Stretchable neuromorphic device aims to advance health data analysis
Researchers at the University of Chicago’s Pritzker School of Molecular Engineering (PME) say they have developed a flexible, stretchable computing chip that processes information by mimicking the human brain. The device, say the researchers, aims to change the way health data is processed.
“With this work,” says said Sihong Wang, a materials scientist and Assistant Professor of Molecular Engineering, “we’ve bridged wearable technology with artificial intelligence and machine learning to create a powerful device which can analyze health data right on our own bodies.”
In the future, say the researchers, people’s health could be tracked continuously by wearable biosensor electronics that can detect disease even before symptoms appear. Unobtrusive, wearable computing devices are one step toward making this vision a reality.
Such wearable biosensors could track complex indicators of health including levels of oxygen, sugar, metabolites and immune molecules in people’s blood. One of the keys to making these sensors feasible is their ability to conform to the skin.
As such skin-like wearable biosensors emerge and begin collecting more and more information in real-time, the analysis becomes exponentially more complex. A single piece of data must be put into the broader perspective of a patient’s history and other health parameters.
Today’s smart phones are not capable of the kind of complex analysis required to learn a patient’s baseline health measurements and pick out important signals of disease, say the researchers. However, cutting-edge artificial intelligence platforms that integrate machine learning to identify patterns in extremely complex datasets can do a better job. But sending information from a device to a centralized AI location is not ideal.
“Sending health data wirelessly is slow and presents a number of privacy concerns,” says Wang. “It is also incredibly energy inefficient; the more data we start collecting, the more energy these transmissions will start using.”
The researchers set out to design a chip that could collect data from multiple biosensors and draw conclusions about a person’s health using cutting-edge machine learning approaches. Importantly, they wanted it to be wearable on the body and integrate seamlessly with skin.
To achieve this, the researchers turned to polymers, which can be used to build semiconductors and electrochemical transistors but also have the ability to stretch and bend. They assembled polymers into a device that allowed the artificial intelligence-based analysis of health data. Rather than work like a typical computer, the chip — called a neuromorphic computing chip — functions more like a human brain, able to both store and analyze data in an integrated way.
To test the utility of their new device, the researchers used it to analyze electrocardiogram (ECG) data representing the electrical activity of the human heart. They trained the device to classify ECGs into five categories: healthy, or four types of abnormal signals. Then, they tested it on new ECGs. Whether or not the chip was stretched or bent, they showed, it could accurately classify the heartbeats.
More work is needed to test the power of the device in deducing patterns of health and disease, say the researchers, but eventually, it could be used either to send patients or clinicians alerts, or to automatically tweak medications.
“If you can get real-time information on blood pressure, for instance, this device could very intelligently make decisions about when to adjust the patient’s blood pressure medication levels,” says Wang.
The researchers are planning new iterations of the device to both expand the type of devices with which it can integrate and the types of machine learning algorithms it uses. For more, see “Intrinsically stretchable neuromorphic devices for on-body processing of health data with artificial intelligence.”