20.09.2024
Rice University bioengineers have harnessed the lotus leaf's unique properties to create a cutting-edge platform for culturing cancer cell clusters. This system offers a new approach to studying tumor progression and metastasis, providing essential insights into cancer biology and treatment.19.09.2024
A team of researchers at the University of Rochester has developed a new approach using ultrasound technology to promote the growth of blood vessels in damaged tissue. The method could have significant applications in reconstructive and plastic surgeries, as well as wound healing.20.08.2024
As the medical field seeks more ethical and accurate alternatives to traditional drug testing, vessel-chip technology is a prospective solution. This technology promises greater accuracy and a reduced need for animal trials.02.07.2024
A team of researchers from the Keck School of Medicine of USC and the California Institute of Technology (Caltech) is developing advanced electronic bandages and other tools to improve the monitoring and healing of chronic wounds. These wearable bioelectronic systems, tested in animal models, have the potential to enhance wound care through controlled drug release and electrical stimulation.06.06.2024
Penn State researchers have developed an adhesive sensing device that seamlessly attaches to human skin to detect and monitor health. The writable sensors can be removed with tape, allowing new sensors to be patterned onto the device.21.05.2024
NYU Langone Health has achieved a medical milestone with the first-ever combined mechanical heart pump and gene-edited pig kidney transplant surgery.14.05.2024
Professor Andreas Herrmann, a leading researcher at the DWI - Leibniz Institute for Interactive Materials, has been granted an ERC Advanced Grant totaling €2.5 million by the European Research Council (ERC). This funding will support his research into the use of biocompatible ultrasound for medical applications over the next five years.13.05.2024
A recent study highlights the safety and effectiveness of PeriCord bioimplants, derived from umbilical cord stem cells, for regenerating heart tissue post-myocardial infarction.10.05.2024
Research from Monash and Osaka Universities highlights the key role sensory neurons play in tissue repair and regeneration, marking a significant advancement for regenerative medicine.30.04.2024
A team of engineers, led by the University of Massachusetts Amherst, has developed a cutting-edge bioelectronic mesh system integrated with graphene sensors to monitor both mechanical movement and electrical signals in lab-grown human cardiac tissue.22.04.2024
New developments at the Fraunhofer Institute for Material and Beam Technology IWS and partners enable improved research possibilities for cancer therapy using microphysiological systems.15.04.2024
A breakthrough in reconstructive surgery may be on the horizon, as researchers develop a 3D-printed skin that integrates hair follicle precursors, leveraging adipose tissue for more natural results.05.04.2024
At the University Hospital Wuerzburg, a promising new treatment for knee joint defects involves the use of nasal cartilage, and it's edging closer to approval with significant EU funding. The new method is using autologous cartilage from the nasal septum, an approach that may seem as enchanting as the term "ENCANTO" implies.11.03.2024
The University of Granada (UGR) has pioneered a solution for burn treatment with its artificial skin “UGRSKIN”. Developed by the Tissue Engineering Research Group, this advanced therapy medicinal product (ATMP) has improved the approach to treating severe burns, offering patients new hope and enhanced outcomes.26.02.2024
POSTECH researchers led by Prof. Hyung Joon Cha, alongside colleagues, introduced groundbreaking personalized underwater bio-adhesive patches (CUBAP) derived from mussel adhesive proteins. This discovery, featured in Advanced Materials, improves biomedical adhesives, offering tailored internal healing solutions.19.02.2024
Advancements in 3D printing technology are improving tissue engineering, offering promising prospects for the artificial production of biological tissues. Researchers at the University of Bayreuth have developed a changing technique that combines hydrogels and fibers, opening new avenues for tissue fabrication.07.02.2024
Metabolic dysfunction-associated steatohepatitis (MASH), previously known as nonalcoholic steatohepatitis (NASH), is a liver disease characterized by inflammation and scarring, reaching epidemic proportions with an estimated 1.5 percent to 6.5 percent of U.S. adults affected.24.01.2024
Empa researchers have pioneered a novel soldering process that employs nanoparticles and lasers to gently fuse tissue, ushering in a new era in wound closure.07.12.2023
A new method for examining tissue samples could change the way we diagnose and treat cancer. Researchers at the Max Planck and Fraunhofer IPA have developed an automated system based on the principle of enzyme-free tissue processing and the mechanical deformability of individual cells.15.09.2023
The European Research Council (ERC) has announced the recipients of its prestigious Starting Grants. Among them is a researcher from the Technical University of Braunschweig: Dr. Thomas Winkler will receive €1.5 million for his research on modular organ-on-chip technology to better understand neuropsychiatric disorders such as schizophrenia.23.08.2023
A new method allows large quantities of muscle stem cells to be safely obtained in cell culture.22.08.2023
The team of Dr. Elisha Krieg at the Leibniz Institute of Polymer Research Dresden has developed a dynamic DNA-crosslinked matrix (DyNAtrix) by combining classical synthetic polymers with programmable DNA crosslinkers.09.08.2023
PeptiMatrix is the latest spin-out company from the University of Nottingham, providing access to an innovative 3D cell culture platform that aims to replace the use of animals in research.28.07.2023
Developing technology to quickly and efficiently bioprint human tissues at scale is the goal of a new project led by Penn State researchers. When fully developed, the technology will be the first to enable the fabrication of scalable, native tissues such as bones, tracheas and organs.20.07.2023
Dr. Jasmina Gačanin, postdoctoral researcher at the Max Planck Institute for Polymer Research in the department of Prof. Dr. Tanja Weil, has been appointed as a “Peretti-Schmucker Fellow”.27.06.2023
Knee osteoarthritis is a widespread form of arthrosis that limits those affected in their everyday lives. The wear and tear in the cartilage tissue often causes pain and movement restrictions. In order to improve treatment, researchers have developed a process that allows artificial cartilage tissue to be individually tailored to sufferers.21.06.2023
Two new assistant professors at the University of Bonn are setting out to develop “mini-organs” in order to study metabolic and disease mechanisms.02.06.2023
Using a newly developed method for the efficient and cost-effective production of biocompatible microfibres, the production of autologous skin and organs can be significantly accelerated. Responsible for the development are Carole Planchette and her team from TU Graz.24.05.2023
Researchers in the UNC School of Medicine's Department of Microbiology and Immunology and the UNC-NC State Joint Department of Biomedical Engineering have developed a new strategy to improve drug-delivery into chronic wounds infections.19.05.2023
Wavy wounds heal faster than straight wounds because shapes influence cell movements, a team of researchers at Nanyang Technological University, Singapore (NTU Singapore) has found.17.05.2023
The Wake Forest Institute for Regenerative Medicine (WFIRM) will make history this month when the first bioprinted solid tissue constructs soar to the International Space Station (ISS) on board the next all private astronaut mission by commercial space leader Axiom Space.20.04.2023
Novel microelectrode array system enables long-term cultivation and electrophysiological analyses of brain organoids.19.04.2023
In the process of organoid manufacturing, bioprinting technology not only facilitates the creation and maintenance of complex biological 3D shapes and structures, but also allows for standardization and quality control during production.12.04.2023
In a joint project of the Max Planck Institute for Polymer Research, Mainz, and the Translational Center for Regenerative Therapies at the Fraunhofer Institute for Silicate Research ISC, Würzburg, scientific principles and biomaterials for the standardized production of valid tissue models are to be developed.11.04.2023
The team working with Alessandra Moretti, Professor of Regenerative Medicine in Cardiovascular Disease, has developed a method for making a sort of "mini-heart" using pluripotent stem cells.10.03.2023
Researchers at the Translational Center for Regenerative Therapies TLC-RT of the Fraunhofer Institute for Silicate Research ISC want to work with partners to replace animal testing.03.03.2023
Synthetic hydrogels were shown to provide an effective scaffold for neuronal tissue growth in areas of brain damage, providing a possible approach for brain tissue reconstruction.02.03.2023
The boundaries between biology and technology are becoming blurred. Researchers at Linköping, Lund, and Gothenburg universities in Sweden have successfully grown electrodes in living tissue using the body’s molecules as triggers. The result, published in the journal Science, paves the way for the formation of fully integrated electronic circuits in living organisms.14.02.2023
Molecules from mucus can be used to produce synthetic bone graft material and help with the healing of larger bone loss, a new study found.25.01.2023
Fraunhofer researchers have now developed a new method for the production and clinical application of stem-cell-based retinal implants, which could contribute towards the successful treatment of AMD.01.12.2022
Wound care by nurses is directly about cleaning, sterile covering, and documentation. Medical and surgical interventions may also be necessary. In this context, wound care also offers potential for the use of technical aids that can help prevent complications.01.12.2022
Wounds – both acute and chronic ones – can have many different causes. They all have in common that they require meticulous care because complications in wound healing can severely reduce both the patients’ health and quality of life. But there is more to modern wound care than just cleaning and bandaging them. Nursing staff and physicians can also access technical aids for this work.19.08.2022
Researchers at Karolinska Institutet in Sweden and the Swedish University of Agricultural Sciences have discovered that spider silk proteins can be fused to biologically active proteins and be converted into a gel at body temperature.08.07.2022
Ex vivo studies of human obesity without animal testing? The Adipose-on-Chip system offers a solution that allows scientists to gain better insights into various obesity-linked secondary diseases and comorbidities in the future.08.06.2022
We are nowadays already able to weave implants out of artificial fibers that can replace tissue or heal injuries. Different materials like polymers or nitinol are used to create flexible shapes. But the materials and their uses can still be improved.22.02.2022
3D printing opens a world of endless possibilities – for both industrial and medical applications. A cross-national project recently created tissue that produces insulin, spelling hope for patients with diabetes.27.01.2021
Drug research and artificial skin replacement - these are the areas in which tissue engineering and bioprinting are already used today. What else could be possible in the future? We asked Dr. Nadine Nottrodt from Fraunhofer ILT and Prof. Sabine Neuß-Stein from RWTH Aachen University Hospital!01.12.2020
How do cells react to certain drugs? And how exactly is new tissue created? This can be analyzed by using bioprinting to embed cells in fine frameworks. However, current methods are often imprecise or too slow to process cells before they are damaged. At the TU Vienna, a high-resolution bioprinting process has now been developed using a new bio-ink.01.12.2020
The big hope of bioprinting is to someday be able to print whole human organs. So far, the process has been limited to testing platforms such as organs-on-a-chip. That's because the actual printing process already poses challenges. Scientists need suitable printing materials that ensure the cell's survival as it undergoes the procedure. The Fraunhofer IGB is researching and analyzing this aspect.01.12.2020
It aims at the production of test systems for drug research and gives patients on the waiting lists for donor organs hope: bioprinting. Thereby biologically functional tissues are printed. But how does that actually work? What are the different bioprinting methods? And can entire organs be printed with it? These and other questions are examined in our Topic of the Month.19.03.2020
Regenerative medicine often relies on implants and materials that support healing in our body. Collagen has a special significance here. It is compatible to the body and offers an excellent environment for the growing of new cells. In our video, we took a look on where collagen and collagen products for medicine come from.23.09.2019
For patients waiting for donor organs, every day can mean the difference between life and death. Making things even more complicated is the fact that not every organ is a compatible match with the patient. It would mean enormous progress if we could grow organs from the patient's own cells in the lab. That's why patients with heart disease place big hope in tissue engineering.15.05.2019
New active substances that are suitable for drugs are initially tested in animal experiments. However, the results cannot always be transferred to the human organism. At the Karlsruhe Institute of Technology, Prof. Ute Schepers from vasQlab explains how active substances can be tested in human tissue without endangering human health.