Tim Denison DPhil

When treating neurological disorders, such as Parkinson’s disease, doctors have generally relied on drug discoveries, but this is often a costly and lengthy process. With the significant personal and societal costs incurred by such disorders there’s an imperative to invest in alternative approaches to treatment. 

Bioelectronics work directly with the body’s own nervous system to monitor brain signals and, as needed, tweak the electrical activity within nerves to alleviate symptoms of diseases. Despite clinical success in treating symptoms of diseases like Parkinson’s, existing bioelectronic systems have several limitations that arguably limit their adoption. For example, currently a skilled surgeon is required to implant the system in a patient, and the system’s output is inflexible in contrast to the rapidly changing and reactive activity of the nervous system.

The microelectronic basis and digital programmability of bioelectronic systems means that there is huge potential for flexibility in both research and future medical device design. Emerging technology offers the possibility of building restorative neural systems which are adaptable and programmable for various diseases, as well as specifically for individuals. The codes used to programme the systems can be modified as scientific understanding of the brain evolves, and also be used to rapidly respond to physiological fluctuations within the body. But to realize this potential, we first need a better understanding of how the brain functions and responds to bioelectronic interventions.

Professor Denison’s programme is exploring a continuum of adaptive, minimally-invasive bioelectronic systems. This includes developing the key scientific instrumentation required to better understand how the brain functions and adapts to a range of interventions including electrical, ultrasound and transcranial electro-magnetic stimulation, and in collaboration with clinician-partners, applying these tools and know-how to prototype concepts for future disease treatments; all with the goal of ultimate clinical translation

• Open Mind: A collaboration supporting a bi-directional brain-machine-interface research tool for the BRAIN initiative.
• MRC Brain Network Dynamics Unit: A project designing and evaluating minimally-invasive neural interfaces.
• NIH Working Group for BRAIN 2.0
• Associate Editor, IEEE TBioCAS, TBME

Bioelectronics, Medical Device Design, Physiologic Interfaces and Controls