This technology describes screwless cranial implants that are custom-fit to individual skulls and provide broad neural access for sensing and stimulation.
Cranial windows are necessary for using neural-electronic interfaces to study and treat the brain. However, affixing the interface devices to the skull remains a technical challenge. The current standard approach is bone screws that are invasive and may cause mechanical failure by concentrating forces onto a small area of the skull. A faultless cranial implant is crucial to ensure biomechanical protection of the brain. Since the skull shape varies among patients, it is important to customize the implant for individual patients.
This technology describes custom-fit titanium neural implants with broad neural access that adhere to the inferior surface of the skull with no screws or adhesives. The titanium implant is 3D-printed and is durable and robust, stabilizing on the skull surface in a wrap-around manner. Titanium can foster new bone development in the gaps between the implant and the skull. Broad neural access allows the installation of intra- and extra-cranial devices for sensing and stimulation. The enhanced stability and bone-integrative properties may be useful in studying and treating neurological diseases.
This technology has been tested in human subjects.
Patent Pending (WO/2024/026489)
IR CU22306, CU23044
Licensing Contact: Kristin Neuman