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.

Microrobots have the potential to revolutionize medicine. Researchers at the Max Planck ETH Centre for Learning Systems have now developed an imaging technique that for the first time recognises cell-sized microrobots individually and at high resolution in a living organism. This is an important step towards precise control of the robots and their clinical translation.

Robot arm for greater accuracy - 08/06/2022

guidoo: robotic assistance for fast and precise biopsies

Needle-based procedures through the skin, such as biopsies of internal organs, not only require a great deal of skill and experience, but they also take time. Fraunhofer IPA Mannheim, together with BEC GmbH from Pfullingen, is developing a robotic surgical assistance system that supports the correct positioning and angulation of a needle with the help of a guide sleeve. This significantly speeds up the procedure while maintaining precision.

The family-owned MedTech company KARL STORZ announces the acquisition of the innovative software manufacturer Innersight Labs Ltd. (ISL) headquartered in London. In addition to state-of-the-art endoscopes, high-end medical devices, and integrated solutions for the operating room, KARL STORZ is also continuing to expand in innovative software solutions.

The MedTech company KARL STORZ announces the acquisition of the innovative software manufacturer Innersight Labs Ltd. (ISL) headquartered in London. In addition to state-of-the-art endoscopes, high-end medical devices, and integrated solutions for the operating room, KARL STORZ is also continuing to expand in innovative software solutions. Its large customer base, including top-class physicians worldwide, can now look forward to 3D models.

Scientists at the Max Planck Institute for Intelligent Systems, the University of Tübingen and the University of Stuttgart under the Bionic Intelligence Tübingen Stuttgart (BITS) collaboration developed a biorobotic arm that can mirror human tremors. Artificial muscles on either side of the forearm contract and relax to suppress the involuntary shaking of the wrist and hand.

A research team of scientists from the Fraunhofer IPA, the Bosch Digital Innovation Hub at Bosch Health Campus and the Institute of Image-Guided Surgery (IHU) of Strasbourg has jointly launched the DAIOR project. Within the framework of the project, the project partners are working on realizing the operating room of the future with help of artificial intelligence and robot assisted telemedicine.

Pipetting robot for academic research - 28/08/2024

goodBot GmbH: a third arm for researchers

Repetitive tasks that researchers have to conduct in the lab tend to be tiring and often lead to errors. Precise pipetting is crucial for achieving reproducible results. Automation is underrepresented in research labs and existing pipetting robots are unsuitable for scientists. This is why Dr. Julius Wiener, Tobias Zundel and Oliver Brunner decided to found the company goodBot GmbH and develop a pipetting robot tailored to academic research.

A building with 7400 m² of research space for robotics and artificial intelligence is being built on the Max Planck Campus in Büsnau. Researchers from the Max Planck Institute for Intelligent Systems (MPI-IS) and the University of Stuttgart will be working there with partners from science and industry as well as start-ups from 2027.

The new Center for Bionic Intelligence Tübingen Stuttgart aims to optimize the interaction between humans and technical systems in a fundamentally new way. Scientists from the Universities of Stuttgart and Tübingen, the Max Planck Institute for Intelligent Systems and the Max Planck Institute for Biological Cybernetics are conducting research on intelligent bionic systems that will aid understanding and treatment of certain diseases of the CNS.

Scientists at the Max Planck Institute for Intelligent Systems developed a single-cell green microalgae coated with magnetic material. This miniature robot was put to the test: would the microalgae with its magnetic coating be able to swim through narrow spaces and, additionally, in a viscous fluid that mimics those found in the human body? Would the tiny robot be able to fight its way through these difficult conditions?

Pioneering cutting-edge diagnostic systems for the detection of complex diseases: Cyber Valley is pleased to announce it has awarded funding of 500K EUR to the CELL’n’ROLL team through the 2023 Cyber Valley Innovation Fellowship program, funded by the Carl-Zeiss-Stiftung.

The AutoProNano German/French collaborative project involves developing a process for the automated production of nanoparticles for in vitro and in vivo diagnostics. The project is being launched within the smart analytics cooperation network. This international initiative has been funded by the Central Innovation Programme for SMEs (ZIM) of the German Federal Ministry for Economic Affairs and Climate Action (BMWK) since May 2020.

In the medicine of the future, tiny robots will navigate independently through tissue and medical instruments will indicate their position inside the body during surgery. Both require doctors to be able to localize and control the devices precisely and in real time. Scientists from the German Cancer Research Center (DKFZ) have now described a signaling method based on an oscillating magnet that can significantly improve such medical applications.

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…

At the finale of the Cyber Valley Days, and Science Minister Petra Olschowski opened the ELLIS Institute Tübingen, heralding the next phase of the AI Innovation Campus. With the world's first ELLIS Institute, Cyber Valley is gaining further radiance. Olschowski also announced at the ceremony that the Karlsruhe Institute of Technology (KIT) is joining the Cyber Valley Community.

Robotics in medicine - 15/02/2024

Copied from the pangolin: innovative flexible miniature robot for minimally invasive applications

Wireless miniature robots that can penetrate hard-to-reach areas of the body for the purpose of medical treatment are currently still a vision of the future. Researchers at the Max Planck Institute for Intelligent Systems in Stuttgart have now constructed the first flexible prototype modelled on the pangolin, which can generate heat and stop bleeding, kill tumour cells or release "cargo" in the model system.

Dossier - 24/05/2012

Biochips microsystems technology for the life sciences

Nanoscale robots and intelligent measurement systems in arteries, fingernail-sized DNA chips that can be used to analyze thousands of genes in tiny samples, intelligent DNA microsensors – the trend in the life sciences is moving towards miniaturization.

Dossier - 25/03/2013

Biotechnology goes automated

Processes that previously required pipetting analysis and production to be carried out manually are increasingly now controlled by automated systems. However this has not necessarily involved a complete reinvention of the wheel instead automation systems used in the plant construction and mechanical engineering sectors are being adapted and optimised for application in the life sciences.

5G-OR is one of the 4 winning projects jointly selected by the Federal Ministry of Economics and Climate Action in Germany and the Ministry of Economy, Finance and Relaunch in France for the call “Technical developments and application ecosystems for 5G private networks”. The joint Franco-German 5G-OR project takes up the challenge in the healthcare domain.

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.

A quantum sensor that can register nerve impulses without contact opens up new possibilities in prosthetics. Researchers at Fraunhofer IPA are developing together with the industrial partner Q.ANT the prototype of one Prosthetic arm that is controlled by neural commands like healthy limbs.

Innovations in the field of endoscopy - 08/06/2020

Gastroscopies with pill cameras

A pill camera to examine the gastrointestinal tract that can be swallowed without major difficulty, controlled intuitively from the outside and deliver images in real time - why would any doctor or patient say no? To non-experts, it sounds more like science fiction but such a device is actually already in development: since 2019, Tübingen-based Ovesco Endoscopy AG and three partners have been working together on this in a project called nuEndo.

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.

Article - 21/02/2019

Using neuromedical artificial intelligence responsibly

Brain-computer interfaces are the latest developments in the neurotechnology field. They are used to record brain activity, which is then decoded with artificial intelligence techniques and converted into control signals for robots or computers. While this brings hope to severely paralysed people, it also implies risks due to the interest of companies like Google and Facebook in this type of data.