Latest technology that could help those with hearing loss

A recent story on CNBC.com reported that scientists are working on a number of experimental techniques that may soon transform hearing interventions and could greatly improve the quality of life for the 360 million people worldwide who lack some or all of their ability to hear.   Here’s a recap of some of the latest technology researchers are working on.

How Hearing Works

Normal hearing is actually simpler than it may appear. Sound waves move through the ear canal and pulse the ear drum, which then moves the tiny bones inside the middle ear. They in turn tap the cochlea, a snail shell–looking structure that contains thousands of delicate hairs and fluid. The cochlea converts mechanical signals into electrical ones, which it then passes to the auditory nerve, which transmits it to the brain for processing.

But the ear presents a difficult engineering problem. If any of these parts are disrupted, a person might lose some or all of her hearing. And what kind of intervention works best depends on which part is affected. Those who lose hearing later in life, either due to a toxin, loud noise or simply as a part of aging, can be fitted with hearing aids to amplify sounds; children born with hereditary hearing loss can get devices called cochlear implants surgically placed deep into the ear.

New Hearing Technology

For those who lost hearing later in life, more sophisticated devices might be the first big step to improving hearing. Tobias Moser, a professor of auditory neuroscience at the University Medical Center Göttingen is working to improve the function of a cochlear implant by turning it into an optical device instead of an electric one. Instead of turning sound into electrical signals to be transmitted to the brain, as current cochlear implants do, this technique turns sound into light. Micro-LEDs flash onto genetically altered neurons, which send the information to the brain.

Other scientists are turning to other senses to encode information usually communicated audibly. “We’re used to thinking that we have five senses, but that’s actually not the case — we have tons of different types of sensory receptors in the body,” said Scott Novich, the co-founder and chief technology officer at start-up Neosensory. The sense of touch, for example, actually processes pressure, pain, temperature and vibration, each through a different type of sensory receptor in the skin, Novich said.

At Neosensory, Novich and his colleagues are developing a commercially available version of VEST, their research project that uses sensory substitution to map sounds onto the skin before the information is transmitted to the brain. Novich’s goal is to make a device that can be worn under clothes and may be more comfortable to wear for long periods of time than hearing aids.

Initial trials show that it takes some time to train the brain to understand these signals, and Novich doesn’t expect VEST to replace hearing aids necessarily — it could compensate for frequencies of sound that hearing aids might not transmit well, or even augment the nuance of information that wearers receive. Neosensory is doing participant research now and hopes to start manufacturing a product in about a year.

Regenerating Cells to Restore Heairng

Some researchers are going past devices and working directly on the body’s cells to restore hearing. Stefan Heller, a professor of otolaryngology at Stanford University, is figuring out how to revert inner ear cells to their earlier, functional state in order to restore hearing. It’s an ability that birds have and mammals lack, so Heller and his team have been working to understand how cells tell each other to regenerate. In five to 10 years, they plan to start testing a few drug compounds on humans. If all goes as planned, their discoveries wouldn’t offer a cure for hearing loss but could give people with degenerative hearing loss the option to take a drug and delay getting a hearing aid.

Albert Edge, a professor of otolaryngology at Harvard Medical School, is also looking into regenerating cells to restore hearing. But his lab has focused on the hair cells inside the cochlea and the neurons from the auditory nerve connected to it. Four years ago Edge and his collaborators discovered that certain molecular compounds could help hair cells regrow, which led to an improvement in hearing in mice. That showed them it could be done, but the effect was not as dramatic as they would have liked, said Edge.

Armed with more knowledge about how cells regenerate elsewhere in the body, Edge and his team have been exploring how various drugs can encourage the regrowth of hair cells and neurons. Ultimately, drugs, which would likely have to be injected deep into patients’ ears, could be tailored to individual needs. “What’s attractive about our approach and others like us is that our aim is to restore the ear to what it was,” Edge said.

The goal is providing alternatives to people for whom hearing aids are not a good option. Edge’s work is still limited to Petri dishes and mice, but his team hopes to start some small clinical trials in a few years.

Gene Therapy

For those with inherited hearing loss, many of these approaches won’t work. If a person had a genetic mutation that caused the cochlear hairs to die off, taking a drug like the one Edge is working on won’t fix that problem. “Even if we did regenerate the cells with a drug, they would still be defective and would presumably die off because