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Our Clever Country

The Bionic Ear

Wired for sound

Great Australian science is helping deaf people to hear all over the world.

What’s the problem?

About 120 million people around the world and about 1 million Australians have some degree of hearing loss. Of those 1 million Australians, 20 000 are profoundly deaf, that is they hear NO sound from the outside world, and more than 50 000 are severely deaf. Three in every 1000 children are born with a hearing loss or lose some hearing before learing to speak. This makes speech very difficult.

The reason that deafness is such a common condition is that our hearing apparatus is very delicate. Corrective surgery and hearing aids can improve some forms of deafness but usually not profound deafness caused by inner ear damage.

A great Aussie solution

Cochlear’s Nucleus 3G ear implant

Image courtesy Cochlear Ltd

‘Can you hear me?’ This is often the first question heard by recipients of a cochlear implant (or ‘bionic’ ear)... simple but very exciting words if you have never heard anyone speak before!

More than 24 000 severely deaf or profoundly deaf people in 50 countries have received a cochlear implant. They all owe their new hearing to technology first developed by Australian scientist Professor Graeme Clark and his colleagues at the University of Melbourne in the late 1960s and 1970s. Australian scientists have continued to be world leaders in hearing technology and the Australian cochlear implant is continually being upgraded.

The cochlear implant replaces the function of the entire ear by directly stimulating the hearing nerves with electrical impulses to produce the same effect as sound.

How does it work?

The cochlear implant consists of an internal (the bit implanted under the skin behind the ear) and an external component which can be worn like a standard hearing aid or tucked away in the person's pocket. So how do these bits work together to produce sound for deaf people?

Speech and other sounds are picked up by a microphone and sent to the speech processor.
The processor codes the sounds into an elecrical signal, which is sent to the transmitting coil.
The coil passes the signal through the skin to the implant, which transforms the signal to electrical impulses.
The electrical pulses pass from the electrode array to stimulate the hearing nerve.
The brain recognises the nerve stimulation as sound!

The future

The cochlear implant relies on stimulating the 20 000 auditory nerve fibres through 22 electrodes. Current research is investigating ways to increase the amount of imformation provided by miniaturised advanced electrode designs and stimulation that more closely mimics the normal auditory system.

The importance of CRC research was highlighted when the Nucleus 24 Contour Electrode was awarded the 1999 Australian Design Award of the Year. The award judges said the Contour was ‘an outstanding example of Australian innovative design and development which makes a major contribution to improving people's quality of life around the world’.

Further info, facts and fun

An Australian man, who became profoundly deaf after a head injury, was the world’s first recipient in 1978. He regained partial hearing and the sound barrier was broken!
More than 80% of the world's cochlear implant patients use technology manufactured in Australia.
Australia has a strong history of excellence in medical research. Another revolutionary technology to do with sound (that no humans can hear), developed in the 1960s is ‘ultrsound imaging’. Widely used in medicine to examine organs and unborn babies, ultrasound technology is now being used to help people with poor vision find their way around.
Sound is produced by vibrating objects that genrate pressure or sound sound waves. The faster the vibrations (or the higher the frequncy of vibrations) the higher the sound. Try this with a ruler sticking out over the edge of a table. When there is just a small amount of ruler hanging off the table and you flick it, it vibrates very quickly (has high frequency) and produces a higher sound. When you sing a high note your vocal chords are vibrating more quickly than when you sing a low note.
CRC for Cochlear Implant & Hearing Innovation http://www.medoto.unimelb.edu.au

For more info on great Australian Science check out:

CSIRO’s Australia Advances http://www.csiro.au/promos/ozadvances
The Australian Academy of Science’s Nova http://www.science.org.au/nova
The Australian Science Archive Project http://www.asap.unimelb.edu.au/

Printable version (pdf)


	Questacon > Kids > Exhibitions & Shows > The Archives > Our Clever Country > Bionic Ear Our Clever Country The Bionic Ear Wired for sound Great Australian science is helping deaf people to hear all over the world. What’s the problem? About 120 million people around the world and about 1 million Australians have some degree of hearing loss. Of those 1 million Australians, 20 000 are profoundly deaf, that is they hear NO sound from the outside world, and more than 50 000 are severely deaf. Three in every 1000 children are born with a hearing loss or lose some hearing before learing to speak. This makes speech very difficult. The reason that deafness is such a common condition is that our hearing apparatus is very delicate. Corrective surgery and hearing aids can improve some forms of deafness but usually not profound deafness caused by inner ear damage. A great Aussie solution Cochlear’s Nucleus 3G ear implant Image courtesy Cochlear Ltd ‘Can you hear me?’ This is often the first question heard by recipients of a cochlear implant (or ‘bionic’ ear)... simple but very exciting words if you have never heard anyone speak before! More than 24 000 severely deaf or profoundly deaf people in 50 countries have received a cochlear implant. They all owe their new hearing to technology first developed by Australian scientist Professor Graeme Clark and his colleagues at the University of Melbourne in the late 1960s and 1970s. Australian scientists have continued to be world leaders in hearing technology and the Australian cochlear implant is continually being upgraded. The cochlear implant replaces the function of the entire ear by directly stimulating the hearing nerves with electrical impulses to produce the same effect as sound. How does it work? The cochlear implant consists of an internal (the bit implanted under the skin behind the ear) and an external component which can be worn like a standard hearing aid or tucked away in the person's pocket. So how do these bits work together to produce sound for deaf people? Speech and other sounds are picked up by a microphone and sent to the speech processor. The processor codes the sounds into an elecrical signal, which is sent to the transmitting coil. The coil passes the signal through the skin to the implant, which transforms the signal to electrical impulses. The electrical pulses pass from the electrode array to stimulate the hearing nerve. The brain recognises the nerve stimulation as sound! The future The cochlear implant relies on stimulating the 20 000 auditory nerve fibres through 22 electrodes. Current research is investigating ways to increase the amount of imformation provided by miniaturised advanced electrode designs and stimulation that more closely mimics the normal auditory system. The importance of CRC research was highlighted when the Nucleus 24 Contour Electrode was awarded the 1999 Australian Design Award of the Year. The award judges said the Contour was ‘an outstanding example of Australian innovative design and development which makes a major contribution to improving people's quality of life around the world’. Further info, facts and fun An Australian man, who became profoundly deaf after a head injury, was the world’s first recipient in 1978. He regained partial hearing and the sound barrier was broken! More than 80% of the world's cochlear implant patients use technology manufactured in Australia. Australia has a strong history of excellence in medical research. Another revolutionary technology to do with sound (that no humans can hear), developed in the 1960s is ‘ultrsound imaging’. Widely used in medicine to examine organs and unborn babies, ultrasound technology is now being used to help people with poor vision find their way around. Sound is produced by vibrating objects that genrate pressure or sound sound waves. The faster the vibrations (or the higher the frequncy of vibrations) the higher the sound. Try this with a ruler sticking out over the edge of a table. When there is just a small amount of ruler hanging off the table and you flick it, it vibrates very quickly (has high frequency) and produces a higher sound. When you sing a high note your vocal chords are vibrating more quickly than when you sing a low note. CRC for Cochlear Implant & Hearing Innovation http://www.medoto.unimelb.edu.au For more info on great Australian Science check out: CSIRO’s Australia Advances http://www.csiro.au/promos/ozadvances The Australian Academy of Science’s Nova http://www.science.org.au/nova The Australian Science Archive Project http://www.asap.unimelb.edu.au/ Printable version (pdf)
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