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Waste recycling in the healthcare sector - 30/01/2024
Quality and safety of medical care are top priorities in the healthcare sector. However, this is often at the expense of climate protection, as not only are energy and raw material consumption very high, but so is the amount of waste generated due to the large number of disposable products. Sustainable product design and improved recycling strategies are therefore required to reduce waste and the CO2 footprint.
https://www.gesundheitsindustrie-bw.de/en/article/news/sustainability-medical-technology-particular-challenge
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Alternative construction materials: mycelium-based materials - 20/12/2023
Most of us see fungi as just food - and possibly pathogens. This is a mistake, because these amazing organisms are capable of much more: they grow on plant residues of all kinds, forming a dense and interconnected structure as they spread. The resulting material can be moulded into desired shapes and be turned into new sustainable and economically attractive products such as leather and polystyrene substitutes or building materials.
https://www.biooekonomie-bw.de/en/articles/news/using-fungi-create-sustainable-and-economical-mycelium-based-materials
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Sustainable binder alternative - 18/12/2023
Plastic is all around us; and unfortunately, it is not going away any time soon. The search for more sustainable solutions is fully underway. However, binders that degrade only with difficulty or not at all are still used to bond natural materials such as wood and straw - not yet truly environmentally friendly. Fraunhofer researchers are working on an insect-inspired wood binder that makes bonded wood products both resistant and biodegradable.
https://www.biooekonomie-bw.de/en/articles/news/copied-insects-new-biological-wood-binder-under-development
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All-enzyme hydrogels in action - 13/12/2023
Conventional chemical synthesis processes consume large amounts of energy and environmentally harmful solvents. Prof. Dr. Christof Niemeyer’s team at the Karlsruhe Institute of Technology has generated porous, solid foams from crosslinked enzymes that allow the production of high-quality compounds under significantly more environmentally friendly conditions. The novel biocatalysts are also extremely resistant and have a long shelf life.
https://www.gesundheitsindustrie-bw.de/en/article/news/biocatalytic-foams-enable-sustainable-synthesis-complex-molecules
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The AlbLavendel project - 20/11/2023
Blue-violet, fragrant fields like those in Provence may soon become a common sight in the Swabian Alb. As part of the AlbLavendel project, the University of Hohenheim along with the company naturamus GmbH and the German Institutes of Textile and Fibre Research Denkendorf has started to investigate the cultivation of lavender, the production of essential oils and the use of distillation residues for producing textile fibres in the local region.
https://www.biooekonomie-bw.de/en/articles/news/swabian-lavender-cultivation-aesthetic-and-sustainable
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Press release - 15/11/2023
Pancreatic cancer is one of the deadliest types of cancers in humans. Chemotherapies attack not only the tumor cells but also healthy cells throughout the body. Innovative nanoparticles could be a new approach to treat cancer more precisely. The approach was developed by a research team from the Max Planck Institute (MPI) for Multidisciplinary Sciences, the University Medical Center Göttingen (UMG), and the Karlsruhe Institute of Technology.
https://www.gesundheitsindustrie-bw.de/en/article/press-release/nanopartikel-fuer-optimierte-krebstherapie
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Wasser 3.0: #detect|remove|reuse - 31/10/2023
We all pollute our water with things we use in our everyday lives. In the process, microplastics and micropollutants accumulate in sometimes significant quantities and are difficult to remove. This has increasingly devastating consequences for our health and the environment. Wasser 3.0, a non-profit start-up from Karlsruhe, has declared war on this problem by developing a customisable process to detect, remove and even recycle these pollutants.
https://www.biooekonomie-bw.de/en/articles/news/how-sustainably-remove-and-recycle-microplastics-water
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Press release - 30/10/2023
An interdisciplinary research group combining mechanical engineering and biotechnology has taken up its work at the Institute for Molecular Systems Engineering and Advanced Materials (IMSEAM) of Heidelberg University. The team under the direction of Dr Kai Melde will pursue an innovative approach to biofabrication – 3D cell culture using ultrasound. Tools are being developed that can be used as an alternative to or enhancement for 3D printing.
https://www.gesundheitsindustrie-bw.de/en/article/press-release/neue-forschungsgruppe-konstruktion-von-gewebe-im-labor
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Microorganisms degrade biobased turf infill - 17/10/2023
There are thousands of artificial turf pitches in Germany. They are extremely practical, but often not at all environmentally friendly. When it rains or the pitch is used, plastic particles from the rubber granules can be released into the envronment, where they remain. Researchers at the University of Stuttgart along with the company TECNARO are now developing an artificial turf with an infill that biodegrades as soon as it leaves the pitch.
https://www.biooekonomie-bw.de/en/articles/news/eco-friendly-artificial-turf-sports-pitch-s-good-people-and-environment
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Preventing waste from instant meals - 05/10/2023
Many instant meals such as ramen soups have both a protective outer packaging and individual ingredients in small plastic sachets. To prevent this environmentally harmful waste, five students at the University of Hohenheim have developed a sustainable film based on eggshells and plant proteins that dissolves in hot water and is edible.
https://www.biooekonomie-bw.de/en/articles/news/edggy-edible-packaging-film-made-eggshell-waste
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DNA nanotechnology - 25/08/2023
The physicists Prof. Dr. Kerstin Göpfrich and Prof. Dr. Laura Na Liu want to understand life from the bottom up. They intend to do this by constructing an artificial cell. However, rather than natural protein building blocks, they are using 3D-DNA structures as construction material. The first step involved creating an artificial cell skeleton that dynamically assembles and disassembles like the biological model and can transport vesicles.
https://www.gesundheitsindustrie-bw.de/en/article/news/artificial-cytoskeleton-made-dna-synthetic-cells
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