Muscle fiber formation
With our topography-guided tissue engineering technique, made possible by the BiomACS screening platform, we can improve the parallel alignment of muscle (sub)structures, promoting effective regeneration.
Bone formation
Discover how physicochemical properties are key to controlling cell behavior in the development of biomaterials for tissue engineering and regenerative medicine, with a focus on osteogenesis. Using mesenchymal stem cells (MSCs) and advanced screening technologies such as BiomACS, we identify optimal surface structures to promote bone formation.
Neuronale ontwikkeling
BiomACS culture systems pave the way for neurogenic regeneration. Our research shows that precise control over biophysical properties, such as topography and elasticity, is crucial for promoting neural differentiation, opening up new possibilities for effective neurogenic therapies.
Gene transfer
Discover how gene therapy and advanced delivery systems are opening new horizons in biomedical sciences. Our findings show that surface-mediated gene transport, using advanced screening technologies such as BiomACS, can improve the transfection efficiency of stem cells, which is promising for improved cell culture and gene therapies without viral vectors.
Translational culture system
Discover how biomaterials are shaping the future of medicine, with a focus on bio-instructive materials that stimulate beneficial cell responses. Our BiomACS screening platform offers advanced technology to investigate the impact of biomaterials on cell behavior at scale and with precision, advancing the development of implantable technologies and medical devices.
Circular culture systems
Discover how BiomACS develops sustainable growing media using bio-based and biodegradable PHA as an alternative to traditional plastic. With our advanced screening platform, we deliver the same performance, but with a circular and eco-friendly impact.
