Epileptic seizures strike with little warning, and nearly one third of people living with epilepsy are resistant to treatment that controls these attacks. More than 250,000 Australians and 65 million people worldwide are living with epilepsy.

Now researchers at the University of Sydney have used advanced artificial intelligence and machine learning to develop a generalized method to predict when seizures will strike that will not require surgical implants.

Dr. Omid Kavehei from the faculty of engineering and IT and the University of Sydney Nano Institute says, “We are on track to develop an affordable, portable and nonsurgical device that will give reliable prediction of seizures for people living with treatment-resistant epilepsy.”

Dr. Omid Kavehei from the faculty of engineering and IT and Sydney Nano. (Credit: University of Sydney)

In a paper published in Neural Networks, Dr. Kavehei and his team have proposed a generalized, patient-specific, seizure-prediction method that can alert epilepsy sufferers within 30 minutes of the likelihood of a seizure.

Dr. Kavehei says there had been remarkable advances in artificial intelligence as well as micro- and nano-electronics that have allowed the development of such systems.

“Just four years ago, you couldn't process sophisticated AI through small electronic chips. Now it is completely accessible. In five years, the possibilities will be enormous,” Dr. Kavehei says.

The study uses three data sets from Europe and the United States. Using that data, the team has developed a predictive algorithm with sensitivity of up to 81.4 percent and false prediction rate as low as 0.06 an hour.

“While this still leaves some uncertainty, we expect that as our access to seizure data increases, our sensitivity rates will improve,” Dr. Kavehei says.

Carol Ireland, chief executive of Epilepsy Action Australia, says, “Living with constant uncertainty significantly contributes to increased anxiety in people with epilepsy and their families, never knowing when the next seizure may occur.

“Even people with well-controlled epilepsy have expressed their constant concern, not knowing if or when they will experience a seizure at work, school, traveling or out with friends.

“Any progress toward reliable seizure prediction will significantly impact the quality of life and freedom of choice for people living with epilepsy.”

Dr. Kavehei and lead author of the study, Nhan Duy Truong, used deep machine learning and data-mining techniques to develop a dynamic analytical tool that can read a patient's electroencephalogram, or EEG, data from a wearable cap or other portable device to gather EEG data.

Wearable technology could be attached to an affordable device based on the readily available Raspberry Pi technology that could give a patient a 30-minute warning and percentage likelihood of a seizure.

Dr. Kavehei says an advantage of their system is that is unlikely to require regulatory approval, and it could easily work with existing implanted systems or medical treatments.

The algorithm that Dr. Kavehei and team have developed can generate optimized features for each patient. They do this using what is known as a ‘convolutional neural network,’ that is highly attuned to noticing changes in brain activity based on EEG readings.

Other technologies being developed typically require surgical implants or rely on high levels of feature engineering for each patient. Such engineering requires an expert to develop optimized features for each prediction task.

An advantage of Dr. Kavehei's methodology is that the system learns as brain patterns change, requiring minimum feature engineering. This allows for faster and more frequent updates of the information, giving patients maximum benefit from the seizure prediction algorithm.

The next step for the team is to apply the neural networks across much larger data sets of seizure information, improving sensitivity. They are also planning to develop a physical prototype to test the system clinically with partners at the University of Sydney's Westmead medical campus.

An alarm would be triggered between 30 and 5 minutes before a seizure onset, giving patients time to find a safe place, reduce stress, or initiate an intervention strategy to prevent or control the seizure.

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