Jump to content

Unilateral hearing loss

From Wikipedia, the free encyclopedia
(Redirected from Single sided deafness)
Unilateral hearing loss
Other namesSingle-sided deafness (SSD)
SpecialtyAudiology, ear, nose, and throat

Unilateral hearing loss (UHL) is a type of hearing impairment where there is normal hearing in one ear and impaired hearing in the other ear.

Signs and symptoms

[edit]

Patients with unilateral hearing loss have difficulty:

  • Hearing conversation on their impaired side
  • Localizing sound
  • Understanding speech in the presence of background noise
  • In interpersonal interaction in social settings
  • Focusing on individual sound sources in large, open environments
  • Heavy impairment of the auditory Figure–ground perception

In quiet conditions, speech discrimination is no worse than normal hearing in those with partial deafness;[1] however, in noisy environments speech discrimination is almost always severe.[1][2]

The prevalence is 3–8.3% of the population.[3] Individuals who are diagnosed with Single Sided Deafness have difficulties with sound localization and speech in noise discrimination.[3] Children with SSD are more likely to experience developmental delays- school, speech, behavioral problems.[3]

Causes

[edit]

Known causes include genetics, maternal illness and injury. Examples of these causes are physical trauma, acoustic neuroma, maternal prenatal illness such as measles, labyrinthitis, microtia, meningitis, Ménière's disease, Waardenburg syndrome, mumps (epidemic parotitis),mastoiditis or due to an overstrained nervus vestibulocochlearis after a brain surgery to close to the nerve.

SSD's most severe form of unilateral hearing loss is caused by: sudden sensorineural hearing loss (SSNHL), acoustic neuroma, anomalies inner ear abnormalities, cochlear nerve deficiency (CND), mumps, congenital cytomegalovirus (CMV) infection, meningitis and auditory neuropathy spectrum disorder (ANSD) treatment is based on the cause of the hearing loss. Limited treatment when the cause is the Central auditory system or Auditory nerve.[4]

Prevalence

[edit]

A 1998 study of schoolchildren found that per thousand, 6–12 had some form of unilateral hearing loss and 0–5 had moderate to profound unilateral hearing loss. It was estimated that in 1998 some 391,000 school-aged children in the United States had unilateral hearing loss.[5]

Profound unilateral hearing loss

[edit]

Profound unilateral hearing loss is a specific type of hearing loss when one ear has no functional hearing ability (91 dB or greater hearing loss). People with profound unilateral hearing loss can only hear in monaural (mono).

Profound unilateral hearing loss or single-sided deafness, SSD, makes hearing comprehension very difficult. With speech and background noise presented at the same level, persons with unilateral deafness were found to listen only about 30–35% of the conversation.[6] A person with SSD needs to make more effort when communicating with others.[7] When a patient can hear from only one ear, and there are limited possibilities to compensate for the disability, e.g., changing listening position, group discussions and dynamic listening situations become difficult. Individuals with profound unilateral hearing loss are often perceived as socially awkward due to constant attempts to maximize hearing leading to socially unique body language and mannerisms.[8]

UHL also negatively affects hearing and comprehension by making it impossible for the patient to determine the direction, distance and movement of sound sources.[8] In an evaluation using the Speech, Spatial and Qualities of Hearing Scale (SSQ) questionnaire, SSD results in a greater handicap than subjects with a severe hearing loss in both ears.

Profound SSD is often confused with sensory discrimination disorder (SDD), a type of sensory processing disorder, and can lead to incorrect processing of sensory information or auditory input during interpersonal communications.

Profound unilateral hearing loss is known to cause:

  • Irritability
  • Sound aversion: any presence of noise, no matter how low
  • Body language and mannerisms which appear socially awkward or unusual, like staring at others mouths or tilt the head frequently
  • Frequent headaches, stress
  • Social isolation
  • Chronic interpersonal communication difficulties due to inability of brain to isolate or beam form sounds and voices of other individuals
  • Appearance of anxiousness even in low noise situations
  • Jumpiness
  • Trouble figuring out where sounds are coming from.
  • Variable light dizziness
  • Trouble paying attention to what people are saying: "evasive" behaviour.
  • Misdiagnoses as ADHD
  • Seeming lack of awareness of other people's personal space and moods since brain is hyper-focused on deciphering auditory information in lieu of non-verbal social cues.
  • Lack of sound depth: any background noise (in the room, in the car) is flat and wrongly interpreted by the brain. The effect is similar to what happens when trying to hear someone speaking in a noisy crowd on a mono recording. The effect is also similar to talking on the phone to someone who is in a noisy environment (see also: King-Kopetzky syndrome)
  • Inability to filter out background noise or selectively listen to only the important portion of the noise in the environment.
  • For sensorineural hearing loss, the lack of input coming from the damaged sensory apparatus can cause "ghost beeps" or ringing/tinnitus as the brain attempts to interpret the now missing sensory data. The frequency and the volume of the noise can increase according to one's physical condition (stress, fatigue, etc.). This can aggravate social problems and increase the difficulty of speech comprehension.
  • Talking loudly or "broadcasting": the affected person cannot perceive the volume of their voice relative to other people in the same room or close company, resulting in being characterized by others (who may be located beyond normal auditory range) as domineering or boorish

Treatment

[edit]

Several hearing devices have been shown to benefit individuals with unilateral hearing loss.

Contralateral Routing of Signals (CROS) hearing aids are hearing aids that take sound from the ear with poorer hearing and transmit to the ear with better hearing. They consist of a microphone placed near the impaired ear and an amplifier (hearing aid) near the normal ear. The two units are connected either by a wire behind the neck or by wireless transmission. The aid appears as two behind-the-ear hearing aids and is sometimes incorporated into eyeglasses.[9]

Bone Anchored Hearing Aids (BAHAs) are bone conduction devices that are surgically implanted into the mastoid bone, with an abutment protruding through the skin. The external hearing aid clicks onto the abutment and uses bone conduction to transmit sound to the cochlea of the normal hearing ear. The external component can also be attached to a headband or softband and used as a non-surgical device.[10]

The BONEBRIDGE bone conduction implant is surgically implanted into the mastoid bone completely underneath the skin. The audio processor is worn externally and held in place by magnets. It sends sound as electrical signals through the skin to the implant. The implant then sends sound vibrations to the cochlea of the normal hearing ear through the skull via bone conduction.[11]

The ADHEAR bone conduction system is a non-surgical device that sticks to the skin behind the ear. It vibrates to send sound vibrations through the skin and the skull bone to the cochlea of the normal hearing ear.[12]

The SoundBite intraoral bone conduction system used bone conduction via the teeth. One component resembled a conventional behind-the-ear hearing aid that wirelessly connects to a second component worn in the mouth that resembles a conventional dental appliance. The device was discontinued in 2015 and is no longer available.[13]

A cochlear implant can also be used to treat unilateral hearing loss in many countries.  The device is surgically implanted in the cochlea of non-hearing ear, with a sound processor worn externally.  Using electrical stimulation of the cochlea, sound is sent to the hearing nerve and onto the brain.[14]

Evaluation

[edit]

According to Snapp 2019, CROS technology solutions provide a noninvasive, aesthetically appealing, low-cost option for individuals with single sided deafness (SSD). The primary benefits of a CROS hearing devices are improved sound awareness from the impaired side and better hearing in noise when speech is located on the impaired side. However, CROS solutions do not provide restoration of binaural hearing and cannot improve tasks requiring binaural input, such as localization.[15]

One study of the BAHA system showed a benefit depending on the patient's transcranial attenuation.[16] Another study showed that sound localization was not improved, but the effect of the head shadow was reduced. The BAHA system has been shown to have higher patient satisfaction and greater perceived benefit by users than the CROS system.[17]

The BONEBRIDGE system has been shown to provide good hearing outcomes, and patients also reported high subjective benefit.[18] The device has been shown to decrease the head shadow effect.[19] Sprinzl et al. (2016) also found that the BONEBRIDGE system had a lower complication rate when compared to other implanted bone conduction devices.[20]

Studies of the ADHEAR system have shown that patients report higher comfort satisfaction and longer daily wearing times compared to the BAHA system with a headband or softband, due to the lack of pressure on the skin.[21] Better outcomes compared to CROS hearing aids have also been reported.[22]

Studies on the SoundBite system showed it to have strong hearing benefit and high patient satisfaction, particularly due to its non-surgical design. Some users reported acoustic feedback from the device.[23]

Cochlear implants (CIs) have been shown to benefit patients with unilateral hearing loss in terms of tinnitus reduction, localization, speech understanding, and quality of life (QoL).[24] The increased ability to locate sounds is explained by the fact that, unlike with the other treatments available, treating unilateral hearing loss with a cochlear implant results in both cochleae being stimulated, which helps the brain to better decipher the location of the sound. However, patients may still have difficulties at frontal locations and on the CI side.[25]

Other Hearing issues

[edit]

School-age children with unilateral hearing loss tend to have poorer grades and require educational assistance. This is not the case with everyone, however. They can also be perceived to have behavioral issues.[26]

People affected by UHL have great difficulty locating the source of any sound. They may be unable to locate an alarm or a ringing telephone. The swimming game Marco Polo is generally impossible for them.

When wearing stereo headphones, people with unilateral hearing loss can hear only one channel, hence the panning information (volume and time differences between channels) is lost; some instruments may be heard better than others if they are mixed predominantly to one channel, and in extreme cases of sound production, such as complete stereo separation or stereo-switching, only part of the composition can be heard; in games using 3D audio effects, sound may not be perceived appropriately due to coming to the disabled ear. This can be corrected by using settings in the software or hardware—audio player, OS, amplifier or sound source—to adjust balance to one channel (only if the setting downmixes sound from both channels to one), or there may be an option to outright downmix both channels to mono. Such settings may be available via the device or software's accessibility features.[27][28]

See also

[edit]

References

[edit]
  1. ^ a b Sargent EW, Herrmann B, Hollenbeak CS, Bankaitis AE (July 2001). "The minimum speech test battery in profound unilateral hearing loss". Otol. Neurotol. 22 (4): 480–6. doi:10.1097/00129492-200107000-00012. PMID 11449104. S2CID 37980161.
  2. ^ Welsh LW, Welsh JJ, Rosen LF, Dragonette JE (December 2004). "Functional impairments due to unilateral deafness". Ann. Otol. Rhinol. Laryngol. 113 (12): 987–93. doi:10.1177/000348940411301209. PMID 15633902. S2CID 3218109.
  3. ^ a b c Sharma, Anu; Glick, Hannah; Campbell, Julia; Torres, Jennifer; Dorman, Michael; Zeitler, Daniel M. (2016). "Cortical Plasticity and Re-organization in Pediatric Single-Sided Deafness Pre- and Post- Cochlear Implantation: A Case Study". Otology & Neurotology. 37 (2): e26–e34. doi:10.1097/MAO.0000000000000904. PMC 6530986. PMID 26756152.
  4. ^ Usami, Shin-ichi; Kitoh, Ryosuke; Moteki, Hideaki; Nishio, Shin-ya; Kitano, Tomohiro; Kobayashi, Masafumi; Shinagawa, Jun; Yokota, Yoh; Sugiyama, Kenjiro; Watanabe, Kizuki (April 2017). "Etiology of single-sided deafness and asymmetrical hearing loss". Acta Oto-Laryngologica. 137 (sup565): S2–S7. doi:10.1080/00016489.2017.1300321. PMID 28366032.
  5. ^ Lee DJ, Gómez-Marín O, Lee HM (August 1998). "Prevalence of unilateral hearing loss in children: the National Health and Nutrition Examination Survey II and the Hispanic Health and Nutrition Examination Survey". Ear Hear. 19 (4): 329–32. doi:10.1097/00003446-199808000-00008. PMID 9728728. S2CID 9790680.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  6. ^ Christensen L, Richter GT, Dornhoffer JL (Feb 2010). "Update on bone-anchored hearing aids in pediatric patients with profound unilateral sensorineural hearing loss". Archives of Otolaryngology–Head & Neck Surgery. 136 (2): 175–7. doi:10.1001/archoto.2009.203. PMID 20157065.
  7. ^ Bess FH, Tharpe AM (February 1986). "An introduction to unilateral sensorineural hearing loss in children". Ear Hear. 7 (1): 3–13. doi:10.1097/00003446-198602000-00003. PMID 3512353. S2CID 46695863.
  8. ^ a b Noble W, Gatehouse S (2004). "Interaural asymmetry of hearing loss, Speech, Spatial and Qualities of Hearing Scale (SSQ) disabilities, and handicap". International Journal of Audiology. 43 (2): 100–14. doi:10.1080/14992020400050015. PMID 15035562. S2CID 11541363.
  9. ^ "CROS and BiCROS Hearing Aids". hear.com. Retrieved 2022-02-07.
  10. ^ "Bone-anchored hearing systems: What you need to know". Healthy Hearing. Retrieved 2022-02-07.
  11. ^ "Bonebridge, Medel". Ears & Hearing UK. Retrieved 2022-02-07.
  12. ^ Douglas, Amanda O'Donnell,Uta Stewart,Charlotte. "ADHEAR System by MED-EL: An Overview of the Research and Clinical Experiences from the Field Amanda O'Donnell Uta Stewart Charlotte Douglas". AudiologyOnline. Retrieved 2022-02-07.{{cite web}}: CS1 maint: multiple names: authors list (link)
  13. ^ "Soundbite Re-emerges as 'Molar Mic', a Military/Rescue Communication Device | The Hearing Review – a MEDQOR brand". hearingreview.com. 12 September 2018. Retrieved 2022-02-07.
  14. ^ Kornak, Jillian (2019-08-22). "FDA Approves Cochlear Implants for Single-Sided Deafness, Asymmetric Hearing Loss". Leader Live. doi:10.1044/fda-approves-cochlear-implants-for-single-sided-deafness-asymmetric-hearing-loss. S2CID 230425292.
  15. ^ Snapp, Hillary (April 2019). "Nonsurgical Management of Single-Sided Deafness: Contralateral Routing of Signal". Journal of Neurological Surgery. Part B, Skull Base. 80 (2): 132–138. doi:10.1055/s-0039-1677687. ISSN 2193-6331. PMC 6438788. PMID 30931220.
  16. ^ Stenfelt S (March 2005). "Bilateral fitting of BAHAs and BAHA fitted in unilateral deaf persons: acoustical aspects". Int J Audiol. 44 (3): 178–89. doi:10.1080/14992020500031561. PMID 15916119. S2CID 37349704.
  17. ^ "Effectiveness in Treating Single-Sided Deafness with the Baha System | The Hearing Review – a MEDQOR brand". hearingreview.com. 4 April 2009. Retrieved 2022-02-07.
  18. ^ Huber, Alexander M.; Strauchmann, Bernd; Caversaccio, Marco D.; Wimmer, Wilhelm; Linder, Thomas; De Min, Nicola; Hempel, John-Martin; Pollotzek, Marlene; Frenzel, Henning; Hanke, Frauke; Röösli, Christof (2022-02-01). "Multicenter Results With an Active Transcutaneous Bone Conduction Implant in Patients With Single-sided Deafness". Otology & Neurotology. 43 (2): 227–235. doi:10.1097/MAO.0000000000003418. ISSN 1537-4505. PMC 8746904. PMID 34816809.
  19. ^ Salcher, Rolf; Zimmermann, Denise; Giere, Thomas; Lenarz, Thomas; Maier, Hannes (June 2017). "Audiological Results in SSD With an Active Transcutaneous Bone Conduction Implant at a Retrosigmoidal Position". Otology & Neurotology. 38 (5): 642–647. doi:10.1097/MAO.0000000000001394. ISSN 1537-4505. PMID 28375939. S2CID 21684216.
  20. ^ Sprinzl, G. M.; Wolf-Magele, A. (April 2016). "The Bonebridge Bone Conduction Hearing Implant: indication criteria, surgery and a systematic review of the literature". Clinical Otolaryngology. 41 (2): 131–143. doi:10.1111/coa.12484. ISSN 1749-4486. PMID 26073720. S2CID 37071934.
  21. ^ Dahm, Valerie; Auinger, Alice B.; Liepins, Rudolfs; Baumgartner, Wolf-Dieter; Riss, Dominik; Arnoldner, Christoph (June 2019). "A Randomized Cross-over Trial Comparing a Pressure-free, Adhesive to a Conventional Bone Conduction Hearing Device". Otology & Neurotology. 40 (5): 571–577. doi:10.1097/MAO.0000000000002184. ISSN 1531-7129. PMID 31083074. S2CID 85502496.
  22. ^ Mertens, Griet; Gilles, Annick; Bouzegta, Rajae; Van de Heyning, Paul (September 2018). "A Prospective Randomized Crossover Study in Single Sided Deafness on the New Non-Invasive Adhesive Bone Conduction Hearing System". Otology & Neurotology. 39 (8): 940–949. doi:10.1097/MAO.0000000000001892. hdl:10067/1564170151162165141. ISSN 1537-4505. PMID 30020266. S2CID 51677865.
  23. ^ Gurgel, Richard K.; Shelton, Clough (November 2013). "The SoundBite hearing system: patient-assessed safety and benefit study". The Laryngoscope. 123 (11): 2807–2812. doi:10.1002/lary.24091. ISSN 1531-4995. PMID 23856912. S2CID 5331746.
  24. ^ Galvin, John J. III; Fu, Qian-Jie; Wilkinson, Eric P.; Mills, Dawna; Hagan, Suzannah C.; Lupo, J. Eric; Padilla, Monica; Shannon, Robert V. (July–August 2019). "Benefits of Cochlear Implantation for Single-Sided Deafness: Data From the House Clinic-University of Southern California-University of California, Los Angeles Clinical Trial". Ear and Hearing. 40 (4): 766–781. doi:10.1097/AUD.0000000000000671. ISSN 1538-4667. PMID 30358655. S2CID 53024090.
  25. ^ Ludwig, Alexandra Annemarie; Meuret, Sylvia; Battmer, Rolf-Dieter; Schönwiesner, Marc; Fuchs, Michael; Ernst, Arne (2021). "Sound Localization in Single-Sided Deaf Participants Provided With a Cochlear Implant". Frontiers in Psychology. 12: 753339. doi:10.3389/fpsyg.2021.753339. ISSN 1664-1078. PMC 8566543. PMID 34744930.
  26. ^ Lieu, J. E. C. (2004). "Speech-Language and Educational Consequences of Unilateral Hearing Loss in Children". Archives of Otolaryngology–Head & Neck Surgery. 130 (5): 524–530. doi:10.1001/archotol.130.5.524. PMID 15148171.
  27. ^ OS X Mavericks: Audio pane of Accessibility preferences
  28. ^ Apple - Accessibility - iOS
[edit]