Neuroscientists at Newcastle University have developed the device, the size of a mobile phone, which delivers a series of small electrical shocks followed by an audible click to strengthen brain and spinal connections.
The experts believe this could revolutionise treatment for patients, providing a wearable solution to the effects of stroke.
Following successful work in primates and healthy human subjects, the Newcastle University team are now working with colleagues at the prestigious Institute of Neurosciences, Kolkata, India, to start the clinical trial. Involving 150 stroke patients, the aim of the study is to see whether it leads to improved hand and arm control.
Stuart Baker, Professor of Movement Neuroscience at Newcastle University who has led the work said: “We were astonished to find that a small electric shock and the sound of a click had the potential to change the brain’s connections. However, our previous research in primates changed our thinking about how we could activate these pathways, leading to our study in humans.”
Recovering hand control
Publishing today in the Journal of Neuroscience, the team report on the development of the miniaturised device and its success in healthy patients at strengthening connections in the reticulospinal tract, one of the signal pathways between the brain and spinal cord.
This is important for patients as when people have a stroke they often lose the major pathway found in all mammals connecting the brain to spinal cord. The team’s previous work in primates showed that after a stroke they can adapt and use a different, more primitive pathway, the reticulospinal tract, to recover.
However, their recovery tends to be imbalanced with more connections made to flexors, the muscles that close the hand, than extensors, those that open the hand. This imbalance is also seen in stroke patients as typically, even after a period of recuperation, they find that they still have weakness of the extensor muscles preventing them opening their fist which leads to the distinctive curled hand.
Partial paralysis of the arms, typically on just one side, is common after stroke, and can affect someone’s ability to wash, dress or feed themselves. Only about 15% of stroke patients spontaneously recover the use of their hand and arm, with many people left facing the rest of their lives with a severe level of disability.
Senior author of the paper, Professor Baker added: “We have developed a miniaturised device which delivers an audible click followed by a weak electric shock to the arm muscle to strengthen the brain’s connections. This means the stroke patients in the trial are wearing an earpiece and a pad on the arm, each linked by wires to the device so that the click and shock can be continually delivered to them.
“We think that if they wear this for 4 hours a day we will be able to see a permanent improvement in their extensor muscle connections which will help them gain control on their hand.”
The techniques to strengthen brain connections using paired stimuli are well documented, but until now this has needed bulky equipment, with a mains electric supply.
The research published today is a proof of concept in human subjects and comes directly out of the team’s work on primates. In the paper they report how they pair a click in a headphone with an electric shock to a muscle to induce the changes in connections either strengthening or weakening reflexes depending on the sequence selected. They demonstrated that wearing the portable electronic device for seven hours strengthened the signal pathway in more than half of the subjects (15 out of 25).
Professor Stuart Baker added: “We would never have thought of using audible clicks unless we had the recordings from primates to show us that this might work. Furthermore, it is our earlier work in primates which shows that the connections we are changing are definitely involved in stroke recovery.”
The clinical trial is just starting at the Institute of Neurosciences, Kolkata, India. The country has a higher rate of stroke than Western countries which can affect people at a younger age meaning there is a large number of patients. The Institute has strong collaborative links with Newcastle University enabling a carefully controlled clinical trial with results expected at the end of this year.
REFERENCE: Spike-timing Dependent Plasticity in the Long Latency Stretch Reflex Following Paired Stimulation from a Wearable Electronic Device. KH.M. Riashad Foysal, Felipe de Carvalho, Stuart N. Baker. Journal of Neuroscience.
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