The project aims at developing a novel sensor for measuring weak magnetic fields due to electric activity of the human brain by performing magnetoencephalographic (MEG) measurements. The goal is to develop quantum-optics-based magnetometers which will be integrated into a helmet placed on the head of the study subject.
The main objectives of OPMMEG are:
1) to develop a prototype multi-OPM system consisting of at least four densely-packed OPM sensors with performance suitable for biomagnetic applications in a clinical context
2) to evaluate the system’s performance in a laboratory environment for MEG- and MMG-measurements with human subjects
3) to evaluate the performance, usability, reliability and safety of the system, relative to the needs of clinicians and researchers
4) to assess the manufacturability of the system and its business potential in the medical field
5) to explore routes to exploitation of the core components of the OPM sensor system as spin-off technologies in other application areas, including other quantum sensor types.
The project consists of 3 WPs which focuses on the development of technological elements, such as VCSEL (WP3), protocols for optimal signal generation and recovery (WP4), and sensor packaging (WP5). The developed elements are then integrated and the performance of the sensor array is validated (WP6) and verified through demonstrator (WP7). Commercialization aspects (WP2), such as business model, are kept in mind. Ethical issues (WP1) and management (WP8) complete the project.
The impact of the developed products and processes can be seen in different fields. The main result of the project is a MEG system demonstrator which can be used in hospitals and clinics for improving quality of life for patients. Also novel scientific insights on brain function can be gained. VCSEL of 795 nm can be utilized in several fields in addition to MEG. Quantum sensor packages are aimed to have improved heat management, and as miniaturized and mass-producible packages they can be utilized also in different areas in e.g. aerospace and medical applications. The developed quantum sensor control systems have an impact on different atomic vapor cell-based components, such as OPMs, gyroscopes and clocks.