Pure-tone audiometry

Pure tone audiometry
Diagram of the human ear
ICD-9-CM95.41
MeSHD001301
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For broader coverage of this topic, see Audiometry.

Pure-tone audiometry is the main hearing test used to identify hearing threshold levels of an individual, enabling determination of the degree, type and configuration of a hearing loss[1][2] and thus providing a basis for diagnosis and management. Pure-tone audiometry is a subjective, behavioural measurement of a hearing threshold, as it relies on patient responses to pure tone stimuli.[3] Therefore, pure-tone audiometry is only used on adults and children old enough to cooperate with the test procedure. As with most clinical tests, standardized calibration of the test environment, the equipment and the stimuli is needed before testing proceeds (in reference to ISO, ANSI, or other standardization body). Pure-tone audiometry only measures audibility thresholds, rather than other aspects of hearing such as sound localization and speech recognition. However, there are benefits to using pure-tone audiometry over other forms of hearing test, such as click auditory brainstem response (ABR).[3] Pure-tone audiometry provides ear specific thresholds, and uses frequency specific pure tones to give place specific responses, so that the configuration of a hearing loss can be identified. As pure-tone audiometry uses both air and bone conduction audiometry, the type of loss can also be identified via the air-bone gap. Although pure-tone audiometry has many clinical benefits, it is not perfect at identifying all losses, such as ‘dead regions’ of the cochlea and neuropathies such as auditory processing disorder (APD).[4][5][6] This raises the question of whether or not audiograms accurately predict someone's perceived degree of disability.

  1. ^ Audiology Pure-Tone Testing at eMedicine
  2. ^ Roeser, Ross J. (2013). Roeser's audiology desk reference (2nd ed.). New York: Thieme. ISBN 9781604063981. OCLC 704384422.
  3. ^ a b Handbook of clinical audiology. Katz, Jack., Burkard, Robert, 1953-, Medwetsky, Larry. (5th ed.). Philadelphia: Lippincott Williams & Wilkins. 2002. ISBN 0683307657. OCLC 47659401.{{cite book}}: CS1 maint: others (link)
  4. ^ Moore, BC (April 2004). "Dead regions in the cochlea: conceptual foundations, diagnosis, and clinical applications". Ear and Hearing. 25 (2): 98–116. doi:10.1097/01.aud.0000120359.49711.d7. PMID 15064655. S2CID 12200368.
  5. ^ Moore BCJ (2001). "Dead Regions in the Cochlea: Diagnosis, Perceptual Consequences, and Implications for the Fitting of hearing aids". Trends Amplif. 5 (1): 1–34. doi:10.1177/108471380100500102. PMC 4168936. PMID 25425895.
  6. ^ Landegger, LD; Psaltis, D; Stankovic, KM (May 2016). "Human audiometric thresholds do not predict specific cellular damage in the inner ear". Hearing Research. 335: 83–93. doi:10.1016/j.heares.2016.02.018. PMC 5970796. PMID 26924453.