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For the estimated 28 million Americans with hearing loss, life is a series of missed opportunities. Frustrated friends and family members often tire of shouting and will just give up on communicating altogether. This can make the world a very lonely place for the hearing-impaired. Hearing aids -- small electronic devices that amplify sound -- can help restore many of the sounds that hearing-impaired people are missing. However, research finds that very few people who need hearing aids actually use them. Only one out of every five Americans who could benefit from a hearing aid wears one, according to a 2006 study from Duke University.
Some people pass on hearing aids because of the cost, while others do so because they are embarrassed to be seen wearing them. What they don't realize is that many hearing aids are relatively inexpensive, and many of today's hearing aid styles are so small that they are nearly impossible to spot.
In this article, we'll find out exactly how hearing aids work, and learn about new technologies that are providing clearer, more natural sound for people with hearing loss. But first, let's look at what causes hearing loss.
What Causes Hearing Loss?
When you listen to something, whether it is a car alarm or a dog barking, the sound travels through the opening of your outer ear and causes your eardrum to vibrate. Three small bones in your middle ear carry this vibration to the cochlea -- the shell-shaped structure in your inner ear. The vibration stimulates hair cells, which create an electrical current in the auditory nerve. This current transmits the sound via nerve impulses to your brain, where it is processed into noise, like the sound of a car alarm or that of a dog barking.
People lose hearing in one of two ways:
Conductive hearing loss occurs when sound doesn't move as it should through the eardrum, ear canal or the three bones of the inner ear. It can be caused by earwax, a punctured eardrum, fluid in the ear, a genetic defect or an infection. The result is a sensation as though your ears are plugged. Conductive hearing loss can be treated with surgery.
Sensorineural hearing loss involves damage to the cochlea. It's the most common type, affecting about 90 percent of people with hearing loss. Sensorineural hearing loss can be a byproduct of aging, or it can occur due to infections, genes, head trauma, exposure to loud noises or fluid buildup in the inner ear. This is the type of hearing loss that a hearing aid can help.
Hearing aids are fairly simple devices, consisting of four basic parts:
Hearing aids aren't effective for everyone. Hair cells in the inner ear must pick up the vibrations that the hearing aid sends and convert those vibrations into nerve signals. So, you need to have at least some hair cells in the inner ear for it to work. And, even if some hair cells remain, a hearing aid won't completely restore normal hearing.
People with hearing loss have several hearing aid styles from which to choose. Generally, the smaller the hearing aid, the more it costs and the shorter its battery life.
In the ear (ITE): This large hearing aid works well for people with mild to severe hearing loss. It fits completely in the bowl of the ear. Because it is so large, the ITE hearing aid is among the most visible of styles, but the battery lasts longer than in smaller aids, and it can accommodate directional microphones (more on that later) and other added features.
In the canal (ITC): The ITC hearing aid works only for mild to moderate hearing loss. It is customized to fit the size and shape of the person's ear canal. Although this hearing aid is inconspicuous, its small size makes it difficult to adjust and change the battery. Some ITC hearing aids come with a remote control to make changing the settings easier. Also, users sometimes experience feedback noise with this type of hearing aid because the microphone and receiver sit close together.
Completely in the canal (CIC): This hearing aid is also appropriate for mild to moderate hearing loss, and it's even smaller than the ITC hearing aid. In fact, it's so small that a user must pull on a small wire to remove it from his ear. Because it fits completely in the ear canal, the CIC hearing aid is barely visible. Again, though, its small size makes it difficult to adjust and use added features. It's also more expensive than larger hearing aids.
Behind the ear (BTE): The BTE hearing aid can help with all types of hearing loss, from mild to profound. The electronics are in a case that sits just behind the ear. The case connects by a piece of clear tubing to a plastic piece called an earmold, which sits inside the ear. Sound travels from the earmold into the ear. This powerful and adjustable hearing aid can accommodate progressive hearing loss, as well as growth, which makes it ideal for children. However, its size and the tubing attaching the electronics to the earmold make it very visible. Also, the BTE hearing aid can cause feedback if it's not fitted correctly.
Behind the ear open fit: This newer version of the BTE model solves the problem of visibility. It is so small that it can barely be seen. A tiny device sits behind the ear and is attached by a tube to a miniscule speaker inside the ear canal. This hearing aid doesn't require an impression for fitting, and it provides better sound quality than ITE hearing aids. The downside is that it works only on people with mild hearing loss who can still hear low- and mid-frequency sounds.
Traditional hearing aids work well for people with varying degrees of hearing loss, but they can't restore sound to people who are profoundly deaf. Cochlear implants work better in people with more severe ear damage because they bypass the damaged parts of the ear and send the sound information -- as electrical signals -- directly to the auditory nerve. Cochlear implants can be used alone or with traditional hearing aids in people who have mild hearing loss at some frequencies but more severe hearing loss at other frequencies.
The cochlear implant is made up of two main systems: an external system and an internal system. The external system is composed of three parts: a sound processor, a microphone and a transmitter. The internal system features a receiver and an electrode array.
The microphone, which is attached to the sound processor, captures sound and sends it to the sound processor, a small device that can be inconspicuously clipped over the outer ear. The transmitter sits behind the sound processor and connects to the scalp directly outside where the internal receiver is implanted under the skin. The transmitter is fitted with a magnet that holds it onto the internal receiver. (Instead of being fastened to the scalp and ear, the external system can also be carried in a shirt pocket or hip pouch.) The receiver, which is about the size of a quarter, is implanted under the skin in the bone behind the ear. And the electrode array is a wire that runs from the implant into the cochlea.
The microphone picks up sound and sends it to the sound processor, which translates sound into digital information. It sends this digital information to the implanted receiver, which changes the digital information into electrical signals and sends these signals to the electrode array. The electrode array sends these signals to the auditory nerve, which then passes along the signals to the brain.
New Hearing Aids
New bone-anchored (baha) hearing aids bypass the normal hearing process to help people with severe sensorineural, conductive or mixed hearing loss who can't be helped by regular hearing aids. Instead of merely amplifying sound, these surgically implanted devices attach to the bones in the middle ear. Bypassing the auditory canal and middle ear, baha hearing aids create vibrations in the skull and transmit those vibrations directly to the cochlea through a process called direct bone conduction.
The most basic and essential component of any hearing aid is the battery. Without it, the hearing aid won't work. Most hearing aids use zinc-air cells, which are powered by oxygen, but a few use mercury batteries. The size of the hearing aid dictates how long a battery will last. Larger hearing aids have bigger batteries, which can last for about two weeks. Smaller batteries work for three to five days, on average.
In addition to the basic components of the hearing aid, you can add a couple of special features to enhance the quality of sound you're receiving:
A directional microphone allows you to hear sounds directly in front of you more clearly than sounds behind you and to the sides, so that you can focus on conversations without worrying about annoying background noise. You can switch between a directional microphone and regular microphone, depending on your listening situation. Directional microphones will fit only on the larger hearing aids.
A telecoil allows you to switch from your normal hearing aid microphone to the "T" setting in order to filter out environmental sounds when you're on the phone. Telecoils work only with hearing-aid-compatible phones. (All wired phones manufactured today must be hearing-aid-compatible, but many cordless and cell phones aren't compatible.) Many theaters, places of worship and auditoriums have induction-loop systems, which will also work with your hearing aid's "T" setting.
Telecoils aren't the only devices that can help people with hearing loss use the phone. Amplified phones have a louder ringer, as well as flashing lights, to signal incoming calls. Text phones transcribe the call into text for people who are severely hearing impaired. A loopset has a wire loop that goes around the neck and connects to a mobile phone. The loop sends sound from the phone to the hearing aid and filters out background noise.
If you find that you still have to turn the TV volume way up to hear it, you might benefit from direct audio input. Many hearing aids can be plugged directly into the television, computer, CD player, and radio for clearer sound.
Research to Improve Hearing Aids
Hearing aids available today are smaller and more powerful than ever, and researchers are aiming for even higher sound quality in the future. They're looking for ways to better amplify the sound signal and reduce feedback using the latest computer technology.
One avenue of research is focusing on a very unusual subject -- the fly Ormia ochracea. This tiny fly has very precise hearing, which allows it to determine the source of a sound with uncanny ease. Scientists are modeling directional microphones after the fly's ears. The new microphones will help amplify sounds from certain directions, while suppressing sounds from other directions to help people focus on conversations when they are surrounded by background noise.
Board certified hearing aid specialist since 2007, graduate of Emory University. Member of Georgia Society of Hearing Professionals, Rabun County Chamber of Commerce, and the Clayton Merchants Association.
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