New research has been able to demonstrate, for the first time, that a wearable brain scanner can measure brain function whilst individuals are standing and walking around.
It is thought that this breakthrough could help to better understand and diagnose a range of neurological problems that affect movement, including stroke.
To enable this novel technology, researchers from the University of Nottingham’s School of Physics have developed a new design of magnetic field control system.
This allows for a much greater degree of subject movement than has ever previously been possible.
The unique wearable brain scanner system uses what can be described small LEGO-brick-sized sensors, known as optically pumped magnetometers (OPMs), which measure magnetic fields generated by cellular activity in the brain, a technique called Magnetoencephalography, or MEG.
These sensors are incorporated into a lightweight helmet. The unique design means the system can be adapted to fit anyone, from newborns to adults, and sensors can be placed much closer to the head, which dramatically enhancing data quality.
This is a step change from conventional brain scanners that are large and fixed and require the patient to stay very still during scanning.
However, OPMs must operate at precisely zero magnetic field to become sensitive enough to measure brain signals, this means they must be operated inside a magnetically shielded room (MSR). This room must contain additional equipment that allows precise control of magnetic fields at a level 50,000 times smaller than the Earth’s magnetic field.
Existing solutions to this problem used complex wire patterns to generate cancellation fields over small, fixed regions. This allowed people to move their heads whilst seated, but was unable to allow ambulatory movement.
The Nottingham team have now designed a ‘matrix coil’ system formed from multiple simple square coils. The coil currents can be reconfigured in real time to compensate magnetic fields over a moving region that can be flexibly placed within the coils, giving much greater scope for people to move during a scan.
Niall Holmes, study lead, says: “By using the matrix coils to allow greater movement we can, for the first time, realise many scanning scenarios that would have previously been considered impossible, but that have the potential to significantly expand our understanding of exactly what is happening in the brain during movement, neurodevelopment and in a range of neurological issues.”
Professor Matt Brookes leads MEG research in Nottingham, says: “Just 5 years ago, the idea of acquiring high resolution images of human brain electrophysiology whilst people walk around a room would have seemed like something from science fiction. The matrix coil has made this a reality! The applications span a huge area, from basic neuroscientific questions like how do young children learn to walk, to clinical challenges like why are older people prone to falling. It’s incredible to think how far this technology has come, and even more incredible to imagine where it’s going”.
