This research examines the legal risks of mind-reading neurotechnology in criminal justice. By developing a neurorights framework—covering mental autonomy, privacy, and integrity—it aims to protect freedom of thought while enabling responsible forensic use of brain data as neurotechnologies rapidly advance.

This research uses advanced brain imaging, long-term clinical monitoring, and sensor data to understand why deep brain stimulation helps Essential Tremor patients—and why it sometimes stops working. By modelling neural pathways and analysing two-year outcomes, the project identifies optimal DBS targets and the main causes of treatment failure, improving long-term patient care.

My research improves brain–computer interfaces for children with disabilities by reducing the repetitive calibration needed before use. Using transfer learning and a team-selection algorithm, data from other users help personalise the system, cutting calibration by up to 90%. This makes creative activities like painting more accessible, enjoyable, and sustainable.