/Focused ultrasound for vagus nerve stimulation

Focused ultrasound for vagus nerve stimulation

Gent | More than two weeks ago

Unlocking the potential of ultrasound for minimally invasive and targeted stimulation of the vagus nerve

Vagus nerve stimulation (VNS) has been increasingly used in the treatment of several health conditions. These include treatment-resistant epilepsy, obesity, pain, and incontinence. One of the main obstacles in VNS is the lack of stimulation selectivity when it comes to only activating vagus nerve fibres that produce a desired effect while avoiding activation of non-targeted fibres, the latter of which could lead to serious side effects. In electrical VNS, fibre-selectivity is currently achieved by adjusting parameters of the stimulation waveform. However, the results are less than perfect. While it is possible to selectively activate the large-diameter A-type fibres, selectively activating the small-diameter C-type fibres while avoiding the concurrent recruitment of A-type fibres, proves to be difficult. Moreover, fibre type-selectivity alone cannot always provide adequate control of VNS effects. In this case, spatially selective VNS would need to be deployed: the knowledge of the anatomical arrangement of fibre populations in the vagus nerve can be used to design a stimulator device capable of targeting a single compartment of a nerve fibre, rather than the entire fibre. Spatial targeting of specific areas of the vagus nerve, especially those that lie in the interior, may require complex stimulation waveforms, multi-contact electrodes and cathode/anode arrangements to produce clinically meaningful selectivity.
 
Other than electrical stimulation, focused ultrasound stimulation (FUS) has also shown potential in targeting specific neural tissue within a larger neural mass, including tissue deeper in the nerve structure. FUS thanks its spatial selectivity to the short wavelength of ultrasound in biological tissue. In ideal circumstances, FUS can achieve a spatial resolution in the order of cubic millimetres in tissue. The inherent focusing ability of ultrasound also simplifies the stimulator design compared to electrical stimulation. Ultrasound has the potential to stimulate the vagus nerve distally and non-invasively while maintaining focality (e.g., transcutaneously through the neck, Fig. 1 left).
 
The goal of this PhD research is to design a FUS system for spatially selective activation of the vagus nerve. The focus is on two usage scenarios: non-invasive transcutaneous FUS (Fig. 1 left) and minimally invasive FUS that places the transducer directly on the vagus nerve (Fig. 1 right). FUS has been rediscovered in the past 15 years and has enjoyed much attention from researchers. Despite this, the mechanisms of action of FUS are still not well-understood. For this reason, this PhD focuses on fundamental research including simulations of FUS biophysics and validation in experimental in-vitro/in-vivo setups. The first subobjective is to build extensive validated knowledge of the biophysics of FUS for VNS. The second subobjective is to formulate the requirements of a prototype FUS system for VNS, focusing on steerability of the stimulation target and low complexity of implementation.
 
In the first phase of the project, the PhD candidate performs numerical simulations of the acoustic pressure and particle velocity fields induced in the vagus nerve by a FUS transducer or transducer array. Both non-invasive (transcutaneous) and minimally invasive (transducer(s) on the vagus nerve) usage scenarios are considered. The goal is to design a transducer system of which the pressure focal point is aligned with the stimulation target. In the second phase, the field simulations are combined with simulations of the electro-mechanical neuron coupling and vagus nerve fibre response. In-silico optimization of the FUS focal spot and stimulation waveform is performed to maximize fibre recruitment. Of note is that the optimal FUS focal spot is not necessarily located on the cervical vagus nerve in the neck as in Fig. 1, left. There are indications that the vagus nerve branches in the abdominal cavity may be more sensitive to FUS than the cervical branch, explained by the larger presence of mechanosensitive ion channels in the former. In the third phase, the optimized design is experimentally validated in phantom models, living tissue and optionally animals. The project end result is a comprehensive set of requirements for a (pre)clinical FUS system for VNS. The end result should pave the way for a future prototype hardware realization of vagus nerve FUS.
 
Skills and background:
  • Electrical engineering, engineering physics or biomedical engineering
  • System design and implementation
  • Ability to devise creative solutions based on and going beyond the state of the art
  • Affinity with CMOS processes and transducer technology
  • Simulations, prototyping and proof-of-principle experiments

2025-141

Required background: Electrical engineering, engineering physics or biomedical engineering

Type of work: 85% modeling/simulation, 15% experimental

Supervisor: Chris Van Hoof

Co-supervisor: Xavier Rottenberg

Daily advisor: Thomas Tarnaud

The reference code for this position is 2025-141. Mention this reference code on your application form.

Who we are
Accept marketing-cookies to view this content.
Cookie settings
imec inside out
Accept marketing-cookies to view this content.
Cookie settings

Send this job to your email