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DOI: 10.1055/a-2125-7645
Letter to the Editor: Misophonia: A Need for Audiological Diagnostic Guidelines
- The Misophonia Consensus Definition
- Diagnosing Misophonia as an Audiologist
- A Need for Audiological Diagnostic Guidelines
- References
The Misophonia Consensus Definition
Misophonia is a perceptual disorder that is gaining increased awareness across the fields of neuroscience, psychiatry, behavioral psychology, and audiology. However, conclusions as to the underlying etiology and effective management of misophonia suffer from inconsistent definitions of this disorder in the literature. For instance, some authors define misophonia as “hatred of sound” resulting in anger,[1] while others consider it to be a reaction to patterns of sound in certain settings.[2] To clarify the definition of this disorder for research and clinical purposes, the Misophonia Research Fund, an organization supported by The REAM Foundation and in partnership with the Milken Institute's Center for Strategic Philanthropy, invited a panel of 15 professionals with specialties in the fields of neuroscience, psychology, neuropsychology, behavioral psychology, psychiatry, and audiology to develop a consensus definition of misophonia.[3] Consensus was achieved using a modified Delphi method, which consisted of four rounds of voting on misophonia-related statements drawn from 68 references in the literature. Eighty percent agreement among the consensus team was required for the inclusion of identifiers and descriptors in the definition. The general description of the consensus definition is included below:
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Misophonia is a disorder of decreased tolerance to specific sounds or stimuli associated with such sounds. These stimuli, known as “triggers,” are experienced as unpleasant or distressing and tend to evoke strong negative emotional, physiological, and behavioral responses that are not seen in most other people. Misophonic responses do not seem to be elicited by the loudness of auditory stimuli, but rather by the specific pattern or meaning to an individual. Trigger stimuli are often repetitive and primarily, but not exclusively, include stimuli generated by another individual, especially those produced by the human body. Once a trigger stimulus is detected, individuals with misophonia may have difficulty distracting themselves from the stimulus and may experience suffering, distress, and/or impairment in social, occupational, or academic functioning. The expression of misophonic symptoms varies, as does the severity, which ranges from mild to severe impairments. Some individuals with misophonia are aware that their reactions to misophonic trigger stimuli are disproportionate to the circumstances. Misophonia symptoms are typically first observed in childhood or early adolescence.[3]
Notably, the consensus definition characterizes misophonia as a sound tolerance disorder in which distinct sounds and/or related sensory input (such as visual imagery) elicit strong negative emotional, physiological, and behavioral reactions not typically observed in the general population. This designation differs from the opinion of other experts, who have stated that misophonia should be classified as a psychiatric disorder, with diagnostic criteria as such.[1] [4] [5] According to the consensus definition, sensory input that evokes atypical negative responses to sound is termed a “trigger” and is usually generated by another entity (e.g., a family member), specifically but not limited to the human body (e.g., chewing versus mechanical sounds). Triggers may initiate intense emotional responses of distress and subsequent difficulty functioning in everyday life,[6] with such responses lying along a spectrum of severity. Please refer to Swedo et al,[3] for the complete consensus definition.
This expert definition clarifies several points concerning triggers, associated symptomatology, and resulting behavioral impairments in individuals with misophonia, as well as emphasizes the importance of differential diagnosis from similar pathologies (e.g., obsessive, compulsive-related disorders and hyperacusis). For instance, misophonic responses may be triggered by auditory inputs and other sensory stimuli present concurrent with the auditory event. These emotional responses can include many different manifestations, such as anger, irritation, and disgust.[5] Responses may also be moderated by external factors or context, including the environment in which the trigger is presented, the patient's relationship with the source of the trigger, and the sense of control over the aversive stimulus.[7] [8] Finally, it is important to consider misophonia in relation to comparable disorders, particularly for therapeutic intervention purposes. Patterns of psychiatric disorders across a varied range have been found to be highly comorbid with misophonia.[9] The most reported have been mood disorders, such as anxiety and depression.[5] [6] [9] These conditions may require medication and/or specific behavioral therapy that is outside of the audiologist's scope of practice. Within the audiologist's scope of practice, it is critical that misophonia be differentially diagnosed from the auditory disorders of hearing loss, tinnitus, recruitment, phonophobia, and, most of all, hyperacusis.[2] [10] For example, the general description of the Misophonia Consensus Definition could also characterize hyperacusis, as both are sound tolerance disorders and involve an intense emotional, behavioral, and physiologic response to sound. Intervention options for sound tolerance disorders include cognitive behavioral therapy, sound therapy, and tinnitus retraining therapy.[2] [11] Clearly, diagnosis and management of misophonia requires a multidisciplinary approach in which psychiatrists, psychologists, and audiologists come together. However, little guidance is provided in the literature regarding the audiological diagnostic criteria for misophonia.
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Diagnosing Misophonia as an Audiologist
The consensus definition states that neither misophonia's presence nor severity appear related to the patient's pure-tone sensitivity, although it is unclear what bearing hearing loss may have on this percept.[12] While tinnitus is a very different percept from misophonia, that is, a phantom “ringing” in the ears, significant comorbidity exists between the two pathologies,[2] especially as tinnitus severity increases.[12] Similarly, as previously stated, hyperacusis appears to be highly comorbid with misophonia.[2] [12] While the consensus definition does not explicitly clarify the difference between hyperacusis and misophonia, hyperacusis has been described as an individual experiencing “physical discomfort or pain” in response to sound levels typically tolerable for much of the population.[11] [13] [14] Misophonia is considered to consist of an intense emotional response to specific sounds, regardless of intensity level.[3] [11] [15] For example, an individual with hyperacusis might react negatively to any sound presented above a set intensity level, while an individual with misophonia might respond negatively to distinct types of sounds at any intensity. However, it has been suggested that four subtypes of hyperacusis exist: loudness, annoyance, fear, and pain.[10] [16] According to this categorization, misophonia could fall into the subtypes of annoyance or possibly fear, as these emotions are commonly seen in misophonics.[10] [11] [16] Salvi and colleagues[16] state that the distinguishing point of difference between these two disorders is loudness intolerance and that misophonia may be an instance of annoyance and fear hyperacusis without the loudness component. In considering these definitions, it appears that if hyperacusis is present, misophonia may then be classified as annoyance and/or fear hyperacusis. If hyperacusis is not present, misophonia may be a unique diagnosis. Due to the similarities between these sound intolerance disorders, there is a significant need for research in the field to determine whether these two conditions are unique or related subtypes.
Such comorbidities make it very difficult for audiologists to disentangle and identify misophonia as a clinical diagnosis. While the recent consensus definition does not recommend clinical measures that may be useful for audiologists in misophonia assessment, research has indicated that various behavioral and audiometric tools may be sensitive to this disorder. The following discussion highlights current clinical measures, from general to specific, that are sensitive to misophonia and will also detect comorbid audiological disorders such as tinnitus and hyperacusis ([Fig. 1]). This model further identifies behavioral and physiologic measures suggested by the literature to be sensitive to misophonia (highlighted in yellow) but which still require rigorous research to determine diagnostic efficacy. For a review of an exhaustive and exemplary audiological misophonia test battery, please see Pellicori.[17]
As in any audiological appointment, a case history is essential. This is where the clinician may first observe specific patient complaints regarding sound tolerance and gain insight into the etiology of sound tolerance disorders (e.g., noise exposure, hearing loss, etc.). Detection of tinnitus, hyperacusis, and misophonia begins with the patient's self-report. Next, questionnaires ranging from the evaluation of overall sound tolerance to specific misophonic symptomatology are critical. The Sound Tolerance Interview and Questionnaire Instrument (STIQI[18]) was developed to obtain information on the patient's sound tolerance that may predict success for amplification, but scored questions focus on both aided and unaided conditions and include queries that touch on sound intensity, sound triggers, characteristics of triggers, and tinnitus. Thus, this questionnaire may be useful in determining sound tolerance in the domains of hyperacusis, misophonia, and tinnitus for both patients with hearing loss and hearing thresholds less than or equal to 20 dB HL. Another example is the Sound Sensitivity Symptoms Questionnaire[19] which consists of questions on emotions and physical sensations elicited by sound. Following a sound tolerance report, the patient should also complete a tinnitus questionnaire, such as the Tinnitus Handicap Inventory (THI)[20] or the Tinnitus Functional Index (TFI).[21] A tinnitus questionnaire will establish whether tinnitus is present and comorbid with misophonia. If so, a separate psychometric tinnitus assessment may be conducted for the patient if they are participating in a research study or clinical trial,[22] [23] but this approach is not recommended outside of research practices or for clinical care.[24] Similarly, a hyperacusis questionnaire will determine if this disorder is present and comorbid with misophonia, which may inform the intervention approach to focus on sensitivity to both intensity levels of sound and the type of sound itself. Examples of hyperacusis assessments include the Modified Khalfa Hyperacusis Questionnaire,[25] the Hyperacusis Impact Questionnaire,[19] and the Inventory of Hyperacusis Symptoms.[26] Finally, symptoms specific to misophonia may be assessed via the Amsterdam Misophonia Scale,[1] the Duke Misophonia Questionnaire,[27] or the Misophonia Questionnaire,[28] to name a few. Clearly, there are a plethora of surveys that may be implemented to ascertain whether misophonia and comorbid disorders are present, with only a few examples listed. Guidelines presented in Schröder et al[1] and Dozier et al[4] for misophonia diagnostic criteria may prove helpful, but at present it is appropriate for the clinician to use their judgement in building a battery of clinical questionnaires.[17] A suggestion from the author is to ensure that the chosen instrument has been psychometrically evaluated and validated (all presented examples are validated excluding the STIQI). Furthermore, it should be noted that the proposed model of multiple questionnaires ranging from general sound tolerance to misophonia allows the clinician to obtain a holistic picture of the patient that will aid in intervention while also providing converging evidence that will point to symptomatology unique to misophonia. At this point, if misophonia is indicated, a referral to a psychiatrist and psychologist is warranted. These professionals will assess whether there are comorbid psychiatric disorders and determine whether medical intervention, as well as behavioral, is required.
While not clinically standardized, some audiometric measures may provide behavioral indicators of sound tolerance disorders, especially in patients with hearing thresholds less than or equal to 20 dB HL. [Fig. 1] highlights these approaches to illustrate that additional research is needed to better understand the clinical utility of such measures, whereas questionnaires have already been validated. For example, there is some evidence that extended high-frequency pure-tone testing (above 8 kHz) may reveal significantly better thresholds in patients with misophonia.[17] Similar findings have been observed in adults with hearing thresholds less than or equal to 20 dB HL and minimal tinnitus. For instance, adults who have THI scores at 6 or above tend to present with an extended high-frequency pure-tone average (at 10, 12.5, and 16 kHz) of better than 15 dB HL in the worse ear.[29] Therefore, these individuals may experience a heightened awareness of sound as reflected by extended high-frequency thresholds.[29] Another metric, loudness discomfort levels (LDLs) or uncomfortable loudness levels,[30] may be significantly decreased in both hyperacusis and misophonia.[2] [17] [19] In hyperacusis, LDL values may lie between 60 and 85 dB HL, less than the typical 100 dB HL value, while the range is more variable in misophonia.[2] [31] Thus, LDL measures are useful in indicating whether hyperacusis is also present and comorbid with misophonia but would not indicate whether these two conditions are distinct. Another promising behavioral approach specific to misophonia assessment investigated in one recent study is the determination of trigger threshold. It would be hypothesized that triggers might have a lower threshold than other stimuli in a patient with misophonia. Such an approach was implemented by Savard et al[32] using stimuli embedded in background noise at varying signal-to-noise ratios. While the authors did not find a significant difference between the threshold of trigger stimuli for participants with low and high misophonic tendencies, participants with high misophonic tendencies reported increased negative emotions for trigger stimuli above the threshold. These findings suggest that a modified trigger-threshold method performed in quiet, using audio-visual stimuli, or presented in various contexts could provide a useful tool in misophonia assessment. For example, several researchers have shown that negative emotions for misophonic triggers are decreased when the auditory trigger is incongruent with visual stimuli (e.g., lip smacking with a ball bouncing) or the source is unknown.[8] [8] [33] Thus, the measurement of trigger threshold may be significantly decreased when the context is congruent as compared to incongruent. This approach would be based upon the patient's reported triggers, allowing for personalized testing that cuts across the variability triggers for this population.[5] Open-source audio–visual databases containing misophonic stimuli are useful for such research purposes (https://osf.io/3ysfh/ [33]; https://zenodo.org/record/7109069#.Y9QK8lLMLz8 [34])
Finally, there has been an indication from one study that electrophysiology could serve as a useful objective measure of misophonia in the audiology clinic. Schroder et al[35] presented participants with an auditory oddball paradigm while recording cortical auditory evoked potentials (CAEPs). They found that in participants who fit the diagnostic criteria for the misophonia, the N1 component in response to oddball tones was present at a significantly reduced amplitude in comparison to the control group. The authors surmised that this finding reflects a sensory deficit in the automatic processing of auditory stimuli, as the N1 is thought to represent mechanisms related to early attention in processing sound.[36] However, to our knowledge, there are no other studies examining CAEP biomarkers in misophonia, making it unclear whether this finding is specific to misophonia or related comorbidities.[35] Other studies have also utilized physiologic measures, such as heart rate and galvanic skin response, to assess whether there exists a heightened autonomic condition during trigger presentations.[7] [37] These physiologic assessments may also prove useful clinically.
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A Need for Audiological Diagnostic Guidelines
Due to the minimally researched audiological assessment of misophonia, audiology clinics specializing in misophonia diagnosis have been left to the development of their own methodology.[12] [17] Thus, it is evident that there is a need for consensus on the audiological diagnostic assessment and criteria for misophonia, including guidelines for distinguishing misophonia and hyperacusis. The current consensus definition of misophonia is an initial step toward defining the disorder rather than providing clinical guidance on assessment and treatment. However, as research on misophonia is growing at a rapid pace,[3] it would be helpful to have an evolving consensus definition that is reviewed every few years to identify appropriate diagnostic criteria, similar to other pathologies in medicine.[38] At the same time, in order for there to be diagnostic criteria, translational research focused on the audiological assessment of misophonia must be ongoing. As previously stated, this disorder has been designated as a sound tolerance disorder, putting it directly into the scope of practice for audiologists. As such, there is a call for clinical researchers to evaluate measures that will be sensitive and specific to misophonia. Such measures may help to inform targeted treatments that are suggested to be successful in sound tolerance disorders, such as cognitive behavioral therapy, sound therapy, and tinnitus retraining therapy.[2] [6] Posttreatment assessment may then indicate whether such treatment has been effective in altering trigger perception and associated physiologic responses. While the aforementioned behavioral measures have shown promise, replication and standardization are still necessary. In addition, objective physiological markers provided by the auditory brainstem response and cortical auditory evoked potentials remain to be explored. Finally, it is the opinion of the author that the next necessary step in the audiological diagnosis of misophonia is to answer the question of differentiation between misophonia and hyperacusis. Should these sound tolerance disorders be unique or should misophonia be a subtype of hyperacusis when loudness intolerance is present? Are the underlying mechanisms similar or distinct[39]? What audiological measures can be used or developed to provide differential diagnosis? Without translational research conducted by audiologists and auditory neuroscientists, clinicians will continue to struggle in providing evidence-based practice for this population.
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Disclaimer
Any mention of a product, service, or procedure in the Journal of the American Academy of Audiology does not constitute an endorsement of the product, service, or procedure by the American Academy of Audiology.
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Conflict of Interest
J.C. serves as a member of the Misophonia Research Fund's Scientific Advisory Board, which conceived of the definition project, but did not participate in the consensus definition committee and did not have final approval/input into the definition language.
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References
- 1 Schröder A, Vulink N, Denys D. Misophonia: diagnostic criteria for a new psychiatric disorder. PLoS One 2013; 8 (01) e54706
- 2 Jastreboff PJ, Jastreboff MM. Treatments for decreased sound tolerance (hyperacusis and misophonia). Semin Hear 2014; 3: 105-120
- 3 Swedo SE, Baguley DM, Denys D. et al. Consensus definition of misophonia: a Delphi study. Front Neurosci 2022; 16: 841816
- 4 Dozier TH, Lopez M, Pearson C. Proposed diagnostic criteria for misophonia: a Multisensory conditioned aversive reflex disorder. Front Psychol 2017; 8: 1975
- 5 Jager I, de Koning P, Bost T, Denys D, Vulink N. Misophonia: phenomenology, comorbidity and demographics in a large sample. PLoS One 2020; 15 (04) e0231390
- 6 Guzick AG, Cervin M, Smith EEA. et al. Clinical characteristics, impairment, and psychiatric morbidity in 102 youth with misophonia. J Affect Disord 2023; 324: 395-402
- 7 Edelstein M, Brang D, Rouw R, Ramachandran VS. Misophonia: physiological investigations and case descriptions. Front Hum Neurosci 2013; 7: 296
- 8 Siepsiak M, Vrana SR, Rynkiewicz A, Rosenthal MZ, Dragan WŁ. Does context matter in misophonia? A multi-method experimental investigation. Front Neurosci 2023; 16: 880853
- 9 Rosenthal MZ, McMahon K, Greenleaf AS. et al. Phenotyping misophonia: Psychiatric disorders and medical health correlates. Front Psychol 2022; 13: 941898
- 10 Tyler RS, Pienkowski M, Roncancio ER. et al. A review of hyperacusis and future directions: part I. Definitions and manifestations. Am J Audiol 2014; 23 (04) 402-419
- 11 Henry JA, Theodoroff SM, Edmonds C. et al. Sound tolerance conditions (hyperacusis, misophonia, noise sensitivity, and phonophobia): definitions and management. Am J Audiol 2022; 31 (03) 513-527
- 12 Aazh H, Erfanian M, Danesh AA, Moore BCJ. Audiological and other factors predicting the presence of misophonia symptoms among a clinical population seeking help for tinnitus and/or hyperacusis. Front Neurosci 2022; a 16: 900065
- 13 Baguley DM. Hyperacusis. J R Soc Med 2003; 96 (12) 582-585
- 14 Fackrell K, Potgieter I, Shekhawat GS, Baguley DM, Sereda M, Hoare DJ. Clinical interventions of hyperacusis in adults: a scoping review to assess the current position and determine priorities for research. BioMed Res Int 2017; 2017: 2723715
- 15 Palumbo DB, Alsalman O, De Ridder D, Song JJ, Vanneste S. Misophonia and potential underlying mechanisms: a perspective. Front Psychol 2018; 9: 953
- 16 Salvi R, Chen G-D, Manohar S. Hyperacusis: loudness intolerance, fear, annoyance and pain. Hear Res 2022; 426: 108648
- 17 Pellicori J. Clinician's guide to misophonia. AudiologyOnline 2020 ; Article 27026. Accessed July 24, 2023 at: https://www.audiologyonline.com/articles/clinician-s-guide-to-misophonia-27099
- 18 Sherlock LP, Formby C. Considerations in the development of a sound tolerance interview and questionnaire instrument. Semin Hear 2017; 38 (01) 53-70
- 19 Aazh H, Hayes C, Moore BCJ, Danesh AA, Vitoratou S. Psychometric evaluation of the Hyperacusis Impact Questionnaire (HIQ) and Sound Sensitivity Symptoms Questionnaire (SSSQ) using a clinical population of adult patients with tinnitus alone or combined with hyperacusis. J Am Acad Audiol 2022; b 33 (05) 248-258
- 20 Newman CW, Jacobson GP, Spitzer JB. Development of the tinnitus handicap inventory. Arch Otolaryngol Head Neck Surg 1996; 122 (02) 143-148
- 21 Henry JA, Griest S, Thielman E, McMillan G, Kaelin C, Carlson KF. Tinnitus Functional Index: development, validation, outcomes research, and clinical application. Hear Res 2016; 334: 58-64
- 22 Henry JA, Meikle MB. Psychoacoustic measures of tinnitus. J Am Acad Audiol 2000; 11 (03) 138-155
- 23 Jin I-K, Tyler RS. Measuring tinnitus in pharmaceutical clinical trials. J Acoust Soc Am 2022; 152 (06) 3843
- 24 Tunkel DE, Bauer CA, Sun GH. et al. Clinical practice guideline: tinnitus. Otolaryngol Head Neck Surg 2014; 151 (02) S1-S40
- 25 Khalfa S, Dubal S, Veuillet E, Perez-Diaz F, Jouvent R, Collet L. Psychometric normalization of a hyperacusis questionnaire. ORL J Otorhinolaryngol Relat Spec 2002; 64 (06) 436-442
- 26 Greenberg B, Carlos M. Psychometric properties and factor structure of a new scale to measure hyperacusis: Introducing the Inventory of Hyperacusis Symptoms. Ear Hear 2018; 39 (05) 1025-1034
- 27 Rosenthal MZ, Anand D, Cassiello-Robbins C. et al. Development and initial validation of the Duke Misophonia Questionnaire. Front Psychol 2021; 12: 709928
- 28 Wu MS, Lewin AB, Murphy TK, Storch EA. Misophonia: incidence, phenomenology, and clinical correlates in an undergraduate student sample. J Clin Psychol 2014; 70 (10) 994-1007
- 29 Campbell J, LaBrec A, Bean C, Nielsen M, So W. Auditory gating and extended high-frequency thresholds in normal-hearing adults with minimal tinnitus. Am J Audiol 2019; 28 (1S): 209-224
- 30 Aazh H, Moore BCJ. Factors related to uncomfortable loudness levels for patients seen in a tinnitus and hyperacusis clinic. Int J Audiol 2017; 56 (10) 793-800
- 31 Sherlock LP, Formby C. Estimates of loudness, loudness discomfort, and the auditory dynamic range: normative estimates, comparison of procedures, and test-retest reliability. J Am Acad Audiol 2005; 16 (02) 85-100
- 32 Savard M-A, Sares AG, Coffey EBJ, Deroche MLD. Specificity of affective responses in misophonia depends on trigger identification. Front Neurosci 2022; 16: 879583
- 33 Samermit P, Young M, Allen AK. et al. Development and evaluation of a sound-swapped video database for misophonia. Front Psychol 2022; 13: 890829
- 34 Benesch D, Orloff D, Hansen H. FOAMS: processed audio files. Zenodo 2022 . Accessed July 24, 2023 at: https://zenodo.org/record/7109069#.ZCXvx1LMLz8
- 35 Schröder A, van Diepen R, Mazaheri A. et al. Diminished n1 auditory evoked potentials to oddball stimuli in misophonia patients. Front Behav Neurosci 2014; 8: 123
- 36 Näätänen R, Picton T. The N1 wave of the human electric and magnetic response to sound: a review and an analysis of the component structure. Psychophysiology 1987; 24 (04) 375-425
- 37 Kumar S, Tansley-Hancock O, Sedley W. et al. The brain basis for misophonia. Curr Biol 2017; 27 (04) 527-533
- 38 Singer M, Deutschman CS, Seymour CW. et al. The third international consensus definitions for sepsis and septic shock (Sepsis-3). JAMA 2016; 315 (08) 801-810
- 39 Jastreboff PJ, Jastreboff MM. The neurophysiological approach to misophonia: theory and treatment. Front Neurosci 2023; 17: 895574
Address for correspondence
Publication History
Received: 26 January 2023
Accepted: 04 July 2023
Accepted Manuscript online:
10 July 2023
Article published online:
29 October 2024
© 2024. American Academy of Audiology. This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commercial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/)
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References
- 1 Schröder A, Vulink N, Denys D. Misophonia: diagnostic criteria for a new psychiatric disorder. PLoS One 2013; 8 (01) e54706
- 2 Jastreboff PJ, Jastreboff MM. Treatments for decreased sound tolerance (hyperacusis and misophonia). Semin Hear 2014; 3: 105-120
- 3 Swedo SE, Baguley DM, Denys D. et al. Consensus definition of misophonia: a Delphi study. Front Neurosci 2022; 16: 841816
- 4 Dozier TH, Lopez M, Pearson C. Proposed diagnostic criteria for misophonia: a Multisensory conditioned aversive reflex disorder. Front Psychol 2017; 8: 1975
- 5 Jager I, de Koning P, Bost T, Denys D, Vulink N. Misophonia: phenomenology, comorbidity and demographics in a large sample. PLoS One 2020; 15 (04) e0231390
- 6 Guzick AG, Cervin M, Smith EEA. et al. Clinical characteristics, impairment, and psychiatric morbidity in 102 youth with misophonia. J Affect Disord 2023; 324: 395-402
- 7 Edelstein M, Brang D, Rouw R, Ramachandran VS. Misophonia: physiological investigations and case descriptions. Front Hum Neurosci 2013; 7: 296
- 8 Siepsiak M, Vrana SR, Rynkiewicz A, Rosenthal MZ, Dragan WŁ. Does context matter in misophonia? A multi-method experimental investigation. Front Neurosci 2023; 16: 880853
- 9 Rosenthal MZ, McMahon K, Greenleaf AS. et al. Phenotyping misophonia: Psychiatric disorders and medical health correlates. Front Psychol 2022; 13: 941898
- 10 Tyler RS, Pienkowski M, Roncancio ER. et al. A review of hyperacusis and future directions: part I. Definitions and manifestations. Am J Audiol 2014; 23 (04) 402-419
- 11 Henry JA, Theodoroff SM, Edmonds C. et al. Sound tolerance conditions (hyperacusis, misophonia, noise sensitivity, and phonophobia): definitions and management. Am J Audiol 2022; 31 (03) 513-527
- 12 Aazh H, Erfanian M, Danesh AA, Moore BCJ. Audiological and other factors predicting the presence of misophonia symptoms among a clinical population seeking help for tinnitus and/or hyperacusis. Front Neurosci 2022; a 16: 900065
- 13 Baguley DM. Hyperacusis. J R Soc Med 2003; 96 (12) 582-585
- 14 Fackrell K, Potgieter I, Shekhawat GS, Baguley DM, Sereda M, Hoare DJ. Clinical interventions of hyperacusis in adults: a scoping review to assess the current position and determine priorities for research. BioMed Res Int 2017; 2017: 2723715
- 15 Palumbo DB, Alsalman O, De Ridder D, Song JJ, Vanneste S. Misophonia and potential underlying mechanisms: a perspective. Front Psychol 2018; 9: 953
- 16 Salvi R, Chen G-D, Manohar S. Hyperacusis: loudness intolerance, fear, annoyance and pain. Hear Res 2022; 426: 108648
- 17 Pellicori J. Clinician's guide to misophonia. AudiologyOnline 2020 ; Article 27026. Accessed July 24, 2023 at: https://www.audiologyonline.com/articles/clinician-s-guide-to-misophonia-27099
- 18 Sherlock LP, Formby C. Considerations in the development of a sound tolerance interview and questionnaire instrument. Semin Hear 2017; 38 (01) 53-70
- 19 Aazh H, Hayes C, Moore BCJ, Danesh AA, Vitoratou S. Psychometric evaluation of the Hyperacusis Impact Questionnaire (HIQ) and Sound Sensitivity Symptoms Questionnaire (SSSQ) using a clinical population of adult patients with tinnitus alone or combined with hyperacusis. J Am Acad Audiol 2022; b 33 (05) 248-258
- 20 Newman CW, Jacobson GP, Spitzer JB. Development of the tinnitus handicap inventory. Arch Otolaryngol Head Neck Surg 1996; 122 (02) 143-148
- 21 Henry JA, Griest S, Thielman E, McMillan G, Kaelin C, Carlson KF. Tinnitus Functional Index: development, validation, outcomes research, and clinical application. Hear Res 2016; 334: 58-64
- 22 Henry JA, Meikle MB. Psychoacoustic measures of tinnitus. J Am Acad Audiol 2000; 11 (03) 138-155
- 23 Jin I-K, Tyler RS. Measuring tinnitus in pharmaceutical clinical trials. J Acoust Soc Am 2022; 152 (06) 3843
- 24 Tunkel DE, Bauer CA, Sun GH. et al. Clinical practice guideline: tinnitus. Otolaryngol Head Neck Surg 2014; 151 (02) S1-S40
- 25 Khalfa S, Dubal S, Veuillet E, Perez-Diaz F, Jouvent R, Collet L. Psychometric normalization of a hyperacusis questionnaire. ORL J Otorhinolaryngol Relat Spec 2002; 64 (06) 436-442
- 26 Greenberg B, Carlos M. Psychometric properties and factor structure of a new scale to measure hyperacusis: Introducing the Inventory of Hyperacusis Symptoms. Ear Hear 2018; 39 (05) 1025-1034
- 27 Rosenthal MZ, Anand D, Cassiello-Robbins C. et al. Development and initial validation of the Duke Misophonia Questionnaire. Front Psychol 2021; 12: 709928
- 28 Wu MS, Lewin AB, Murphy TK, Storch EA. Misophonia: incidence, phenomenology, and clinical correlates in an undergraduate student sample. J Clin Psychol 2014; 70 (10) 994-1007
- 29 Campbell J, LaBrec A, Bean C, Nielsen M, So W. Auditory gating and extended high-frequency thresholds in normal-hearing adults with minimal tinnitus. Am J Audiol 2019; 28 (1S): 209-224
- 30 Aazh H, Moore BCJ. Factors related to uncomfortable loudness levels for patients seen in a tinnitus and hyperacusis clinic. Int J Audiol 2017; 56 (10) 793-800
- 31 Sherlock LP, Formby C. Estimates of loudness, loudness discomfort, and the auditory dynamic range: normative estimates, comparison of procedures, and test-retest reliability. J Am Acad Audiol 2005; 16 (02) 85-100
- 32 Savard M-A, Sares AG, Coffey EBJ, Deroche MLD. Specificity of affective responses in misophonia depends on trigger identification. Front Neurosci 2022; 16: 879583
- 33 Samermit P, Young M, Allen AK. et al. Development and evaluation of a sound-swapped video database for misophonia. Front Psychol 2022; 13: 890829
- 34 Benesch D, Orloff D, Hansen H. FOAMS: processed audio files. Zenodo 2022 . Accessed July 24, 2023 at: https://zenodo.org/record/7109069#.ZCXvx1LMLz8
- 35 Schröder A, van Diepen R, Mazaheri A. et al. Diminished n1 auditory evoked potentials to oddball stimuli in misophonia patients. Front Behav Neurosci 2014; 8: 123
- 36 Näätänen R, Picton T. The N1 wave of the human electric and magnetic response to sound: a review and an analysis of the component structure. Psychophysiology 1987; 24 (04) 375-425
- 37 Kumar S, Tansley-Hancock O, Sedley W. et al. The brain basis for misophonia. Curr Biol 2017; 27 (04) 527-533
- 38 Singer M, Deutschman CS, Seymour CW. et al. The third international consensus definitions for sepsis and septic shock (Sepsis-3). JAMA 2016; 315 (08) 801-810
- 39 Jastreboff PJ, Jastreboff MM. The neurophysiological approach to misophonia: theory and treatment. Front Neurosci 2023; 17: 895574