MERGING HEARING TECHNOLOGIES SOUNDS GOOD TO RESEARCHER
WEST LAFAYETTE, Ind. - A Purdue University researcher is combining two technologies - hearing aids and cochlear implants - to help improve
speech understanding and sound quality for cochlear implant users. Research by King Chung, an assistant professor in audiology, and
colleagues shows that by applying advanced hearing aid technologies, such as preprocessors, to cochlear implants, background noise can be
reduced, speech understanding enhanced and sound quality improved for cochlear implant users. Chung collaborated with Fan-Gang Zeng, a
professor at the University of California, and Susan Waltzman, a professor at New York University School of Medicine.
"The common goals of hearing aids and cochlear implants are to enhance users' speech understanding and listening comfort, as well as improve
the convenience of device use," says Chung, who studies issues related to hearing amplification and communication. "To achieve these goals,
hearing aid and cochlear implant manufacturers have gone through different research and development paths."
Hearing aid technologies, many of which are not available in cochlear implants, are more advanced in reducing different types of background
noises and increasing the convenience of hearing aid use, Chung says. Cochlear implant technologies have advanced in coding strategies,
miniaturization of the speech processor and electrode mechanics.
"Our study shows that by combining these two technologies, cochlear implant users can understand speech better and be more comfortable when
they listen in background noise," she says. "Cochlear implant users also prefer the conditions in which advanced hearing aid technologies
were applied as a preprocessor to their cochlear implants."
The research is published in the current issue of Acoustic Research Letters Online. Chung and her co-authors will present their findings in
May at the European Symposium in Pediatric Cochlear Implants in Geneva, Switzerland, and at the International Cochlear Implant Conference in
Indianapolis.
Approximately 10 percent of the country's population suffers from hearing impairment, and the number is expected to grow as the
population ages. Hearing aids are the most common remedy for people with hearing impairments, Chung says. Hearing aids have microphones to
pick up sounds, then processors send the signals to the ear canal and through the auditory nerve to the brain for interpretation.
People with severe hearing loss may choose to use cochlear implants. There are more than 60,000 people worldwide with these implants, which
work by providing direct electrical simulation to the auditory nerve. The microphone, speech processor and transmitter are placed on the
outside of the ear similar to a hearing aid. The microphone picks up sounds from the environment so the speech processor can process and
encode the incoming signal. Then, the transmitter sends the signal to a receiver implanted under the skin of the skull and to electrodes
implanted in the inner ear. The electrodes directly stimulate the auditory nerve and the signal is sent to the brain for interpretation.
The two devices' main differences lie in how they send sound through our auditory system, Chung says. Hearing aids output acoustic signals
to the ear canal. Cochlear implants, on the other hand, convert those acoustic signals into electronic impulses and directly stimulate the
auditory nerve.
"There are many advanced hearing aid technologies that may help cochlear implant users," Chung says. "For example, hearing aids have
adaptive directional microphones that can automatically track the direction of the background noise and maximally reduce the noise
interference even if the noise is moving in the environment. Most cochlear implants do not use these advanced directional microphone
technologies and, if they do, it is usually in a less sophisticated form.
"In addition, hearing aids have switchless telephone coils, so when a person talks on the phone, the hearing aid detects the magnetic field
of the telephone headset and automatically switches to telecoil input, which does not pick up the background noise. Some children and older
people with weak hands may not be able to manually switch back and forth from microphone to telecoil inputs with their cochlear implants.
If advanced hearing aid technologies are used as preprocessors to cochlear implant speech processors, cochlear implant users may be able
to take advantage of all these features."
Chung and her colleagues evaluated if hearing-aid technologies could help people with cochlear implants improve their speech understanding,
especially in noisy environments.
Twelve subjects -four with normal hearing, four with hearing aids and four with cochlear implants - listened to prerecorded material that had
been processed by hearing aids. The first prerecorded sounds were processed through a hearing aid with an omni-directional microphone,
which picks up sounds from all directions. The second sets of recordings came from the same hearing aids programmed to directional
microphones, which are more sensitive to sounds in front of the hearing aid user. The third sets of recordings combined directional microphones
with noise-reduction algorithms. The noise-reduction algorithms are intended to reduce noise interference.
Participants were asked to repeat the processed words and to rank the ease of listening for each of the experimental conditions.
The average improvement on speech understanding for cochlear implant users, hearing aid users and people with normal hearing using the
directional microphones were 11.7 percent, 21.5 percent and 23.7 percent, respectively. There were no differences in speech
understanding between the directional microphone condition and the directional microphone plus noise-reduction algorithm condition. All
subjects ranked omni-directional as the most difficult, and all but two participants with normal hearing identified the directional microphone
plus noise-reduction algorithms as the easiest to listen to.
"This research is still in the preliminary stage, and we will continue to investigate the effects of applying different types of hearing aid
technologies to cochlear implant users," Chung says. "We also will explore different methods to integrate these technologies. The
advantage of this marriage of hearing aid and cochlear implant technologies may ensure timely delivery of advanced hearing aid
technologies to cochlear implant users. In addition, the two industries may be able to combine resources to develop the next generation of
signal processing technologies that can benefit both hearing aid and cochlear implants users."
Chung is now working on a similar study with a larger sample size and a new study with adaptive directional microphones. The latter is
supported by a New Investigators Grant from the American Academy of Audiology.
Purdue's Department of Audiology and Speech Sciences is ranked among the top 10 in the nation by U.S.News & World Report. The master's and
doctoral degree program in speech-language pathology and audiology are ranked third and eighth, respectively,
Writer: Amy Patterson-Neubert, (765) 494-9723, apatterson@purdue.edu
Source: King Chung, (765) 494-0402, kingchung@purdue.edu
Related Web sites:
Audiology and Speech Sciences http://www.sla.purdue.edu/academic/aus/
Chung's journal article: http://scitation.aip.org/dbt/dbt.jsp?KEY=ARLOFJ&Volume=5&Issue=2
PHOTO CAPTION:
King Chung, assistant professor of audiology, sets up for her next experiment in the Amplification and Communication Research Laboratory
at Purdue University. She will evaluate how hearing-aid technologies can improve the efficiency of cochlear implants. Chung's current
research shows that by applying the front-end processing capability of hearing aids to cochlear implants, cochlear implant users achieved
better listening quality. Chung's research findings are published in the current issue of Acoustic Research Letters Online. (Purdue News
Service photo/David Umberger)
A publication-quality photo is available at
http://ftp.purdue.edu/pub/uns/+2004/chung-dummy.jpg
ABSTRACT
Using hearing aid directional microphones and noise reduction algorithms to enhance cochlear implant performance
King Chung, Fan-Gang Zeng, and Susan Waltzman
Hearing aids and cochlear implants are two major hearing enhancement technologies but yet share little in research and development. The
purpose of this study was to determine whether hearing aid directional microphones and noise-reduction technologies could enhance cochlear
implant users' speech understanding and ease of listening. Digital hearing aids serving as preprocessors were programmed to
omni-directional microphone, directional microphone, and directional microphone plus noise reduction conditions. Three groups of subjects
were tested with the hearing aid processed speech stimuli. Results indicated that hearing aids with directional microphones and noise
reduction algorithms significantly enhanced speech understanding and listening comfort.
