Printing a new cornea during an operation to restore a patient’s eyesight: This groundbreaking step in the fight against corneal disorders is set to become reality with a laser based process using personalized bioink. The method was developed by researchers at the Karlsruhe Institute of Technology (KIT) in collaboration with Carl Zeiss Meditec AG and Evonik Healthcare. Their project won the idea award in this year’s NEULAND innovation contest.

Collagen has been used in ophthalmology since the 1990s, particularly in the treatment of corneal defects. However, why and how this technique works was only known in theory. Researchers at the NMI Natural and Medical Sciences Institute in Reutlingen led by Lu Fan have found the necessary evidence and can now reliably explain how this technique works.

Waste recycling in the healthcare sector - 30/01/2024

Sustainability in medical technology: a particular challenge

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.

All-enzyme hydrogels in action - 13/12/2023

Biocatalytic foams enable the sustainable synthesis of complex molecules

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.

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.

Wearable medical devices, such as soft exoskeletons that provide support for stroke patients or controlled drug delivery patches, have to be made of materials that can adapt intelligently and autonomously to the wearer's movements and to changing environmental conditions. These are the type of autonomously switchable polymer materials that have recently been developed by researchers at the University of Stuttgart and the University of…

Scientists at the Max Planck Institute for Intelligent Systems in Stuttgart have developed a magnetically controlled soft medical robot with a unique, flexible structure inspired by the body of a pangolin. The robot is freely movable despite built-in hard metal components. Thus, depending on the magnetic field, it can adapt its shape to be able to move and can emit heat when needed.

"Programmable" polymer materials - 24/04/2023

Medicine of the future: intelligent 4D polymers from the printer

It is impossible to imagine medicine without 3D printing, which can be used to make implants or for culturing cells and tissues. It is now possible for 3D objects to be given an added dimension, namely an ability to make simple autonomous movements, by changing their size. Researchers at Heidelberg University have been able to produce microscopically small 4D structures from intelligent polymers that can be tailored to individual requirements.

Heidelberg University is to acquire a research building to develop innovative engineering science strategies and technologies on the basis of life-inspired molecular systems. The German Science and Humanities Council has now expressed its backing for the idea with an outstanding rating. This recommendation is the crucial precondition for a new building on the university campus Im Neuenheimer Feld.

The Bundesanstalt für Materialforschung und -prüfung (BAM) is developing a more sustainable process to produce active pharmaceutical ingredients in a major EU project: The pilot project is intended to demonstrate the advantages of mechanochemistry for more environmentally friendly and CO2-neutral pharmaceutical production.

Although just cute little creatures at first glance, the microscopic geckos and octopuses fabricated by 3D laser printing in the molecular engineering labs at Heidelberg University could open up new opportunities in fields such as microrobotics or biomedicine. The printed microstructures are made from novel materials – known as smart polymers – whose size and mechanical properties can be tuned on demand and with high precision.

Article - 19/09/2019

Magnetised algae as microrobots for medical and environmental purposes

Algae, for most of us, is something that lives in water courses that we occasionally find unpleasant. However, that is to do them a wrong. These extremely versatile and frugal organisms might in future prove to be extremely important. Scientists at the University of Stuttgart are investigating how algae can be used as microrobots in biomedicine and environmental remediation.

Dossier - 31/03/2014

Peptides diverse molecules of life

Peptides exist in all organisms, wherever there are cells. The range of their physiological functions is huge. Biologically active peptides can act as hormones, neurotransmitters, growth factors as well as toxins and antibiotics. This is what makes them highly interesting drug leads. They are used for the treatment of autoimmune diseases, cancer and other diseases. Peptides are gaining in importance as candidates for drugs.