca Limones Ahijón Limones from IMDEA Materials Institute. 🏥 BIOMET4D aims to create a new generation of biodegradable implants capable of shape change and load-bearing for dynamic tissue restoration to provide improved health outcomes in the treatment of craniosynostosis and skin expansion procedures. The consortium members include IMDEA Materials, Uniklinik Köln, the University of Galway, Aerosint , Meotec GmbH, the Universidad Politécnica de Madrid and the Instituto de Investigación Sanitaria Gregorio Marañón. Find out more about this project, here: https://lnkd.in/d9AUgPbQ Blanca shares with us her role in the BIOMET4D project team, which involves conducting experiments into seeding cells directly onto the materials being developed for the next generation of shape morphing implants. The project has received funding from the EIC Pathfinder under grant agreement No 101047008. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Innovation Council and SMEs Executive Agency (EISMEA). Neither the European Union nor EISMEA can be held responsible for them. Jennifer Patterson, Ted Vaughan, Alexander Kopp, Sergio Peña Camacho, Santiago Ochandiano, Manuel Desco, European Commission.

🩸 Curious to see how inert designer hydrogels can be fine-tuned to provide the native cells' 3D microenvironment? 🚀 The cutting-edge research in biomaterials is revolutionizing the way we understand and replicate cellular environments. This latest study dives deep into the intricate world of designer hydrogels, showing how these seemingly inert materials can be meticulously engineered to mimic the complex 3D microenvironments that cells naturally inhabit. 🎯 Why is this important? Hydrogels have immense potential in tissue engineering, regenerative medicine, and drug delivery. By fine-tuning their properties, we can create more accurate and functional models for research and therapeutic applications. 📈 What will you learn? The latest advancements in hydrogel design Techniques for tailoring hydrogels to specific cellular needs Real-world applications and future prospects in biomedical science This paper is a must-read for anyone passionate about biomaterials, tissue engineering, and the future of medical science. Dive into the research and discover how we're pushing the boundaries of what's possible. 📄 Read the full paper here: https://lnkd.in/dntbiswB 💡 Join the conversation and share your thoughts on the future of hydrogels in biomedical applications! Let's innovate together. #Biomaterials #TissueEngineering #Hydrogels #BiomedicalResearch #Innovation #MYLeukaemia