UW News

October 31, 2022

How low-cost earbuds can make newborn hearing screening accessible

UW News

A child sits in a chair and a person sits next to them. The person is holding a probe to the child's ear. The probe is connected to a smartphone on the person's lap.

A team led by researchers at the University of Washington has created a new hearing screening system that uses a smartphone and earbuds. Now the team is working with collaborators to use this tool as part of a hearing screening project in Kenya. Here, lead researcher Justin Chan, a UW doctoral student in the Paul G. Allen School of Computer Science & Engineering, uses the device to test a child’s hearing.Dr. Nada Ali/University of Washington

Newborns across the United States are screened to check for hearing loss. This test is important because it helps families better understand their child’s health, but it’s often not accessible to children in other countries because the screening device is expensive.

A team led by researchers at the University of Washington has created a new hearing screening system that uses a smartphone and low-cost earbuds instead. The team tested this device with 114 patients, including 52 babies up to 6 months old. The researchers also tested the device on pediatric patients with known hearing loss. Their tool performed as well as the commercial device, and it correctly identified all patients with hearing loss.

The team published these results Oct. 31 in Nature Biomedical Engineering.

“There is a huge amount of health inequity in the world. I grew up in a country where there was no hearing screening available, in part because the screening device itself is pretty expensive,” said senior author Shyam Gollakota, a UW professor in the Paul G. Allen School of Computer Science & Engineering. “The project here is to leverage the ubiquity of mobile devices people across the world already have — smartphones and $2 to $3 earbuds — to make newborn hearing screening something that’s accessible to all without sacrificing quality.”

One hand holds a probe and another hand holds a smartphone showing "pass" on the screen.

The earbuds are connected to a microphone in a probe (shown here in blue) that can be placed in the patient’s ear.Raymond Smith/University of Washington

Because babies can’t tell doctors whether they can hear a given sound, these tests rely on the mechanics of the ear.

“When an external sound is played, hair cells in the inner ear move and vibrate. The result is a very quiet sound that our instruments can pick up,” said co-author Dr. Randall Bly, an associate professor of otolaryngology-head and neck surgery at the UW School of Medicine who practices at Seattle Children’s Hospital. “This screening is very sensitive, meaning that if there is a concern about a patient’s hearing, they will be referred for a more thorough evaluation with a specialist.”

For the test, doctors send two different tones into the ear at the same time. Based on those tones, the hair cells in the ear vibrate and create a third tone, which is what the doctors are listening for.

One reason the commercial device is expensive is that its speaker has been designed to play the two tones without any interference. The UW researchers found that they could use affordable earbuds — where each earbud plays one of the two tones — instead. The earbuds are connected to a microphone in a probe that can be placed in the patient’s ear. The microphone records any sounds from the ear and sends them to a smartphone for processing.

Two earbuds, each is connected to a plastic tube

The earbuds are connected as shown here to the probe.Raymond Smith/University of Washington

“As you can imagine, these sounds that are coming out from the ear are very soft, and sometimes it’s hard to hear them over noise in the environment or if the patient is moving their head,” said lead author Justin Chan, a UW doctoral student in the Allen School. “We designed  algorithms on the phone that help us detect the signal even with all that background noise. These algorithms can run in real time on any smartphone and do not require the latest smartphone models.”

The researchers tested their device at three hearing clinics in the Puget Sound area in the state of Washington. For each test, they tested four different frequencies, which is typical for these types of hearing screenings. Participants ranged in age from a few weeks to 20 years old.

Now the team is working with collaborators to use this tool as part of a newborn hearing screening project in Kenya. The researchers teamed up with a group from the UW global health department, the University of Nairobi and the Kenya Ministry of Health to create the project “Toward Universal Newborn and Early Childhood Hearing Screening in Kenya,” or TUNE.

“Right now, this is a prototype that we created. The next challenge is really scaling this up and then working with local experts in each country who are the most familiar with the particular challenges in each situation,” Chan said. “We have an opportunity to really have an impact on global health, especially for newborn hearing. I think it’s pretty gratifying to know that the research we do can help to directly solve real problems.”

A person holds a child, who is looking at the camera. Another person's arm holds a probe to the child's ear. The probe is connected to a smartphone, which the third person is holding.

A child in Kenya has their hearing tested by lead researcher Justin Chan.Dr. Nada Ali/University of Washington

Additional co-authors on this paper are Dr. Nada Ali, a resident in otolaryngology-head and neck surgery at the UW School of Medicine; Ali Najafi, who worked on this project as a UW doctoral student in the electrical and computer engineering department; Anna Meehan, a clinical research coordinator at Seattle Children’s; Lisa Mancl, a UW affiliate instructor in speech and hearing sciences; and Dr. Emily Gallagher, an associate professor of pediatrics in the UW School of Medicine who practices at Seattle Children’s. This research was funded by the National Institute on Deafness and Other Communication Disorders, the Washington Research Foundation, the Seattle Children’s Research Institute, the Seattle Children’s Research Integration Hub, the Pilot Awards Support Fund Program, a Moore Inventor Fellow award and the National Science Foundation.

For more information, contact tune@cs.washington.edu.

Grant numbers: T32DC000018, 10617

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