Microengineering
Our device is crafted using well-established microfabrication techniques that are commonly employed in the creation of processors, sensors, and other advanced technologies. By leveraging these proven methodologies, we ensure that our design meets high standards of precision and performance. Microfabrication allows us to manipulate materials at a microscopic scale, enabling the development of intricate structures that are essential for the functionality of our device.
Semiconductor Technologies
We leverage well established microfabrication technologies together with 3D manufacturing techniques to build endovascular stimulation devices
Neuromodulation
We revolutionize neuromodulation by designing chronic implants marking a breakthrough in therapeutic medicine.
Transvascular Neuromodulation
Transvascular neuromodulation is a cutting-edge technique that stimulates nerves via the vascular system, allowing precise neural control without invasive surgery. By using bioelectronic devices placed in blood vessels, this approach targets specific nerves to treat conditions like hypertension and chronic pain. It offers a powerful, less risky alternative to traditional neurosurgical methods, marking a breakthrough in therapeutic medicine.
Flexible Bioelectronics
We leverage expertise from EPFL's Laboratory for Soft Bioelectronic Interfaces to design flexible bioelectronics with seamless body compatibility and exceptional durability.
Transvascular Neuromodulation
Our implants are designed to transmit currents through vascular structures, effectively stimulating nearby neural networks for therapeutic benefits.
We use the Neural Microsystems Platform at Campus Biotech to fabricate our endovascular interfaces, using well established semiconductor processes to ensure precision, quality, and device variety.