Chronic tinnitus: analysis of clinical contributions from different audiological evalutions

Moreira, Hélinton Goulart; Bruno, Rúbia Soares; Oppitz, Sheila Jacques; Sanfins, Milaine Dominici; Garcia, Michele Vargas

doi:10.1590/2317-6431-2022-2660en

ABSTRACT

Purpose

To investigate whether there are differences in peripheral and central audiological findings between individuals with normal hearing thresholds with and without chronic tinnitus, and thereby understand which hearing tests are most important in this population.

Methods

The sample was composed of convenience, including individuals from 18 to 59 years old, divided into two groups: Group 1 (G1) composed of subjects without complaints of chronic tinnitus, and Group 2 (G2) composed of individuals with chronic tinnitus. The evaluation consisted of the following procedures: Anamnesis, High-frequency audiometry (HFA), Transient Otoacoustic emissions (TOAEs), Auditory Brainstem Response (ABR)-click, Frequency Following Response (FFR), and Long Latency Auditory Evoked Potential (LLAEP)-speak.

Results

G2 showed increased values for HFA, with significant differences. For both groups, TOAEs showed a predominance of responses. In ABR there were no statistically significant differences. In FFR, G1 obtained a greater amplitude of wave V and there was a greater absence in LLAEP of P1, N2, and P300 in G2.

Conclusion

The HFA, the analysis of the wave V/I ratio in ABR, the FFR, and the LLAEP identified alterations in individuals with chronic tinnitus, demonstrating that such procedures are promising in the evaluation of this population.

Keywords:
Tinnitus; Evoked potential; Hearing; Adult; Auditory cortex

RESUMO

Objetivo

Investigar se há diferenças nos achados audiológicos periféricos e centrais entre indivíduos com limiares auditivos normais com e sem zumbido crônico e, com isso, entender quais exames auditivos são importantes nessa população.

Métodos

A amostra foi composta por conveniência, incluindo indivíduos de 18 a 59 anos, divididos em dois grupos: grupo 1 (G1), formado por sujeitos sem queixa de zumbido crônico e grupo 2 (G2), por indivíduos com zumbido crônico. A avaliação consistiu nos seguintes procedimentos: anamnese, audiometria de altas frequências (AAF), emissões otoacústicas transientes (EOAT), potencial evocado auditivo de tronco encefálico (PEATE)-clique, frequency following response (FFR) e o potencial evocado auditivo de longa latência (PEALL)-fala.

Resultados

O G2 apresentou valores aumentados para a AFF, com diferenças significativas. Para ambos os grupos, a EOAT mostrou predominância de presença de respostas. No PEATE, não houve diferenças estatisticamente significativas. No FFR, o G1 obteve maior amplitude de onda V e houve maior ocorrência de ausências no PEALL dos potenciais P1, N2 e P300, no G2.

Conclusão

A AAF, a análise da relação da onda V/I do PEATE, o FFR e o PEALL identificaram alterações nos indivíduos com zumbido crônico, demonstrando que tais procedimentos são promissores na avaliação dessa população.

Palavras-chave:
Zumbido; Potenciais evocados; Audição; Adulto; Córtex auditivo

INTRODUCTION

Tinnitus is a symptom caused by diverse underlying mechanisms and it manifests in many different ways⁽¹1 Cederroth CR, Gallus S, Hall DA, Kleinjung T, Langguth B, Maruotti A, et al. Towards an understanding of tinnitus heterogeneity. Front Aging Neurosci. 2019;11:53. http://dx.doi.org/10.3389/fnagi.2019.00053. PMid:30941029.
http://dx.doi.org/10.3389/fnagi.2019.000... ⁾. In 2021, researchers put forward a chaos theory of chronic tinnitus based on dynamic and non-linear functioning of the human brain. It suggests that any change in the auditory system, even if very small, causes auditory deafferentation, which in turn produces generalized and diffuse changes in multiple brain areas and is ultimately experienced as unpleasant tinnitus⁽²2 Sadeghijam M, Moossavi A, Akbari M. Does tinnitus lead to chaos? Rev Bras Otorrinolaringol. 2021;87(2):125-6. PMid:33500207.⁾. In other words, neural deafferentation may result from any decrease in auditory inputs or an imbalance between excitation and inhibition, leading to a compensatory mechanism which results in an increas espontaneous and synchronous neural activity.

In the light of this concept of chronic tinnitus, it becomes necessary to investigate many different auditory and brain areas, and management methods based on current theories may not be effective⁽²2 Sadeghijam M, Moossavi A, Akbari M. Does tinnitus lead to chaos? Rev Bras Otorrinolaringol. 2021;87(2):125-6. PMid:33500207.⁾. Tinnitus is frequently present in individuals who have some type of hearing impairment, although there are frequent reports of its presence in people whose hearing thresholds are within the normal range⁽³3 McCormack A, Edmondson-Jones M, Somerset S, Hall D. A systematic review of the reporting of tinnitus prevalence and severity. Hear Res. 2016;337:70-9. http://dx.doi.org/10.1016/j.heares.2016.05.009. PMid:27246985.
http://dx.doi.org/10.1016/j.heares.2016.... ⁾.

Recently, it has been recommended that detailed medical and audiological evaluations be done in individuals with chronic tinnitus as a first approach to improving treatments for tinnitus. The hope is that by understanding the physiological processes involved in the functioning of the peripheral and central auditory nervous systems, it may be possible to provide better clinical management⁽⁴4 Valim CCA, Sanchez TG. The tinnitus total remission: targeting treatment to the etiological hypothesis. J Otorinolaringol ENT Res. 2018;10(3):153-5. http://dx.doi.org/10.15406/joentr.2018.10.00335.
http://dx.doi.org/10.15406/joentr.2018.1... ⁾.

In any audiological assessment, the possibility of deafferentation should be strongly considered⁽²2 Sadeghijam M, Moossavi A, Akbari M. Does tinnitus lead to chaos? Rev Bras Otorrinolaringol. 2021;87(2):125-6. PMid:33500207.⁾. Neural deafferentation, resulting from cochlear damage or subclinical synaptopathy, causes changes in brain neuroelectrical functioning, reorganization of the cortical tonotopic map, hyperactivity in the auditory cortex and thalamus, and increased neural synchrony, especially in areas connected to the auditory cortex⁽⁵5 De Ridder D, Vanneste S, Langguth B, Llinas R. Thalamocorti- cal dysrhythmia: a theoretical update in tinnitus. Front Neurol. 2015;6:124. http://dx.doi.org/10.3389/fneur.2015.00124. PMid:26106362.
http://dx.doi.org/10.3389/fneur.2015.001... ⁾.

The focus of this study is on the auditory system, looking to find diagnostic procedure(s) which have the greatest potential to assist in therapeutic management. The aim here was to compare peripheral and central audiological findings on individuals with normal hearing thresholds, with and without chronic tinnitus. We wanted to reinforce the idea that a more accurate diagnosis can be the basis for finding a better way of alleviating tinnitus symptoms⁽⁴4 Valim CCA, Sanchez TG. The tinnitus total remission: targeting treatment to the etiological hypothesis. J Otorinolaringol ENT Res. 2018;10(3):153-5. http://dx.doi.org/10.15406/joentr.2018.10.00335.
http://dx.doi.org/10.15406/joentr.2018.1... ⁾.

METHODS

This was an analytical, longitudinal, and quantitative study. Subjects were selected by convenience from those who attended a teaching hospital in the south of Brazil from July 2017 to February 2018. The study was approved by the Ethics Committee in Research with Human Beings (CEP da Federal University of Santa Maria, nr 77611417.5.0000.5346).

The research followed the norms and guidelines of Resolution 466/12 of the National Health Council, and all individuals gave signed consent after being informed about the procedures, risks, and benefits.

Participants were enrolled at a clinical audiology outpatient clinic, scheduled via the Municipal Health Department of Santa Maria (RS) for an audiological assessment. A total of 151 individuals of both genders, aged between 18 and 59, were screened. Of these, 129 were excluded for the following reasons: 70 had sensorineural hearing loss; 23, mixed hearing loss; 4, conductive hearing loss; 11, hearing loss at an isolated frequency, and 21 with high-frequency hearing loss. They were excluded because we wanted to test only individuals with or without chronic tinnitus who had normal hearing (thresholds up to 25 dBHL⁽⁶6 OMS: Organização Mundial da Saúde. Guia de orientação na avaliação audiológica [Internet]. Brasília: Sistema de Conselhos de Fonoaudiologia; 2020 [citado em 2022 Mar 8]. Disponível em: https://www.fonoaudiologia.org.br/wp-content/uploads/2020/09/CFFa_Manual_Audiologia-1.pdf
https://www.fonoaudiologia.org.br/wp-con... ⁾. This meant that the total sample consisted of 22 individuals.

Eligibility criteria

Subjects of both genders, with or without the perception of chronic tinnitus, were included in the study if they had auditory thresholds within the normal range of 0.25 to 8 kHz (up to 25 dBHL), type A tympanometric curves and bilateral contralateral stapedial acoustic reflexes, no history of self-reported or diagnosed neurological or psychiatric disease, and had had no continuous exposure to noise.

The participants were divided into two groups: group 1 (G1), composed of subjects without chronic tinnitus perception, and group 2 (G2), individuals who had had chronic tinnitus for at least 6 months; the tinnitus could be unilateral or bilateral but needed to have an annoyance score of at least 5 on the Visual Analogue Scale (VAS).

The testing protocol had two stages: a set of evaluation procedures (for initial screening) and research procedures (for data analysis). In total, testing took 3 hours.

Evaluation procedures

For screening, a basic audiological assessment was performed involving audiological anamnesis, visual inspection of the external acoustic meatus, pure tone audiometry, logoaudiometry, and acoustic immittance measurement.

To gauge tinnitus, a VAS scale was used - a line on a sheet of paper with the ends numbered from 0 to 10. One end of the line was marked “no ringing” and the other “worst ringing imaginable”. The patient was asked to make a mark on the line corresponding to their present level of discomfort. In addition, a Tinnitus Handicap Inventory (THI) questionnaire was verbally addressed to the subject, with responses to 25 questions scored as: “yes” (4 points), “at times” (2 points), or “no” (0 points). The scores were added together to obtain a total score that characterized the severity of the tinnitus: negligible (0 to 16%), mild (18 to 36%), moderate (38 to 56%), severe (58 to 76%), or catastrophic (78 to 100%)⁽⁷7 Figueiredo RR, Azevedo AA, Oliveira PM. Correlation analysis of the visualanalogue scale and the Tinnitus Handicap Inventory in tinnitus patients. Rev Bras Otorrinolaringol. 2009;75(1):76-9. http://dx.doi.org/10.1016/S1808-8694(15)30835-1. PMid:19488564.
http://dx.doi.org/10.1016/S1808-8694(15)... ^,⁸8 Schmidt LP, Teixeira VN, Dall’Igna C, Dallagnol D, Smith MM. Brazilian Portuguese Language version of the “Tinnitus Handicap Inventory”: validity and Reproducibility. Rev Bras Otorrinolaringol. 2006;72(6):808-10. http://dx.doi.org/10.1016/S1808-8694(15)31048-X. PMid:17308834.
http://dx.doi.org/10.1016/S1808-8694(15)... ⁾.

Procedures

High frequency audiometry (HFA)

The thresholds of very high-pitched sounds were measured, taking in frequencies from 9 to 18 kHz at intensities up to the maximum of the equipment (110 dB). An Interacoustics AS10 HF audiometer was used together with Koss headphones, according to the literature⁽⁹9 Oppitz SJ, Silva LCL, Garcia MV, Silveira AF. High-frequency auditory thresholds in normal hearing adults. CoDAS. 2018;30(4):e20170165. PMid:30066724.⁾.

Transient-evoked otoacoustic emissions (TEOAEs)

TEOAEs were measured bilaterally using the Smart EP equipment from Intelligent Hearing Systems (IHS). The procedure was performed in an acoustically treated room using an 80 dB SPL click stimulus in the non-linear mode; 1024 stimuli were recorded in a window of 20 ms ensuring that artifacts were kept below 15%. The pass criterion was a signal-to-noise ratio greater than 3 dB at 3 of the 5 frequencies of 1, 1.5, 2, 3, and 4 kHz⁽¹⁰10 Durante AS, Carvalho RMM, Costa FS, Soares JS. Characteristics of transient evoked otoacoustic emissions in newborn hearing screening program. Pro Fono. 2005;17(2):133-40. http://dx.doi.org/10.1590/S0104-56872005000200002. PMid:16909523.
http://dx.doi.org/10.1590/S0104-56872005... ⁾.

Electrophysiological assessment

For recording auditory evoked potentials, the two-channel Smart EP device was used. Average assessment time was 1.5 hours.

After cleaning the skin with exfoliating gel (Nuprep®), surface electrodes were attached on the scalp with Maxxi Fix® electrolytic paste and secured with adhesive tape, ensuring that the impedance between the electrodes was less than 3 kΩ. During the assessments, subjects were instructed to keep their eyes closed and stay still to reduce muscle artifacts. The light in the room was turned off to avoid electrical interference.

For recording Auditory Brainstem Response (ABR) and frequency following responses (FFRs), the electrodes were positioned as follows: active electrode at Fz; ground electrode at Fpz; and reference electrode on the right and left mastoids⁽¹¹11 Filippini R, Befi-Lopes DM, Schochat E. Efficacy of auditory training using the auditory brainstem response to complex sounds: auditory processing disorder and specific language impairment. Folia Phoniatr Logop. 2012;64(5):217-26. http://dx.doi.org/10.1159/000342139. PMid:23006808.
http://dx.doi.org/10.1159/000342139... ⁾. For long latency auditory evoked potentials (LLAEPs), the electrodes were positioned as follows: Fz = ground electrode on the forehead; Cz = active electrode on the cranial vertex; and reference electrodes on the right and left mastoids. These positions are the most common in the literature⁽¹²12 Jasper HH. Appendix to report to committee on clinical examination in EEG: the ten-twenty electrode system of the international federation. Electroencephalogr Clin Neurophysiol. 1958;10:371-5.⁾. The impedance between electrodes was less than 3 kΩ, the residual noise below 0.11 µV, and the signal/noise ratio >1.0. The maximum number of accepted artifacts was 10% of the total number of stimuli.

ABR Auditory Brainstem Response (ABR)

Responses were elicited using a click stimulus of 80 dBnHL, of rarefied polarity, at a rate of 27.7/sec. Filtering was 0.1-3 kHz within a 12 ms window, and 2048 scans needed to be reproducible from two runs. The criterion for identifying the integrity of the auditory pathway was the presence of waves I, III, and V, as well as normal latency and interpeak intervals (within two standard deviations of the literature norms)⁽¹³13 Webster R. The Auditory Brainstem Response (ABR): a normative study using the Intelligent Hearing System’s Smart Evoked Potential System [thesis]. Towson: Towson University; 2016 [citado em 2022 Mar 8]. Disponível em: https://mdsoar.org/bitstream/handle/11603/3281/TSP2016Webster.pdf?sequence=1&isAllowed=y
https://mdsoar.org/bitstream/handle/1160... ⁾. Amplitude measurements were made from a positive peak to the next negative valley.

Frequency following responses (FFRs)

EEG responses were elicited using the syllable /da/ of 40 ms, alternating polarity, intensity 80 dB, rate of 10.9/sec applied only to the right ear⁽¹⁴14 Hornickel J, Skoe E, Kraus N. Subcortical laterality of speech encoding. Audiol Neurotol. 2009;14(3):198-207. http://dx.doi.org/10.1159/000188533. PMid:19122453.
http://dx.doi.org/10.1159/000188533... ⁾. Two scans with 3000 stimuli were performed, free of artifacts. The responses were added, giving a wave form composed of 6000 stimuli; in the same recording window, a filter of 100-2000 Hz was activated in the toolbar and applied to the resulting wave⁽¹⁵15 Russo N, Nicol T, Musacchia G, Kraus N. Brainstem responses to speech syllables. Clin Neurophysiol. 2004;115(9):2021-30. http://dx.doi.org/10.1016/j.clinph.2004.04.003. PMid:15294204.
http://dx.doi.org/10.1016/j.clinph.2004.... ⁾.

The evaluation of the FFR was performed in the time domain. Seven waves were identified: the first positive peak (V), followed by successive negative peaks (A, C, D, E, F, and O). The interpeak intervals were also calculated, which correspond to the wavelength of the fundamental frequency⁽¹⁵15 Russo N, Nicol T, Musacchia G, Kraus N. Brainstem responses to speech syllables. Clin Neurophysiol. 2004;115(9):2021-30. http://dx.doi.org/10.1016/j.clinph.2004.04.003. PMid:15294204.
http://dx.doi.org/10.1016/j.clinph.2004.... ^,¹⁶16 Johnson KL, Nicol TG, Kraus N. Brainstem response to speech: a biological marker of auditory processing. Ear Hear. 2005;26(5):424-34. http://dx.doi.org/10.1097/01.aud.0000179687.71662.6e. PMid:16230893.
http://dx.doi.org/10.1097/01.aud.0000179... ⁾. Also measured was the VA complex (the slope), which was calculated using the amplitudes and latencies of waves V and A; the slope is based on the formula: (amplitude of V - amplitude of A) divided by (latency of A - latency of V)⁽¹⁷17 Kraus N, Anderson S, White-Schwoch T. The frequency-following response: a window into human communication. In: Kraus N, Anderson S, White-Schwoch T, Fay RR, Popper AN, editores. The frequency-following response. Cham: Springer; 2017. p. 1-15. http://dx.doi.org/10.1007/978-3-319-47944-6_1.
http://dx.doi.org/10.1007/978-3-319-4794... ⁾.

Normative values from the Navigator Pro equipment⁽¹¹11 Filippini R, Befi-Lopes DM, Schochat E. Efficacy of auditory training using the auditory brainstem response to complex sounds: auditory processing disorder and specific language impairment. Folia Phoniatr Logop. 2012;64(5):217-26. http://dx.doi.org/10.1159/000342139. PMid:23006808.
http://dx.doi.org/10.1159/000342139... ⁾ were considered. Although this equipment is different from the type we used, when we collected our data there were still no reference values for the IHS equipment. Nevertheless, the protocol we used was the same as the reference study and both sorts of equipment produce similar responses.

Long Latency Auditory Evoked Potential (LLAEP)

300 verbal stimuli were presented binaurally over insert earphones at an intensity of 80 ndBHL in the traditional oddball paradigm⁽¹⁸18 Oppitz SJ, Didoné DD, da Silva DD, Gois M, Folgearini J, Ferreira GC, et al. Long-latency auditory evoked potentials with verbal and nonverbal stimuli. Rev Bras Otorrinolaringol. 2015;81(6):647-52. PMid:26480901.⁾. Stimuli were composed of the syllable /ba/, which was the frequent stimulus (80% of the time), and the syllable /di/, which was the rare stimulus (20% of the time). To begin, the examiner simulated the test orally, sounding out a sequence of /ba/ and /di/ in order for the subjects to understand the test. The individual was instructed to pay attention to the rare stimulus /di/, counting the number of them mentally. At the end, the examiner asked how many infrequent targets there were, and the number was compared to the total presented by the equipment, thus ensuring that the subject performed the activity correctly⁽¹⁹19 Bruno RS, Oppitz SJ, Garcia MV, Biaggio EPV. Potencial evocado auditivo de longa latência: diferenças na forma de contagem do estímulo raro. Rev CEFAC. 2016;18(1):1982-0216. http://dx.doi.org/10.1590/1982-021620161816415.
http://dx.doi.org/10.1590/1982-021620161... ⁾.

The stimulus rate was 1.1/sec, there were 300 sweeps, and filtering was 1-30 Hz in a time window of 510 ms. The latency (ms) and amplitude (µV) were obtained by identifying waves P1, N1, P2, N2, and P300⁽²⁰20 Jasper HH. Appendix to report to committee on clinical examination in EEG: the ten-twenty electrode system of the international federation. Electroencephalogr Clin Neurophysiol. 1958;10:371-5.^,²¹21 McPherson DL. Long Latency auditory evoked potentials. In: McPherson DL, editor. Late potentials of the auditory system. San Diego: Singular Publishing Group; 1996. p. 7-21.⁾. After a run, if the P300 potential was absent, a few minutes rest were given and the exam repeated. In this way alertness and reliability could be ensured.

Data were placed in an Excel spreadsheet. Initially, the Shapiro-Wilk test was used to determine whether the sample distribution was normal or not. For statistical analyses, a Student t-test, paired Student t-test, and Chi-square test were used, with a significance level set at 5% (p<0.05).

RESULTS

The total sample group consisted of 22 individuals, 11 included in G1 and 11 in G2, representing 22 ears in each group and 44 ears in total. For G1, the mean age was 40.4 years, (range 27 to 57) while for G2 the average age was 44 years (range 26 to 59).

The distribution of the sample is shown in Table 1. The distribution was homogeneous between gender (p = 0.183) and age (p = 0.43) (Chart 1).

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Table 1
Comparison between groups for high frequency audiometry for both ears

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Chart 1
Statistical analysis of the sample considering the variables gender and age between the groups

In G2, the time for which tinnitus had been perceived ranged from 8 months to 15 years (mean 4 years 6 months). In terms of THI, tinnitus ranged from grade 1 (negligible) to 5 (catastrophic), with a mean of 3.09 (moderate). For the VAS, the minimum score was 7 and the maximum 10, with an average of 8.4.

Verbally, 63.6% reported whistle-type tinnitus and 36.4% waterfall-type tinnitus. Of these, 90.9% reported the sensation to be steady and 9.1% pulsatile, but all subjects reported that it was constantly present. For 63.6% of subjects, onset was sudden and for 36.4% it was gradual. In terms of location, 18.2% reported the location in both ears, with the right being worse; 45.5% reported in both ears, with the left being worse; and 9.1% reported “in the head”. There were 18.2% who reported tinnitus in the right ear and 9.1% in the left.

Examining the high frequency audiometry (HFA), comparisons between the groups were made in terms of right and left ears (44 ears in all) (Table 1).

TEOAEs were present in both groups, and had similar magnitudes, with no significant differences (p = 0.138) (Table 2).

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Table 2
Comparison of groups in relation to the presence of transient otoacoustic emissions

ABR showed similar latencies and amplitudes between the groups, and in all comparisons there were no significant differences between them (Table 3).

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Table 3
Comparison between groups for brainstem auditory evoked potential latencies in both ears

For the FFRs, latencies, interpeak intervals, and amplitudes between groups showed generally similar responses, with only one significant difference (V amplitude, p = 0.041) (Table 4).

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Table 4
Comparison of latencies, interpeak intervals, and frequency following response amplitudes between groups

For LLAEPs, G1 presented better findings for the latency of the P300 component (p = 0.003) and no difference in the comparison of amplitudes (Table 5).

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Table 5
Comparison of groups for latencies (ms) and amplitudes (μV) in both ears in the long-latency auditory evoked potential

In the analysis of the presence/absence of LLAEP waves, there were significant differences (p < 0.05) for 3 of the 5 variables (Chart 2).

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Chart 2
Relationship between groups for the absence/presence of long-latency auditory evoked potentials in both ears

Figure 1 shows examples of traces of the ABR illustrating the greater response amplitudes for wave V in G2 (Figure 1).

Figure 1
Traces of the brainstem auditory evoked potential for group 1 (control group) and group 2 (experimental group)

Figure 2 illustrates how the FFR has higher latencies for components V and A in G2 (Figure 2).

Figure 2
Traces of the frequency following response for group 1 (control group) and group 2 (experimental group)

Figure 3 shows how the LLAEP in G2 had longer latencies for the P1 and N1 components as well as a greater amplitude for P300 (Figure 3).

Figure 3
Traces of the long latency auditory evoked potential for group 1 (experimental group) and group 2 (control group)

DISCUSSION

The subject of the present study is in complete agreement with the current literature, highlighting the need to set common criteria for evaluating tinnitus. Common standards will allow for a more adequate clinical management and perhaps, eventually, total cure of tinnitus⁽²²22 Wang H, Tang D, Wu Y, Zhou L, Sun S. The state of the art of sound therapy for subjective tinnitus in adults. Ther Adv Chronic Dis. 2020;11:2040622320956426. http://dx.doi.org/10.1177/2040622320956426. PMid:32973991.
http://dx.doi.org/10.1177/20406223209564... ⁾.

High frequency audiometry (HFA) has shown lower thresholds (better hearing) in G1 compared to G2. The findings agree with researchers⁽²³23 Vielsmeier V, Lehner A, Strutz J, Steffens T, Kreuzer PM, Schecklmann M, et al. The relevance of the high frequency audiometry in tinnitus patients with normal hearing in conventional pure-tone audiometry. BioMed Res Int. 2015;2015(3):302515. http://dx.doi.org/10.1155/2015/302515. PMid:26583098.
http://dx.doi.org/10.1155/2015/302515... ⁾ who have studied the relevance of HFA in individuals with tinnitus and normal auditory thresholds. This study has found that HFA provides additional useful information in this population, suggesting that subjects with tinnitus tend to have alterations in the basal region of the cochlea. Thus, the increase in auditory thresholds at high frequencies may be the cause of the perception of chronic tinnitus, perhaps due to an auditory deafferentation mechanism⁽²⁴24 Morgan AE, Elghandour AMA, Abdeltawwab MM. Hidden or subclinical cochleopathy in idiopathic subjective tinnitus: extended high frequency audiometry and otoacoustic emission. Hear Balance Commun. 2021;19(3):212-8. http://dx.doi.org/10.1080/21695717.2021.1943774.
http://dx.doi.org/10.1080/21695717.2021.... ⁾.

The work described in (24) emphasizes the importance of high thresholds at high frequencies in subjects with chronic tinnitus but with preserved peripheral auditory acuity up to 8 kHz, suggesting that this test could be an important addition to a battery of assessments for diagnosis of tinnitus. HFA provides additional useful clinical information, since it is correlated with the laterality, frequency, and severity of tinnitus⁽²³23 Vielsmeier V, Lehner A, Strutz J, Steffens T, Kreuzer PM, Schecklmann M, et al. The relevance of the high frequency audiometry in tinnitus patients with normal hearing in conventional pure-tone audiometry. BioMed Res Int. 2015;2015(3):302515. http://dx.doi.org/10.1155/2015/302515. PMid:26583098.
http://dx.doi.org/10.1155/2015/302515... ⁾.

For TOAEs (Table 2), we found no responses in only two subjects, demonstrating the similarity between the groups in terms of outer hair cell function. This finding differs from another study⁽²⁴24 Morgan AE, Elghandour AMA, Abdeltawwab MM. Hidden or subclinical cochleopathy in idiopathic subjective tinnitus: extended high frequency audiometry and otoacoustic emission. Hear Balance Commun. 2021;19(3):212-8. http://dx.doi.org/10.1080/21695717.2021.1943774.
http://dx.doi.org/10.1080/21695717.2021.... ⁾, which found differences in TOAEs and DPOAEs between subjects with and without tinnitus. However, perhaps these differences are due to the different type of analysis performed - one in which the response amplitude was measured but not the presence or absence, which was performed here. We suggest that the amplitude of responses of outer hair cells is smaller in individuals with chronic tinnitus, although this reduction does not inhibit the presence of responses in the frequency band assessed by TEOAEs. We have found that the higher frequency regions, analyzed through DPOAEs, increase their response amplitude so as to compensate for the neural reduction at the level of the VIII cranial nerve⁽²⁴24 Morgan AE, Elghandour AMA, Abdeltawwab MM. Hidden or subclinical cochleopathy in idiopathic subjective tinnitus: extended high frequency audiometry and otoacoustic emission. Hear Balance Commun. 2021;19(3):212-8. http://dx.doi.org/10.1080/21695717.2021.1943774.
http://dx.doi.org/10.1080/21695717.2021.... ⁾.

In view of the above, it is suggested that, whenever possible, experimenters use both methods to measure OAEs - that is analyse not only the amplitude of responses but also their presence or absence. Understanding cochlear mechanics is important, since small changes in sensory input from the cochlea can result in a larger compensatory increase in neural amplification of the auditory system, the end result of which is chronic tinnitus⁽²2 Sadeghijam M, Moossavi A, Akbari M. Does tinnitus lead to chaos? Rev Bras Otorrinolaringol. 2021;87(2):125-6. PMid:33500207.^,²⁵25 Bramhall NF, McMillan GP, Mashburn AN. Subclinical auditory dysfunction: relationship between distortion product otoacoustic emissions and the audiogram. Am J Audiol. 2021;30(3S):854-69. http://dx.doi.org/10.1044/2020_AJA-20-00056.
http://dx.doi.org/10.1044/2020_AJA-20-00... ⁾. However, in this context, it is worth mentioning a recent study⁽²⁶26 Han BI, Lee HW, Ryu S, Kim JS. Tinnitus update. J Clin Neurol. 2021 Jan;17(1):1-10. http://dx.doi.org/10.3988/jcn.2021.17.1.1. PMid:33480192.
http://dx.doi.org/10.3988/jcn.2021.17.1.... ⁾ which suggested that tinnitus is not always initiated in the cochlea, and that therefore diagnostic and therapeutic strategies should focus on the central auditory nervous system, limbic system, and autonomous nervous system.

A recent survey showed that the ratio of wave V/I amplitude in ABR can serve as a reliable metric to objectively identify tinnitus, as well as to monitor neuroplastic changes in the auditory pathway over time⁽²⁷27 Lu J, West MB, Du X, Cai Q, Ewert DL, Cheng W, et al. Electrophysiological assessment and pharmacological treatment of blast-induced tinnitus. PLoS One. 2021;16(1):e0243903. http://dx.doi.org/10.1371/journal.pone.0243903.
http://dx.doi.org/10.1371/journal.pone.0... ⁾. The present research supports this approach, since, in our ABR analysis, an increase in the V/I ratio was observed only in subjects with chronic tinnitus. This finding is in line with the central gain theory, in which, when similar wave I values are observed between groups, increases in the V/I wave ratio reflect reduced output of the auditory nerve. This is turn may cause neural amplification at the brainstem level. This finding contributes to the characterization of tinnitus as a neuroplasticity disorder⁽²⁷27 Lu J, West MB, Du X, Cai Q, Ewert DL, Cheng W, et al. Electrophysiological assessment and pharmacological treatment of blast-induced tinnitus. PLoS One. 2021;16(1):e0243903. http://dx.doi.org/10.1371/journal.pone.0243903.
http://dx.doi.org/10.1371/journal.pone.0...

28 Sedley W. Tinnitus: does gain explain? Neuroscience. 2019 Maio 21;407:213-28. http://dx.doi.org/10.1016/j.neuroscience.2019.01.027. PMid:30690137.
http://dx.doi.org/10.1016/j.neuroscience... ^-²⁹29 Johannesen PT, Lopez-Poveda EA. Age-related central gain compensation for reduced auditory nerve output for people with normal audiograms, with and without tinnitus. iScience. 2021;24(6):102658. http://dx.doi.org/10.1016/j.isci.2021.102658.
http://dx.doi.org/10.1016/j.isci.2021.10... ⁾.

In the FFR, the responses were similar between the groups, with one point of difference. It is noteworthy that G2 had higher latencies compared to G1, especially in the VA complex, demonstrating that subjects with tinnitus have greater difficulty decoding the rapid temporal changes inherent to consonants⁽³⁰30 Sanfins MD, Colella-Santos MF. Frequency following response. In: Menezes PL, editor. Tratado de eletrofisiologia para audiologia. 1ª ed. Ribeirão Preto: Book Toy; 2018. p. 97-112.⁾. This supports the compensatory hypothesis, in which some aspects of auditory processing recover due to progressive compensatory plasticity at higher stages of the central auditory pathway. Compensation is observed only at higher levels of the auditory pathway, where acoustic signal processing takes place⁽³¹31 Omidvar S, Mahmoudian S, Khabazkhoob M, Ahadi M, Jafari Z. Tinnitus impacts on speech and non-speech stimuli. Otol Neurotol. 2018;39(10):e921-8. http://dx.doi.org/10.1097/MAO.0000000000002002. PMid:30239441.
http://dx.doi.org/10.1097/MAO.0000000000... ^,³²32 Chambers AR, Resnik J, Yuan Y, Whitton JP, Edge AS, Liberman MC, et al. Central gain restores auditory processing following near-complete cochlear denervation. Neuron. 2016;89(4):867-79. http://dx.doi.org/10.1016/j.neuron.2015.12.041. PMid:26833137.
http://dx.doi.org/10.1016/j.neuron.2015.... ⁾.

In the FFR, it was possible to register seven wave amplitudes, with a significantly greater difference in the amplitude of wave V in G1 compared to G2. In this sense, it is possible to observe that individuals with tinnitus have maladaptive subcortical plasticity, in addition to impairment to the cognitive functions of attention and memory. Therefore, these individuals may have problems processing speech in difficult listening situations, since processing requires all levels of attentional capacity, and may be impaired after the development of tinnitus⁽³³33 Ivansic D, Guntinas-Lichius O, Müller B, Volk GF, Schneider G, Dobel C. Impairments of speech comprehension in patients with tinnitus: a review. Front Aging Neurosci. 2017;9:224. http://dx.doi.org/10.3389/fnagi.2017.00224.
http://dx.doi.org/10.3389/fnagi.2017.002... ⁾.

Two recent systematic reviews highlighted P300 as a potential biomarker for subjective tinnitus, justifying that the symptom causes inhibition of attention to external stimuli, resulting from changes in auditory and cognitive functioning⁽²2 Sadeghijam M, Moossavi A, Akbari M. Does tinnitus lead to chaos? Rev Bras Otorrinolaringol. 2021;87(2):125-6. PMid:33500207.^,³⁴34 Azevedo AA, Figueiredo RR, Penido NO. Tinnitus and event related potentials: a systematic review. Rev Bras Otorrinolaringol. 2020;86(1):119-26. PMid:31753780.^,³⁵35 Cardon E, Joossen I, Vermeersch H, Jacquemin L, Mertens G, Vanderveken OM, et al. Systematic review and meta-analysis of late auditory evoked potentials as a candidate biomarker in the assessment of tinnitus. PLoS One. 2020;15(12):e0243785. http://dx.doi.org/10.1371/journal.pone.0243785.
http://dx.doi.org/10.1371/journal.pone.0... ⁾. Therefore, this leads to the hypothesis that cortical dysfunction is linked to the thalamus, so that the LLAEP might help in correlating tinnitus with neurobiological alterations.

Cortical dysfunctions linked to the thalamus contribute to the perception of tinnitus, since they can impair inhibitory blocking mechanisms. In typical auditory functioning, the tinnitus signal is canceled at the thalamic level by an inhibitory feedback loop which originates in the paralimbic structures. However, as observed in the present study, the impairment of blocking can interrupt the inhibition of the signal at the thalamic level, resulting in the retransmission of the signal to the auditory cortex and be perceived as tinnitus⁽²⁶26 Han BI, Lee HW, Ryu S, Kim JS. Tinnitus update. J Clin Neurol. 2021 Jan;17(1):1-10. http://dx.doi.org/10.3988/jcn.2021.17.1.1. PMid:33480192.
http://dx.doi.org/10.3988/jcn.2021.17.1.... ⁾.

At the same time, when the absence or presence of LLAEP components was analysed here, individuals with tinnitus had a much higher number of absences. This demonstrates that the changes are not restricted just to the auditory regions, but there are modifications to subcortical routes as well, so that tinnitus involves a network of structures in non-auditory areas, including temporoparietal, prefrontal, and limbic regions⁽³⁶36 Zhou GP, Shi XY, Wei HL, Qu LJ, Yu YS, Zhou QQ, et al. Disrupted intraregional brain activity and functional connectivity in unilateral acute tinnitus patients with hearing loss. Front Neurosci. 2019;13:1010. http://dx.doi.org/10.3389/fnins.2019.01010.
http://dx.doi.org/10.3389/fnins.2019.010... ^,³⁷37 Rauschecker JP, Leaver AM, Muhlau M. Tuning out the noise: limbic-auditory interactions in tinnitus. Neuron. 2010;66(6):819-26. http://dx.doi.org/10.1016/j.neuron.2010.04.032. PMid:20620868.
http://dx.doi.org/10.1016/j.neuron.2010.... ⁾. In this sense, neuroplastic changes begin at the brainstem level and proceed to the upper stages of the auditory pathway. Thus, these changes can cause impairments in speech decoding, in attention, and in memory, explaining the absence of the cognitive potential (P300) which depends on these aspects for its elicitation.

The findings of the present study have shown that tinnitus, even if generated peripherally, causes neurobiological changes in the central auditory pathway. In this sense, chronic tinnitus can be characterized as a neuroplasticity disorder, explained by chaos theory. Because brain function is non-linear and dynamic, small changes in sensory input can cause large and irregular changes in general brain function. This manifests as a functional impairment in the processing of acoustic information, as well as in cognition, negatively impacting the subjects' quality of life⁽²2 Sadeghijam M, Moossavi A, Akbari M. Does tinnitus lead to chaos? Rev Bras Otorrinolaringol. 2021;87(2):125-6. PMid:33500207.⁾.

The findings of this research confirm current evidence derived from the assessment of patients with chronic tinnitus who have normal thresholds up to 8 kHz. It is important that hearing professionals understand how multiple evaluations, with rapid testing, open the way for providing a better diagnosis and ultimately, perhaps, remission of the condition⁽⁴4 Valim CCA, Sanchez TG. The tinnitus total remission: targeting treatment to the etiological hypothesis. J Otorinolaringol ENT Res. 2018;10(3):153-5. http://dx.doi.org/10.15406/joentr.2018.10.00335.
http://dx.doi.org/10.15406/joentr.2018.1... ⁾.

Study Limitation

In addition to the small number of samples, it was not possible to perform frequency analyses in the FFR on the Smart EP equipment, due to the unavailability of the BioMark™ program. This work also highlights a need to characterize such procedures in individuals with tinnitus who have also suffered COVID-19, as these subjects my react differently to those tested here.

CONCLUSION

Using HFA, analysis of the wave V/I ratio in ABR, the FFR, and the LLAEP, we could detect alterations in individuals with chronic tinnitus. Our findings have shown that such procedures are promising tools in evaluating subjects with tinnitus.

Study carried out at Curso de Fonoaudiologia, Departamento de Fonoaudiologia, Universidade Federal de Santa Maria - UFSM - Santa Maria (RS), Brasil.
Funding: None.

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³³
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» http://dx.doi.org/10.3389/fnagi.2017.00224
³⁴
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» http://dx.doi.org/10.3389/fnins.2019.01010
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Publication Dates

Publication in this collection
07 Nov 2022
Date of issue
2022

History

Received
13 Apr 2022
Accepted
08 Sept 2022

Este é um artigo publicado em acesso aberto (Open Access) sob a licença Creative Commons Attribution Non-Commercial , que permite uso, distribuição e reprodução em qualquer meio, sem restrições desde que sem fins comerciais e que o trabalho original seja corretamente citado.

[1] Study carried out at Curso de Fonoaudiologia, Departamento de Fonoaudiologia, Universidade Federal de Santa Maria - UFSM - Santa Maria (RS), Brasil.

[2] Funding: None.

HFA dBSPL	Group	n	Average	Median	Mín	Max	SD	CI (95%)	p-value
9 kHz	G1	22	13.86	15.00	0.00	20.00	5.96	(4.58; 8.52)	0.001*
9 kHz	G2	22	22.95	22.50	5.00	45.00	10.43	(8.02; 14.90)	0.001*
10 kHz	G1	22	16.59	15.00	5.00	25.00	6.25	(4.80; 8.92)	0.002*
10 kHz	G2	22	25.45	25.00	10.00	50.00	11.12	(8.55; 15.88)	0.002*
11 kHz	G1	22	12.05	12.50	0.00	25.00	9.59	(7.38; 13.71)	<0.001*
11 kHz	G2	22	27.50	27.50	10.00	50.00	9.35	(7.19; 13.36)	<0.001*
12 kHz	G1	22	10.91	5.00	0.00	35.00	11.30	(8.69; 16.14)	<0.001*
12 kHz	G2	22	31.36	30.00	15.00	55.00	10.82	(8.32; 15.46)	<0.001*
13 kHz	G1	22	16.14	12.50	0.00	40.00	12.24	(9.41; 17.49)	<0.001^* * Statistically significant values (p ≤ 0.05)
13 kHz	G2	22	42.27	45.00	20.00	75.00	13.95	(10.73; 19.93)	<0.001^* * Statistically significant values (p ≤ 0.05)
14 kHz	G1	22	28.18	30.00	5.00	45.00	10.86	(8.35; 15.52)	<0.001*
14 kHz	G2	22	53.86	52.50	20.00	90.00	21.15	(16.27; 30.22)	<0.001*
15 kHz	G1	22	32.50	32.50	10.00	55.00	14.62	(11.24; 20.89)	<0.001*
15 kHz	G2	22	59.77	57.50	10.00	100.00	24.42	(18.78; 34.89)	<0.001*
16 kHz	G1	22	38.86	37.50	10.00	60.00	16.03	(12.33; 22.90)	<0.001*
16 kHz	G2	22	68.86	72.50	10.00	100.00	25.82	(19.86; 36.89)	<0.001*
17 kHz	G1	22	50.68	50.00	10.00	90.00	18.34	(14.11; 26.21)	0.001*
17 kHz	G2	22	75.45	82.50	25.00	105.00	24.92	(19.17; 35.61)	0.001*
18 kHz	G1	22	61.36	60.00	5.00	90.00	21.83	(16.79; 31.19)	0.023*
18 kHz	G2	22	77.27	77.50	20.00	105.00	22.98	(17.67; 32.83)	0.023*

ABR	Variables	Groups	N	Average	Median	Mín	Máx	SD	CI (95%)	p-value
ms	wave I	G1	22	1.57	1.55	1.4	1.8	0.1	(0.07; 0.14)	0.791
	wave I	G2	20	1.57	1.55	1.4	1.75	0.09	(0.07; 0.13)	0.791
	wave III	G1	22	3.75	3.80	3.45	4	0.2	(0.15; 0.28)	0.338
	wave III	G2	22	3.8	3.79	3.5	4.2	0.18	(0.13; 0.25)	0.338
	Wave V	G1	22	5.68	5.69	5.35	5.98	0.2	(0.15; 0.28)	0.835
	Wave V	G2	22	5.69	5.74	5.33	5.95	0.2	(0.15; 0.28)	0.835
	I-III	G1	22	2.17	2.14	1.75	2.55	0.23	(0.17; 0.32)	0.385
	I-III	G2	19	2.23	2.23	1.9	2.65	0.17	(0.12; 0.25)	0.385
	III-V	G1	22	1.93	1.95	1.5	2.25	0.14	(0.10; 0.20)	0.399
	III-V	G2	22	1.89	1.89	1.7	2.25	0.13	(0.09; 0.18)	0.399
	I-V	G1	22	4.1	4.10	3.72	4.45	0.2	(0.15; 0.28)	0.713
	I-V	G2	19	4.13	4.18	3.73	4.4	0.2	(0.15; 0.30)	0.713
µV	amp I	G1	22	0.3	0.29	0.11	0.63	0.11	(0.08; 0.16)	0.182
	amp I	G2	22	0.25	0.24	0.07	0.45	0.11	(0.08; 0.15)	0.182
	amp V	G1	22	0.47	0.48	0.24	0.77	0.14	(0.11; 0.20)	0.802
	amp V	G2	22	0.46	0.48	0.24	0.74	0.14	(0.10; 0.20)	0.802
	ratio V/I	G1	22	1.77	1.58	0.57	4.27	0.8	(0.61; 1.14)	0.179
	ratio V/I	G2	22	2.14	2.00	0.62	4.43	0.99	(0.76; 1.42)	0.179

	FFR		Average	Median	SD	Min	Max	N	CI	p-value
ms	V	G1	6.08	6.25	0.71	4.5	6.88	11	0.42	0.079
	V	G2	6.89	6.63	1.24	5.88	10.25	10	0.77	0.079
	A	G1	8.2	7.88	1.18	6.38	10.88	11	0.7	0.377
	A	G2	8.67	8.32	1.18	7.5	11.75	10	0.73	0.377
	C	G1	17.16	17.38	1.13	14.88	19	11	0.67	0.935
	C	G2	17.21	17.38	1.42	15.25	20.13	11	0.84	0.935
	D	G1	22.62	22.63	1.68	18.5	25.25	11	0.99	0.377
	D	G2	23.33	22.63	1.66	21.5	26.63	8	1.15	0.377
	E	G1	31.48	31.38	1.5	29	33.38	11	0.89	0.377
	E	G2	31.98	31.94	0.91	30.75	33.25	10	0.56	0.377
	F	G1	39.83	39.88	0.82	38.88	41.5	11	0.48	0.184
	F	G2	40.39	39.94	1.03	39.38	42	10	0.64	0.184
	O	G1	48.5	48.75	0.88	47.38	50.5	11	0.52	0.306
	O	G2	49.15	48.5	1.75	47.87	53.38	9	1.14	0.306
	Slope	G1	0.184	0.184	0.1	0.041	0.38	11	0.059	0.717
	Slope	G2	0.169	0.16	0.067	0.06	0.302	9	0.044	0.717
	V-A	G1	2.12	1.63	1.08	1.25	4.63	11	0.64	0.374
	V-A	G2	1.77	1.63	0.51	1.25	2.87	10	0.32	0.374
	A-C	G1	8.96	9.62	1.86	5.37	11.5	11	1.1	0.744
	A-C	G2	8.74	8.63	1.16	7.25	10.38	10	0.72	0.744
	C-D	G1	5.72	5.25	2.15	2.12	8.5	11	1.27	0.896
	C-D	G2	5.59	5.37	2.15	2.5	8.13	8	1.49	0.896
	D-E	G1	8.55	8.5	2.5	5.62	14.12	11	1.48	0.85
	D-E	G2	8.36	8.87	1.38	5.25	9.37	8	0.95	0.85
	E-F	G1	8.35	8.38	1.48	6.5	11.13	11	0.87	0.903
	E-F	G2	8.41	8.38	0.45	7.75	9.13	10	0.28	0.903
	F-O	G1	8.44	8	0.93	7.25	10.5	11	0.55	0.717
	F-O	G2	8.62	8.31	1.31	7.12	12.13	10	0.81	0.717
	V-O	G1	42.42	42.12	1.37	41.12	45.5	11	0.81	0.206
	V-O	G2	41.52	41.74	1.71	37.75	44.12	9	1.12	0.206
µV	V	G1	0.214	0.19	0.064	0.1	0.3	11	0.038	0.041^* * Statistically significant values (p ≤ 0.05)
	V	G2	0.138	0.11	0.09	0.05	0.34	9	0.059	0.041^* * Statistically significant values (p ≤ 0.05)
	A	G1	-0.133	0.11	0.083	-0.01	-0.32	11	0.049	0.511
	A	G2	-0.157	0.16	0.082	-0.01	-0.29	10	0.051	0.511
	C	G1	-0.136	0.13	0.073	-0.01	-0.27	11	0.043	0.708
	C	G2	-0.15	0.11	0.094	-0.03	-0.3	11	0.056	0.708
	D	G1	-0.119	0.09	0.098	-0.03	-0.31	11	0.058	0.97
	D	G2	-0.118	0.14	0.073	-0.01	-0.19	8	0.05	0.97
	E	G1	-0.195	0.2	0.088	-0.01	-0.33	11	0.052	0.152
	E	G2	-0.249	0.23	0.075	-0.17	-0.43	10	0.046	0.152
	F	G1	-0.196	0.19	0.069	-0.08	-0.28	11	0.041	0.735
	F	G2	-0.232	0.22	0.124	-0.09	-0.48	10	0.077	0.735
	O	G1	-0.123	0.08	0.13	-0.02	-0.47	11	0.077	0.293
	O	G2	-0.176	0.17	0.09	-0.04	-0.35	10	0.056	0.293

LLAEP	Variable	Group	n	Average	Median	Mín	Máx	SD	CI (95%)	p-value
ms	P1	G1	22	53.55	52	50	67	4.64	(3.56; 6.62)	0.141
	P1	G2	12	56.5	52.5	50	67	6.76	(4.79; 11.48)	0.141
	N1	G1	22	100.45	98.5	80	116	9.54	(7.34; 13.63)	0.529
	N1	G2	22	102.23	102	86	121	8.96	(6.89; 12.80)	0.529
	P2	G1	22	183.32	181.5	153	222	19.37	(14.90; 27.68)	0.312
	P2	G2	22	189.64	189.5	153	217	21.49	(16.53; 30.71)	0.312
	N2	G1	22	257.77	257.5	212	297	26.58	(20.44; 37.98)	0.734
	N2	G2	15	253.67	268	192	302	46.32	(33.91; 73.05)	0.734
	P3	G1	22	312.14	315.5	253	371	33.52	(25.78; 47.90)	0.003^* * Statistically significant values (p ≤ 0.05)
	P3	G2	12	307.33	319.5	229	355	39.93	(28.28; 67.79)	0.003^* * Statistically significant values (p ≤ 0.05)
µV	P1-N1	G1	22	4.89	4.96	2.23	7.9	1.83	(1.40; 2.61)	0.061
	P1-N1	G2	8	6.64	6.25	3.63	10.97	2.97	(1.96; 6.04)	0.061
	N1-P2	G1	22	7.89	7.82	3.05	13.36	3.25	(2.50; 4.64)	0.699
	N1-P2	G2	17	8.3	6.88	4.1	14.9	3.27	(2.43; 4.98)	0.699
	P2-N2	G1	22	5.03	4.82	1.37	7.49	1.34	(1.02; 1.91)	0.913
	P2-N2	G2	13	4.94	4.05	1.01	11.17	3.52	(2.52; 5.80)	0.913
	P3	G1	22	6.02	4.45	3.01	14.4	3.3	(2.54; 4.72)	0.246
	P3	G2	11	7.87	5.56	3	20.42	5.73	(4.00; 10.05)	0.246

Variables	G1	G2	p-value
Number of ears	22	22
Age	40.4	44	0.43
Gender (number)
Male	6	2	0.183
Female	5	9

		Group 1		Group 2		Total		p-value
		n	%	n	%	N	%	p-value
TOAE	No	0	0%	4	18%	4	9%	0.138
TOAE	Yes	22	100%	18	82%	40	91%	0.138

LLAEP (ms)		G1		G2		Total		p-value
LLAEP (ms)		n	%	n	%	n	%	p-value
P1	Absence	0	0%	10	45%	10	22.72%	<0.001*
P1	Presence	22	100%	12	55%	34	72.27%	<0.001*
N1	Absence	0	0%	0	0%	0	0%	NA
N1	Presence	22	100%	22	100%	44	100%	NA
P2	Absence	0	0%	0	0%	0	0%	NA
P2	Presence	22	100%	22	100%	44	100%	NA
N2	Absence	0	0%	7	31.81%	7	15.90%	0.003^* * Statistically significant values (p ≤ 0.05)
N2	Presence	22	100%	15	68.18%	37	84.09%	0.003^* * Statistically significant values (p ≤ 0.05)
P3	Absence	0	0%	10	45%	10	22.72%	<0.001*
P3	Presence	22	100%	12	55%	34	72.27%	<0.001*

Brasil

Brasil

Chronic tinnitus: analysis of clinical contributions from different audiological evalutions

ABSTRACT

Purpose

Methods

Results

Conclusion

RESUMO

Objetivo

Métodos

Resultados

Conclusão

INTRODUCTION

METHODS

Eligibility criteria

Evaluation procedures

Procedures

High frequency audiometry (HFA)

Transient-evoked otoacoustic emissions (TEOAEs)

Electrophysiological assessment

ABR Auditory Brainstem Response (ABR)

Frequency following responses (FFRs)

Long Latency Auditory Evoked Potential (LLAEP)

RESULTS

DISCUSSION

Study Limitation

CONCLUSION

REFFERÊNCIAS

Publication Dates

History