11.11.2025 – 11:07

Technische Universität München

Nanorobots transform stem cells into bone cells

TECHNICAL UNIVERSITY OF MUNICH

NEWS RELEASE

New method for the targeted production of specific cells

Nanorobots transform stem cells into bone cells

• Mechanical stimulation can transform stem cells into bone cells.
• Researchers have demonstrated that cells can be reliably transformed in a system using nanorobots and laser light.
• In principle this method can also be used to produce heart and cartilage cells.

For the first time, researchers at the Technical University of Munich (TUM) have succeeded in using nanorobots to stimulate stem cells with such precision that they are reliably transformed into bone cells. To achieve this, the robots exert external pressure on specific points in the cell wall. The new method offers opportunities for faster treatments in the future.

Prof. Berna Özkale Edelmann’s nanorobots consist of tiny gold rods and plastic chains. Several million of them are contained in a gel cushion measuring just 60 micrometers, together with a few human stem cells. Powered and controlled by laser light, the robots, which look like tiny balls, mechanically stimulate the cells by exerting pressure. “We heat the gel locally and use our system to precisely determine the forces with which the nanorobots press on the cell – thereby stimulating it,” explains the professor of nano- and microrobotics at TUM. This mechanical stimulation triggers biochemical processes in the cell. Ion channels change their properties, and proteins are activated, including one that is particularly important for bone formation.

Heart and cartilage cells: finding the correct stress pattern

If stimulation is carried out at the right rhythm and with the right (low) force, a stem cell can be reliably triggered to develop into a bone cell within three days. This process can be completed within three weeks. “The corresponding stress pattern can also be found for cartilage and heart cells,” asserts Berna Özkale Edelman. “It’s almost like at the gym: we train the cells for a particular area of application. Now we just have to find out which stress pattern suits each cell type,” says the head of the Microbiotic Bioengineering Lab at TUM.

Mechanical forces pave the way for transformation into bone cells

The research team produces bone cells using mesenchymal stem cells. These cells are considered to be the body’s ‘repair cells’. They are approximately 10 to 20 micrometers in size and are generally capable of developing into bone, cartilage or muscle cells, for example. The challenge: The transformation into differentiated cells is complex and has been difficult to control until now. “We have developed a technology that allows forces to be applied to the cell very precisely in a three-dimensional environment,” says TUM scientist Özkale Edelmann. “This represents an unprecedented advance in the field.” The researchers believe that this method can even be used to produce cartilage and heart cells from human stem cells.

Automation is the next step

For treatments, doctors will ultimately need far more differentiated cells – around one million. “That’s why the next step is to automate our production process so that we can produce more cells more quickly,” says Prof. Özkale Edelmann.

Additional press materials:

Photos: https://mediatum.ub.tum.de/1836403

Further Information:

Researcher Cheng Wang explains how stem cells are transformed into bone cells by impulses from nanorobots: https://www.youtube.com/watch?v=gP8WolgBV54

Researcher Nergishan Iyizan from the Microbiotic Bioengineering Lab at the Technical University of Munich explains how biochemical processes in cells change as a result of mechanical stimulation: https://www.youtube.com/watch?v=pjfSTh-Nxwc

Researcher Chen Weng from the Microbiotic Bioengineering Lab at the Technical University of Munich demonstrates the new system of nanorobots that can transform stem cells into bone cells through stimulation: https://www.youtube.com/watch?v=mNl4Ga5pDkY

Publications

Photothermally Powered 3D Microgels Mechanically Regulate Mesenchymal Stem Cells Under Anisotropic Force; Chen Wang, Nergishan Iyisan, Philipp Harder, Valentin H. K. Fell, Viktorija Kozina, Hendrik Dietz, Olivia M. Merkel, and Berna Özkale; Advanced Materials, 9-2025; https://advanced.onlinelibrary.wiley.com/doi/10.1002/adma.202506769

Hydrostatic Pressure Induces Osteogenic Differentiation of Single Stem Cells in 3D Viscoelastic Microgels; Hydrostatic Pressure Induces Osteogenic Differentiation of Single Stem Cells in 3D Viscoelastic Microgels; Nergishan İyisan, Fernando Rangel, Leonard Funke, Bingqiang Pan, Berna Özkale; https://onlinelibrary.wiley.com/doi/10.1002/smsc.202500287

Subject matter expert:

Prof. Berna Özkale Edelmann

Professorship Nano- and Microrobotics

Technical University of Munich (TUM)

Berna.oezkale@tum.de

TUM Corporate Communications Center contact:

Andreas Schmitz

0162-27 46 193

andreas.schmitz@tum.de

The Technical University of Munich (TUM) is one of the world’s leading universities in terms of research, teaching and innovation, with around 700 professorships, 53,000 students and 12,000 staff. TUM’s range of subjects includes engineering, natural and life sciences, medicine, computer sciences, mathematics, economics and social sciences. As an entrepreneurial university, TUM envisages itself as a global hub of knowledge exchange, open to society. Every year, more than 70 start-ups are founded at TUM, which acts as a key player in Munich’s high-tech ecosystem. The university is represented around the world by its TUM Asia campus in Singapore along with offices in Beijing, Brussels, Mumbai, San Francisco and São Paulo. Nobel Prize laureates and inventors such as Rudolf Diesel, Carl von Linde and Rudolf Mößbauer have conducted research at TUM, which was awarded the title of University of Excellence in 2006, 2012 and 2019. International rankings regularly cite TUM as the best university in the European Union.