Medical Devices

Wireless sensor grows into bone to monitor health data in real-time

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An osseoelectronic device, grafted to a sample of imitation bone
Gutruf Lab
An osseoelectronic device, grafted to a sample of imitation bone
Gutruf Lab
The osseoelectronic device is about the size of a penny and as thin as a sheet of paper
Gutruf Lab

Researchers at the University of Arizona have developed an ultra-thin device that permanently bonds onto bones, and beams data out wirelessly. The breakthrough could allow doctors to monitor the health of a patient’s bones over time, or how well they’re healing after an injury.

The new devices, which the team calls osseosurface electronics, contain an array of sensors packed into a flexible package about the size of a penny and as thick as a piece of paper. They can wirelessly transmit data about the bones out to a smartphone or other device. And they don’t need a battery to run – instead, power can be beamed in from the outside using near-field communication (NFC).

To keep it attached to the bone long-term, the team created an adhesive that contains calcium phosphate ceramic particles, which allows the bone to actually grow onto it. This bonds the device permanently to the bone, rather than having it come loose when the outer layers shed off in time.

The osseoelectronic device is about the size of a penny and as thin as a sheet of paper
Gutruf Lab

The osseosurface electronics are designed to be thin enough that they won’t irritate the muscles moving over the top of them. Eventually it is hoped devices like these could be implanted in people with conditions like osteoporosis, to provide long-term monitoring of their bone health. Or they could help after a break or fracture, to allow doctors to watch how the bone heals.

"Being able to monitor the health of the musculoskeletal system is super important," says Philipp Gutruf, co-senior author of the study. "With this interface, you basically have a computer on the bone. This technology platform allows us to create investigative tools for scientists to discover how the musculoskeletal system works and to use the information gathered to benefit recovery and therapy.”

The team has tested the device in animals, showing that they can be implanted into small and large animal models, and real-time data can be read out with a smartphone. It’s still very early days for the research, and just how practical it might turn out to be is still very much up in the air. But it’s intriguing work nonetheless.

The research was published in the journal Nature Communications.

Source: University of Arizona

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