A cochlear implant (CI) is a surgically implanted electronic device that provides a sense of sound to a person who is profoundly deaf or severely hard of hearing in both ears; as of 2014 they had been used experimentally in some people who had acquired deafness in one ear after learning how to speak. Cochlear implants bypass the normal hearing process; they have a sound processor that resides on the outside of the skin (and generally worn behind the ear) which contains microphones, electronics, battery, and a coil which transmits a signal to the implant. The implant has a coil to receive signals, electronics, and an array of electrodes which is placed into the cochlea, which stimulate the cochlear nerve.
The procedure in which the device is implanted is usually done under general anesthesia. Risks of the procedures include mastoiditis, otitis media (acute or with effusion), shifting of the implanted device requiring a second procedure, damage to the facial nerve, damage to the chorda tympani, and wound infections. People may experience problems with dizziness and balance for up to a few months after the procedure; these problems generally resolve, but for people over 70, they tend not to.
There is low to moderate quality evidence that when CIs are implanted in both ears at the same time, they improve hearing in noisy places for people with severe loss of hearing. There is significant evidence that implanting CIs to improve hearing may also improve tinnitus.
There is controversy around the devices; much of the strongest objection to cochlear implants has come from the Deaf community. For some in the deaf community, cochlear implants are an affront to their culture, which as some view it, is a minority threatened by the hearing majority.
Video Cochlear implant
History
The first cochlear implant was invented by Dr. William House, in 1961. In 1964, Blair Simmons and Robert J. White implanted a six channel electrode in a patient's cochlea at Stanford University.
The modern multichannel cochlear implant was independently developed and commercialized by Graeme Clark from Australia and Ingeborg Hochmair and her future husband, Erwin Hochmair, with the Hochmairs' first implanted in a person in December 1977 and Clark's in August 1978.
Maps Cochlear implant
Parts
Cochlear implants bypass most of the peripheral auditory system which receives sound and converts that sound into movements of stereocilia on hair cells in the cochlea; The movement of the stereocilia causes in influx of potassium ions that stimulates the hair cells cells to release the neurotransmitter glutamate, which makes the cochlear nerve send signals to the brain, which creates the experience of sound. Instead, the devices pick up sound and digitize it, convert that digitized sound into electrical signals, and transmit those signals to electrodes embedded in the cochlea. The electrodes electrically stimulate the cochlear nerve, causing it to send signals to the brain.
There are several systems available, but generally they have the following components:
- External
- one or more microphones that pick up sound from the environment
- a speech processor which selectively filters sound to prioritize audible speech
- a transmitter that sends power and the processed sound signals across the skin to the internal device by electromagnetic induction,
- Internal:
- a receiver/stimulator, which receives signals from the speech processor and converts them into electric impulses.
- an electrode array embedded in the cochlea
Surgical procedure
The surgical procedure most often used to implant the device is called mastoidectomy with facial recess approach (MFRA). If a person's individual anatomy prevents MFRA, other approaches, such as through the suprameatal triangle are used. A systematic literature review published in 2016 found that studies comparing the two approaches were generally small, not randomized, and retrospective so were not useful for making generalizations; it is not known which approach is safer or more effective.
The procedure is usually done under general anesthesia. Risks of the procedures include mastoiditis, otitis media (acute or with effusion), shifting of the implanted device requiring a second procedure, damage to the facial nerve, damage to the chorda tympani, and wound infections.
The rate of complications is about 12% for minor complications and 3% for major complications; major complications include infections, facial paralysis, and device failure. To avoid the risk of bacterial meningitis, which while low is about thirty times as high compared to people who don't undergo CI procedures, the FDA recommends vaccination prior to the procedure. The rate of transient facial nerve palsy is estimated to be approximately 1%. Device failure requiring reimplantation is estimated to occur in 2.5-6% of the time. Up to one-third of people experience disequilibrium, vertigo, or vestibular weakness lasting more than 1 week after the procedure; in people under 70 these symptoms generally resolve over weeks to months, but in people over 70 the problems tend to persist.
Cochlear implants are only approved for people who are deaf in both ears; as of 2014 a cochlear implant had been used experimentally in some people who had acquired deafness in one ear after they had learned how to speak, and none who were deaf in one ear from birth; clinical studies as of 2014 had been too small to draw generalizations from.
Efficiency
A 2011 AHRQ review of the evidence of the effectiveness of CI in people with bilateral hearing loss - the device's primary use - found low to moderate quality data that showed: speech perception in noisy conditions was much better for people who had implants in both ears done at the same time, compared to people who had only one; that no conclusions could be drawn about changes in speech perception in quiet conditions and health-related quality-of-life. There was only one good study comparing implanting implants in both ears at the same time, to implanting them sequentially; this study found that in the sequential approach, the 2nd implantation made no change, or made things worse.
A 2012 review found that the ability to communicate in spoken language was better, the earlier the implantation was done; it also found that overall, the efficacy of cochlear implants is highly variable, and that it was not possible to accurately predict which children will and will not acquire spoken language successfully.
A 2015 review, examining whether CI implantation to treat people with bilateral hearing loss had any effect on tinnitus, found the quality of evidence to be poor, and the results variable: overall total tinnitus suppression rates varied from 8% to 45% of people who received CI; decrease of tinnitus was seen in 25% to 72%, of people; for 0% to 36% of the people there was no change; increase of tinnitus occurred in between 0% to 25% of patients; and in between 0 - 10% of cases, people who didn't have tinnitus before the procedure, got it.
A 2016 systematic review of CI for people with unilateral hearing loss found that of the studies conducted and published, none were randomized, only one evaluated a control group, and no study was blinded; after eliminating multiple uses of the same subjects, the authors found that 137 people with UHL had received a CI. While acknowledging the weakness of the data, the authors found that CI in people with UHL improves sound localization compared with other treatments in people who lost hearing after they learned to speak; in the one study that examined this, CI did improve sound localization in people with UHL who lost hearing before learning to speak. It appeared to improve speech perception and to reduce tinnitus.
A 2015 literature review on the use of CI for people with auditory neuropathy spectrum disorder found that description and diagnosis of the condition was too heterogeneous as of that date, to make clear claims about whether CI is a safe and effective way to manage it.
Society and culture
Usage
As of December 2012, approximately 324,000 cochlear implant devices had been surgically implanted. In the U.S., roughly 58,000 devices were implanted in adults and 38,000 in children.
Cost
In the United States, the overall cost of getting cochlear implants was about $100,000 as of 2017. Some or all of this may be covered by health insurance. In the United Kingdom, the NHS covers cochlear implants in full, as does Medicare in Australia, and the Department of Health in Ireland, Seguridad Social in Spain and Israel, and the Ministry of Health or ACC (depending on the cause of deafness) in New Zealand. According to the US National Institute on Deafness and Other Communication Disorders, the estimated total cost is $60,000 per person implanted.
A study by Johns Hopkins University determined that for a three-year-old child who receives them, cochlear implants can save $30,000 to $50,000 in special-education costs for elementary and secondary schools as the child is more likely to be mainstreamed in school and thus use fewer support services than similarly deaf children.
Manufacturers
As of 2013, the three cochlear implant devices approved for use in the U.S. were manufactured by Cochlear Limited (Australia), Advanced Bionics (USA, a division of Sonova) and MED-EL (Austria). In Europe, Africa, Asia, South America, and Canada, an additional device manufactured by Neurelec (France, a division of William Demant) was available. A device made by Nurotron (China) was also available in some parts of the world. Each manufacturer has adapted some of the successful innovations of the other companies to its own devices. There is no consensus that any one of these implants is superior to the others. Users of all devices report a wide range of performance after implantation.
Criticism and controversy
Much of the strongest objection to cochlear implants has come from within the Deaf community, some of whom are pre-lingually deaf people whose first language is a sign language. For some in the Deaf community, cochlear implants are an affront to their culture, which, as they view it, is a minority threatened by the hearing majority. This is an old problem for the deaf community, going back as far as the 18th century with the argument of manualism vs. oralism. This is consistent with medicalisation and the standardisation of the 'normal' body in the 19th century, when differences between normal and abnormal began to be debated. It is important to consider the sociocultural context, particularly in regards to the Deaf community, which considers itself to possess its own unique language and culture. This accounts for the cochlear implant being seen as an affront to their culture, as many do not believe that deafness is something that needs to be cured. However, it has also been argued that this does not necessarily have to be the case: the cochlear implant can act as a tool Deaf people can use to access the 'hearing world' without losing their Deaf identity.
Cochlear implants for congenitally deaf children are considered to be most effective when implanted at a young age, during the critical period in which the brain is still learning to interpret sound. Hence they are implanted before the recipients can decide for themselves, on the assumption that deafness is a disability. Deaf culture critics argue that the cochlear implant and the subsequent therapy often become the focus of the child's identity at the expense of a possible future deaf identity and ease of communication in sign language, and claim that measuring the child's success only by their mastery of hearing and speech will lead to a poor self-image as "disabled" (because the implants do not produce normal hearing) rather than having the healthy self-concept of a proudly deaf person.
Children with cochlear implants are more likely to be educated orally, in the standard fashion, and without access to sign language and are often isolated from other deaf children and from sign language. Cochlear implants have been one of the technological and social factors implicated in the decline of sign languages in the developed world. Some of the more extreme responses from Deaf activists have labeled the widespread implantation of children as "cultural genocide".
As the trend for cochlear implants in children grows, deaf-community advocates have tried to counter the "either or" formulation of oralism vs manualism with a "both and" approach; some schools are now successfully integrating cochlear implants with sign language in their educational programs.
See also
- Auditory brainstem response
- Auditory brainstem implant
- Bone-anchored hearing aid
- Bone conduction
- Brain implant
- Ear trumpet
- Electric acoustic stimulation
- Electrophonic hearing
- Hearing Aid
- Neuroprosthetics
- Noise health effects
- Visual prosthesis
- Language deprivation § Deaf and Hard of Hearing Children
References
External links
- Cochlear Implants at Curlie (based on DMOZ)
- What is it like to live with a cochlear implant? A short documentary video clip
- What do cochlear implants sound like? An audio example
- Cochlear Implants Information from the National Institutes of Health (NIH).
- NASA Spinoff article on engineer Adam Kissiah's contribution to cochlear implants beginning in the 1970s.
- Wilson, Blake S.; Finley, Charles C.; Lawson, Dewey T.; Wolford, Robert D.; Eddington, Donald K.; Rabinowitz, William M. (1991). "Better speech recognition with cochlear implants". Nature. 352 (6332): 236-8. Bibcode:1991Natur.352..236W. doi:10.1038/352236a0. PMID 1857418.
- NPR Story about improvements to improve the processing of music. Includes simulations of what someone with implants might hear.
- More recent NPR Story about improvements to improve the processing of music. Includes updated simulations of music, before and after these updates.
- Tuning In PBS article about advances in cochlear implant technology with simulations of what someone with each type of implant would hear.
- My Bionic Quest for Boléro (Wired, November 2005): Author Michael Chorost writes about his own implant and trying the latest software from researchers in a quest to hear music better.
- Charles Limb, "Building the musical muscle", TEDMED 2011, October 2011
Source of the article : Wikipedia