New method could lead to deep brain stimulation with no surgery
Imperial College London Health News Jun 21, 2017
A team at the Massachusetts Institute of Technology (MIT), including a neuroengineer at Imperial College London, have developed a DBS method that involves placing electrodes on the scalp, rather than inside the brain. The method is called Temporal Interference (TI) stimulation.
The team have used TI stimulation on mouse models and demonstrated that they can non–invasively activate neurons in the hippocampus – a region deep in the brain that is central to memory and cognition. The advantage of TI stimulation is that it is precise, only exciting the targeted neurons. By comparison the standard non–invasive brain stimulation approach excites both the targeted neurons, and also neurons closer to the surface.
Standard DBS requires the surgeon to manually move the electrodes to different regions of the brain to administer the therapy. By contrast, the TI simulation can be steered in a lateral direction by simply changing the ratios of the currents. The team demonstrated the effectiveness of this steering mechanism by activating different parts of the mouse model associated with paw and whisker movements.
The researchers caution that their work is still in its early stages and that it will take years of work before it could be used in clinical trials with patients. However, the team say their work shows promise as a new type of non–invasive method for DBS, which could ultimately enable DBS to be used more widely. They are interested in whether such a technique could be used to treat neurological conditions such as AlzheimerÂs disease, where neurons in the hippocampus have degenerated.
The lead author of the paper is Dr Nir Grossman, who was a Wellcome Trust–MIT Fellow at the Massachusetts Institute of Technology. He is now at the Centre for Bioinspired Technology of the Department of Electrical and Electronic Engineering at Imperial College London.
Dr Grossman said: ÂMany patients with neurological disorders cannot use deep brain stimulation methods due to the high–risk nature of the procedure. We need to do more work before we can trial this technique in patients, but if that work is successful, it would be great to explore whether deep brain simulation might have uses for conditions like AlzheimerÂs where the treatment options are really limited.
ÂWe think this technique has a lot of potential – the Temporal Interference method uses electrical fields that are well understood, and patients wouldnÂt need to undergo chemical or genetic manipulation in the brain, added Dr Grossman, who is now continuing this work at Imperial.
The new TI method developed by the team in this study, which was published in the journal Cell involves placing two pairs of electrodes on the scalp, from where two electrical currents are applied to the brain.
Both currents oscillate at frequencies that are too fast for the neurons to follow. However, at the intersection where these two currents meet the amplitude of the combined currents oscillates at a slower frequency that the neurons can follow. The slowly oscillating TI stimulation is the point at where the DBS occurs.
In the case of the mouse model, the team were able to localize the slowly oscillating TI stimulation in the hippocampus while exposing the overlaying brain regions to the fast oscillating currents that passed through the tissue without affecting it.
The researchers say the next step will see them improving the range, depth and precision at which the slowly oscillating envelope can penetrate the deeper parts of the brain. This will be done by increasing the number of electrodes that can be placed on the skull and further experimentation with, and fine tuning of, the frequencies of the electrical field.
One of the main aims is for the electrical field to reach the subthalamic nucleus deep in the brain, which is involved in motor control.
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The team have used TI stimulation on mouse models and demonstrated that they can non–invasively activate neurons in the hippocampus – a region deep in the brain that is central to memory and cognition. The advantage of TI stimulation is that it is precise, only exciting the targeted neurons. By comparison the standard non–invasive brain stimulation approach excites both the targeted neurons, and also neurons closer to the surface.
Standard DBS requires the surgeon to manually move the electrodes to different regions of the brain to administer the therapy. By contrast, the TI simulation can be steered in a lateral direction by simply changing the ratios of the currents. The team demonstrated the effectiveness of this steering mechanism by activating different parts of the mouse model associated with paw and whisker movements.
The researchers caution that their work is still in its early stages and that it will take years of work before it could be used in clinical trials with patients. However, the team say their work shows promise as a new type of non–invasive method for DBS, which could ultimately enable DBS to be used more widely. They are interested in whether such a technique could be used to treat neurological conditions such as AlzheimerÂs disease, where neurons in the hippocampus have degenerated.
The lead author of the paper is Dr Nir Grossman, who was a Wellcome Trust–MIT Fellow at the Massachusetts Institute of Technology. He is now at the Centre for Bioinspired Technology of the Department of Electrical and Electronic Engineering at Imperial College London.
Dr Grossman said: ÂMany patients with neurological disorders cannot use deep brain stimulation methods due to the high–risk nature of the procedure. We need to do more work before we can trial this technique in patients, but if that work is successful, it would be great to explore whether deep brain simulation might have uses for conditions like AlzheimerÂs where the treatment options are really limited.
ÂWe think this technique has a lot of potential – the Temporal Interference method uses electrical fields that are well understood, and patients wouldnÂt need to undergo chemical or genetic manipulation in the brain, added Dr Grossman, who is now continuing this work at Imperial.
The new TI method developed by the team in this study, which was published in the journal Cell involves placing two pairs of electrodes on the scalp, from where two electrical currents are applied to the brain.
Both currents oscillate at frequencies that are too fast for the neurons to follow. However, at the intersection where these two currents meet the amplitude of the combined currents oscillates at a slower frequency that the neurons can follow. The slowly oscillating TI stimulation is the point at where the DBS occurs.
In the case of the mouse model, the team were able to localize the slowly oscillating TI stimulation in the hippocampus while exposing the overlaying brain regions to the fast oscillating currents that passed through the tissue without affecting it.
The researchers say the next step will see them improving the range, depth and precision at which the slowly oscillating envelope can penetrate the deeper parts of the brain. This will be done by increasing the number of electrodes that can be placed on the skull and further experimentation with, and fine tuning of, the frequencies of the electrical field.
One of the main aims is for the electrical field to reach the subthalamic nucleus deep in the brain, which is involved in motor control.
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