Role of the medial olivocochlear system among children with ADHD

Pereira, Valéria Reis do Canto; Feitosa, Maria Ângela Guimarães; Pereira, Luiz Henrique Mourão do Canto; Azevedo, Marisa Frasson de

doi:10.1590/S1808-86942012000300006

Abstracts

Attention deficit hyperactivity disorder (ADHD) patients show, as one of the main symptoms, an attentional impairment. Selective attention in the hearing process is the ability to understand speech in a noisy environment, which can be evaluated by several methods. One of the main approaches is the functioning of the Medial Olivocochlear Efferent System, which can be accessed by Transient-Evoked Otoacoustic Emissions (TOAE). OBJECTIVE:This study aimed at evaluating the suppression effect of contralateral noise on TOAE in ADHD (study group) and normal subjects (control group). Study Design: Case-control study. MATERIAL AND METHODS: A study with 20 children distributed in two, age- and gender-matched groups. RESULTS: No differences were found in TOAE responses between the two groups, with and without noise. CONCLUSIONS: We conclude that there were no functional differences in the Medial Olivocochlear Efferent System in the two groups analyzed.

attention deficit disorder with hyperactivity; child; efferent pathways; otoacoustic emissions; spontaneous; supression

Crianças portadoras de Transtorno do Déficit de Atenção/Hiperatividade (TDAH) apresentam como um de seus principais sintomas a dificuldade de atenção. Na audição, a Atenção Seletiva que se caracteriza por ser a capacidade de compreender a fala em ambientes ruidosos, pode ser avaliada de várias formas, salientando-se o funcionamento do Sistema Eferente Olivococlear Medial. Este sistema pode ser avaliado pelo exame de emissões otoacústicas (EOA). OBJETIVO: Este trabalho teve por objetivo verificar a ocorrência do efeito de supressão de EOA, caracterizado pela diminuição da amplitude de resposta das emissões otoacústicas evocadas por estímulo transiente (EOAT) em resposta a apresentação de ruído contralateral, em crianças com TDAH (grupo estudo) e normais (grupo controle). Forma de Estudo: Estudo caso-controle. MATERIAL E MÉTODO: Foi realizado um estudo com 20 crianças alocadas em dois grupos de 10 crianças, pareadas por sexo e idade. Foi realizado o exame de EOAET sem e com ruído em ambos os grupos. RESULTADOS: Não houve diferença nas respostas das EOAET sem e com ruído, entre os grupos estudados. CONCLUSÕES: Pôde-se concluir que não há diferenças no funcionamento do Sistema Eferente Olivococlear Medial nas crianças com transtorno do déficit de atenção/hiperatividade em relação às crianças normais.

criança; emissões otoacústicas espontâneas; supressão; transtorno do deficit de atenção com hiperatividade; vias eferentes

ORIGINAL ARTICLE

^IPh.D. in Psychology (Behavior and Neurosciences) - University of São Paulo (Full Researcher/Collaborator at the Department of Basic Psychological Processes of the Psychology Institute - University of Brasilia)

^IIPh.D. in Psychology (Psychobiology) - The University Of Michigan (Full Professor - Department of Basic Psychological Processes of the Psychology Institute - University of Brasília)

^IIIPost-Doctorate - Medical School of the University of São Paulo General Coordinator of Biotechnology and Health - Ministry of Sciences and Technology)

^IVPh.D. in Human Communications Disorders - Federal University of São Paulo (Associate Professor - Department of Speech and Hearing Therapy - Federal University of São Paulo)

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ABSTRACT

Attention deficit hyperactivity disorder (ADHD) patients show, as one of the main symptoms, an attentional impairment. Selective attention in the hearing process is the ability to understand speech in a noisy environment, which can be evaluated by several methods. One of the main approaches is the functioning of the Medial Olivocochlear Efferent System, which can be accessed by Transient-Evoked Otoacoustic Emissions (TOAE).

OBJECTIVE:This study aimed at evaluating the suppression effect of contralateral noise on TOAE in ADHD (study group) and normal subjects (control group). Study Design: Case-control study.

MATERIAL AND METHODS: A study with 20 children distributed in two, age- and gender-matched groups.

RESULTS: No differences were found in TOAE responses between the two groups, with and without noise.

CONCLUSIONS: We conclude that there were no functional differences in the Medial Olivocochlear Efferent System in the two groups analyzed.

Keywords: attention deficit disorder with hyperactivity, child, efferent pathways, otoacoustic emissions, spontaneous, supression.

INTRODUCTION

The Attention Deficit/Hyperactivity Disorder (ADHD) is described by the American Psychiatric Association - APA¹ as "a persistent pattern of attention deficit and/or hyperactivity, more frequent than what is usually seen in the equivalent level of development". According to the APA, attention deficit and hyperactivity/impulsiveness symptoms manifest in different degrees and, in order to be classified as ADHD, they must manifest before 7 years of age; besides impacting in social development and functioning, academic and occupational lives of individuals, the losses must be present in at least two contexts such as, for example, at home and at school. Still, according to the APA, the ADHD is more frequent in males and its prevalence is estimated to be between 3% and 5% in school aged-children.

Children with ADHD have attention deficit as one of their main symptoms. Attention plays a role in the selection of some stimuli, providing the better processing of them. As far as hearing is concerned, selective attention is the ability to understand speech in noisy environments, and it can be assessed in different ways - one of them is the workings of the Medial Olivocochlear System Efferent.

The Medial Olivocochlear System Efferent has been studied especially because of its role in selective attention. This system can be assessed by the Otoacoustic Emissions Test, which involves low intensity sounds captured in the external acoustic meatus, associated with the mobility and mechanical ability of the external hair cells, apparently managed by the efferent pathways of the olivocochlear system. Otoacoustic emissions may be evoked by transient stimuli (click) which, because of having a broad array of frequencies, stimulates the entire cochlea (TEOAE).

Contralateral noise affects the transient evoked otoacoustic emissions (TEOAE) and it activates the efferent paths of the olivocochlear emissions, impacting the cochlear process responsible for the generation of the TEOAE, which represents suppression. This suppression effect was noticed by numerous authors such as the reduction in the response level of spontaneous and evoked otoacoustic emissions with the use of contralateral acoustic stimulation^2,3.

Ryan et al.³ reported that contralateral acoustic stimulation reduces TEOAE amplitude. This phenomenon may be mediated by the medial olivocochlear efferent system and, thus, its presence may be used to assess the integrity of the neural communication from one cochlea to another.

Some functions of the medial olivocochlear efferent system involve its role in the efficiency of signal capture in the presence of simultaneous noise, in the protection against lesions caused by high noise, in the control of the cochlear mechanical status and in auditory attention⁴.

Pillsbury et al.⁵ suggested that a reduction in auditory processing test performance involving the binaural process assessment may be a sensitive indicator of an "attention disorder" in patients with ADHD. The authors state that children with ADHD have a bad performance in the presence of the signal, because of a failure at this stage in the auditory processing.

Since there is a possibility of the medial olivocochlear efferent system be related to the ability of selective attention there was an interest in studying the function of such system in children diagnosed with ADHD. Moreover, there is a scarcity of papers associating this suppression effect in ADHD patients.

The present study aimed at comparing, by means of TEOAE, the suppression effect of the medial olivocochlear efferent system by contralateral auditory stimulation in normal children and in those with ADHD.

MATERIALS AND METHODS

We recruited 30 children, of whom 20 participated in the study. They were divided in two groups, one made up of 10 children with ADHD and another made up of 10 children without ADHD (Control). The study was of the case-control type. The two groups were paired by gender and age. Each group was made up by three female and seven male children. The mean age of the children in the group was 9.8 years (Standard Deviation (SD) = 1.8 years) and that of the control group was 9.7 years (SD = 1.9 years). The study was carried out in the university clinic, after its approval by the Ethics in Research Committee of the Institution (Protocol # 0398/03) and the Informed Consent Form was signed by the guardians of the children from both groups.

As main complaints, the participants had difficulties in paying attention and, after having been diagnosed by a pediatric neurologist as having ADHD using the diagnostic criteria of DSM IV, they were referred for assessment by TEOAE. The group inclusion criteria were: otoscopy, immittance, normal bilateral tonal audiometry and the presence of TEOAE. The inclusion criteria for the ADHD group were the same inclusion criteria used for the Control group; however, its participants had a diagnosis of ADHD without the use of medication to treat the disorder. Exclusion criteria for both groups were: changes found in otoscopy, immittance measures, tonal audiometry and no TEOAE.

TEOAE measures were carried out using the ILO 96 cochlear emissions analyzer, from OTODYNAMICS, version 5.60, with the help of a probe fit to the external acoustic meatus of the subject, in an acoustic booth with sound insulation. We used a non-linear click stimulus in dBSPL, with regular 80 µs pulses, of rarefaction polarity, at a frequency of 50 Hertz (Hz). The stimulus intensity was 75 to 83 dBSPL, in sync with the procedures used by other authors^6,7. For the contralateral acoustic stimulation, we used the continuous white noise transmitted by means of a MAICO 17, ANSI-69 standard audiometer, through a TDH-39 phone at 50 dBSPL. The phone was coupled to the ear contralateral to the otoacoustic emissions prior to beginning the measuring, thus avoiding manipulating the probe between the different phases of assessment.

The response acceptance criteria were chosen according to the criteria adopted in the current literature, and were 70% higher in percentage of reproducibility values^6,8 and test tone probe setting stability higher than 70%⁹, representing a comparison of the level of stimulation recorded in the external acoustic meatus from test onset all the way to its conclusion. The number of stimuli utilized during TEOAE recording did not vary (260 series of four clicks), following the order of recording TEOAE in the right ear without and with a contralateral white noise; and with and without a contralateral noise for the left ear.

We used TEOAE, in the absence and presence of contralateral white noise, in both ears of all individuals in the sample. The responses were considered present when the signal/noise ratio was higher than 3 dB in the frequencies of 1000 Hz, 1500 Hz, 2000 Hz, 3000 Hz and 4000 Hz. In order to observe the suppression effect, we recorded the TEOAE with and without noise and we assessed the occurrence of changes in the TEOAE response level. We considered the presence of the suppression effect when there was a reduction greater than or equal to 1 dB from the response level with contralateral white noise.

For statistical purposes, we used the Wilcoxon, Mann Whitney Y and Equality of Two Proportions tests, adopting a significance level of 0.05%.

RESULTS

In order to better understand the results obtained, their descriptions were organized in two parts, first checking the ear effect and, following, the group effect and stimulation settings.

Comparing the Transient Evoked Otoacoustic Emissions in the Study and Control groups in relation to the Ear variable

The result shows the comparison between the Right (RE) and Left (LE) ears for the study (Table 1) and control (Table 2) groups in relation to amplitude and TEOAE differences with and without noise. There were no statistically significant differences between the groups.

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Since we found no statistically significant difference between the ears in relation to the variables, the analysis started to be done together for both ears.

Comparing the Transient Evoked Otoacoustic Emissions between the Study and Control groups

At this stage, we tried to see whether there was any difference in TEOAE responses without and with noise between the children of the control and those of the study group. There were no statistically significant differences between the groups. The results from this analysis are depicted on Table 3.

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Following that, we tried to see if TEOAE differences without and with noise were different between the Study and Control groups. There were statistically significant differences between the groups. The results from this analysis are depicted on Table 4.

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We tried to investigate the quantification of the suppression effect for the right ear, left ear, and for both ears, from the study and control groups. There was no statistically significant difference between the groups. The results from these analyses are presented on Table 5.

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DISCUSSION

The present study included ten children with ADHD - seven (70%) were boys, pointing to a greater prevalence of this disorder among males^1,10,11,12.

Initially, we tried to check whether the TEOAE without and with noise and the differences obtained without and with noise varied in relation to ear side (RE x LE), in both groups. There was no statistically significant difference in the Study group (Table 1) or in the Control group (Table 2). After having these results, the data from the two ears were combined, according to Burguetti & Carvallo¹³.

We investigated if the TEOAE amplitudes without and with noise varied between the two groups (Table 3). The results showed that there were no statistically significant differences between the groups. In both groups, the responses with noise were lower than those without noise, corroborating the findings from numerous authors^3,14-16.

Following that, we noticed that the values of the differences obtained without and with noise varied between the groups. There were no statistically significant differences between the groups (Table 4), corroborating other studies carried out^17,18.

The quantification of the suppression effect was studied for both ears separately. The statistical analysis carried out for the Right Ear (RE), Left Ear (LE) and both ears (RE+LE) did not show statistically significant differences between the groups studied (Table 5). Although it was not the objective of the present study to compare the suppression effect between RE and LE, the studies from Khalfa & Collet¹⁹ and Fávero²⁰showed that there is a greater activity of the right side efferent system; however, Rabinovich²¹noticed a significant statistically significant difference for the LE.

According to the results fond in our study, they suggest there were no significant difference in the workings of the medial olivocochlear efferent system in the group with ADHD children, when compared to children of the same age and without such diagnosis. With our findings we can infer that the priority attentional involvement in ADHD patients are not of auditory sensorial mode; however, in order to confirm this hypothesis it would be important to broaden the number of cases studied.

We may also question whether auditory attention complaints in ADHD patients are associated with the existence of comorbid disorders, such as, for example, Central Auditory Processing Disorder, having that in many patients with ADHD this comorbidity was present^22,23.

Current literature shows a straight relationship of the superior olivary complex with the ability of sound location in space²⁴. Based on this fact and on the data found in our study, we suggest the investigation of the olivocochlear efferent system by means of other measures, such as those of behavioral nature, in order to check for occasional difficulties in the auditory perception of patients with ADHD.

We did the present study starting from the principle that one of the ways used to assess Auditory Selective Attention happens through the analysis of the Medial Olivocochlear efferent system and that children with ADHD had important loss in attention.

As we studied the functioning of this system in ADHD children and in normal children, we could conclude that the TEOAE and the differences obtained without and with noise were similar in both groups studied. Thus, it has been suggested that there are no differences in the functioning of the medial olivocochlear efferent system in the children with attention deficit hyperactivity disorder, when compared to normal children; however, there is a need to go more in depth in this hypothesis by means of other methods capable of assessing the auditory function of ADHD patients such as, for example, the use of behavioral measures.

CONCLUSIONS

The suppression effect which assesses the functioning of the medial olivocochlear efferent system by TEOAE with and without noise in children with ADHD did not show any difference when compared to the Control group in the present study. We did not find evidence, in this sample, that the medial olivocochlear efferent system is impacted in the presence of ADHD.

REFERENCES

¹
Diagnostic and Statistical Manual of Mental Disorders. 4th Text Revision (DSM-IV-TR). American Psychiatric Association: Washington; 2000.
2. Harrison WA, Burns EM. Effects of contralateral acoustic stimulation on spontaneous otoacoustic emissions. J Acoust Soc Am. 1993;94(5):2649-58.
3. Ryan S, Kemp DT, Hinchcliffe R. The influence of contralateral acoustic stimulation on click-evoked otoacustic emission in humans. Br J Audiol. 1991;25(6):391-7.
4. Bonaldi LV, De Angelis MA, Smith RL. Developmental study of the round window region. Acta Anat (Basel). 1997;159(1):25-9.
5. Pillsbury HC, Grose JH, Coleman WL, Conners CK, Hall JW. Binaural function in children with attention-deficit hyperactivity disorder. Arch Otolaryngol Head Neck Surg. 1995;121(12):1345-50.
6. Glattke TJ, Robinette MS. Transient evoked otoacustic emissions. In: Robinette MS, Glattke TJ. Otoacustic emissions-clinical applications. New York-Stuttgart: Thieme; 1997. p.63-81.
7. Silva C. A supressão da emissão otoacústica transiente na presença de ruído branco contralateral [monografia]. São Paulo: Universidade Federal de São Paulo, 1998.
8. Bonfils P, Uziel A. Clinical applications of evoked acoustic emissions: results in normally hearing and hearing-impaired subjects. Ann Otol Rhinol Laryngol. 1989;98(5 Pt 1):326-31.
9. Lopes Filho O, Carlos CR. Emissões otocaústicas. In: Lopes Filho O. Tratado de Fonoaudiologia. São Paulo: Rocca; 1997. p.221-37.
10. Wolraich ML, Hannah JN, Baumgaertel A, Feurer ID. Examination of DSM-IV criteria for attention deficit/hyperactivity disorder in a county-wide sample. J Dev Behav Pediatr. 1998;19(3):162-8.
11. Rohde LA. ADHD in Brazil: The DSM-IV criteria in a culturally different population. J Am Acad Child Adolesc Psychiatry. 2002;41(9):1131-3.
12. Vasconcelos MM, Werner Junior J, Malheiros AFA, Lima DFN, Santos ISO, Barbosa JB. Prevalência do transtorno do déficit de atenção/hiperatividade numa escola pública primária. Arq Neuropsiquiatr. 2003;61(1):67-73.
13. Burguetti FAR, Carvallo RMM. Efferent auditory system: its effect on auditory processing. Braz J Otorhinolaryngol. 2008;74(5):737-45.
14. Collet L, Kemp DT, Veuillet E, Duclaux R, Moulin A, Morgon A. Effect of contralateral auditory stimuli on active cochlear micro-mechanical properties in human subjects. Hear Res. 1990;43(2-3):251-62.
15. Thornton AR, Slaven A. The effect of stimulus rate on the contralateral suppression of transient evoked otoacoustic emissions. Scand Audiol. l995;24(2):83-90.
16. Leme VN, Carvallo RMM. Efeito da estimulação acústica contralateral nas medidas temporais das emissões otoacústicas. Rev CEFAC. 2009;11(Suppl 1).
17. Berlin CI, Hood LJ, Hurley A, Wen H. The First Jerger Lecture. Contralateral suppression of otoacustic emissions: an index of the function of medial olivocochlear system. Otolaryngol Head Neck Surg. 1994;110(1):3-21.
18. Ryan S, Kemp DT. The influence of stimulus level on the neural suppression of transient evoked otoacustic. Hear Res. 1996;94(1-2):140-7.
19. Khalfa S, Collet L. Functional asymmetry of medial olivocochlear system in humans. Towards a peripheral auditory lateralization. Neuroreport. 1996;7(5):993-6.
20. Fávero ML, Sanchez TG, Bento RF, Nascimento AF. Contralateral suppression of otoacoustic emission in patients with tinnitus. Braz J Otorhinolaryngol. 2006;72(2):223-26.
21. Rabinovich K. Estudo do efeito de supressão nas emissões otoacústicas evocadas transientes em indivíduos com audição normal e em portadores de esclerose múltipla. [dissertação]. São Paulo: Universidade Federal de São Paulo, Escola Paulista de Medicina; 1999.
22. Chermak GD, Hall JW 3rd, Musiek FE. Differential diagnosis and management of central auditory processing disorder and attention deficit hyperactivity disorder. J Am Acad Audiol. 1999;10(6):289-303.
23. Keller WD. Auditory processing disorder or attention-deficit? In: Katz J, Stecker N, Henderson D, editors. Central Auditory Processing: a Transdiciplinary View. St. Louis: Mosby Yearbook; 1992. p.107-14.
24. Larsen E, Liberman MC. Slow build-up of cochlear suppression during sustained contralateral noise: c¬entral modulation of olivocochlear efferents? Hear Res. 2009;256(1-2):1-10.

Role of the medial olivocochlear system among children with ADHD

Valéria Reis do Canto Pereira^I; Maria Ângela Guimarães Feitosa^II; Luiz Henrique Mourão do Canto Pereira^III; Marisa Frasson de Azevedo^IV

Publication Dates

Publication in this collection
12 June 2012
Date of issue
June 2012

History

Received
06 June 2011
Accepted
22 Sept 2011

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

[1] ¹
Diagnostic and Statistical Manual of Mental Disorders. 4th Text Revision (DSM-IV-TR). American Psychiatric Association: Washington; 2000.

[2] 2. Harrison WA, Burns EM. Effects of contralateral acoustic stimulation on spontaneous otoacoustic emissions. J Acoust Soc Am. 1993;94(5):2649-58.

[3] 3. Ryan S, Kemp DT, Hinchcliffe R. The influence of contralateral acoustic stimulation on click-evoked otoacustic emission in humans. Br J Audiol. 1991;25(6):391-7.

[4] 4. Bonaldi LV, De Angelis MA, Smith RL. Developmental study of the round window region. Acta Anat (Basel). 1997;159(1):25-9.

[5] 5. Pillsbury HC, Grose JH, Coleman WL, Conners CK, Hall JW. Binaural function in children with attention-deficit hyperactivity disorder. Arch Otolaryngol Head Neck Surg. 1995;121(12):1345-50.

[6] 6. Glattke TJ, Robinette MS. Transient evoked otoacustic emissions. In: Robinette MS, Glattke TJ. Otoacustic emissions-clinical applications. New York-Stuttgart: Thieme; 1997. p.63-81.

[7] 7. Silva C. A supressão da emissão otoacústica transiente na presença de ruído branco contralateral [monografia]. São Paulo: Universidade Federal de São Paulo, 1998.

[8] 8. Bonfils P, Uziel A. Clinical applications of evoked acoustic emissions: results in normally hearing and hearing-impaired subjects. Ann Otol Rhinol Laryngol. 1989;98(5 Pt 1):326-31.

[9] 9. Lopes Filho O, Carlos CR. Emissões otocaústicas. In: Lopes Filho O. Tratado de Fonoaudiologia. São Paulo: Rocca; 1997. p.221-37.

[10] 10. Wolraich ML, Hannah JN, Baumgaertel A, Feurer ID. Examination of DSM-IV criteria for attention deficit/hyperactivity disorder in a county-wide sample. J Dev Behav Pediatr. 1998;19(3):162-8.

[11] 11. Rohde LA. ADHD in Brazil: The DSM-IV criteria in a culturally different population. J Am Acad Child Adolesc Psychiatry. 2002;41(9):1131-3.

[12] 12. Vasconcelos MM, Werner Junior J, Malheiros AFA, Lima DFN, Santos ISO, Barbosa JB. Prevalência do transtorno do déficit de atenção/hiperatividade numa escola pública primária. Arq Neuropsiquiatr. 2003;61(1):67-73.

[13] 13. Burguetti FAR, Carvallo RMM. Efferent auditory system: its effect on auditory processing. Braz J Otorhinolaryngol. 2008;74(5):737-45.

[14] 14. Collet L, Kemp DT, Veuillet E, Duclaux R, Moulin A, Morgon A. Effect of contralateral auditory stimuli on active cochlear micro-mechanical properties in human subjects. Hear Res. 1990;43(2-3):251-62.

[15] 15. Thornton AR, Slaven A. The effect of stimulus rate on the contralateral suppression of transient evoked otoacoustic emissions. Scand Audiol. l995;24(2):83-90.

[16] 16. Leme VN, Carvallo RMM. Efeito da estimulação acústica contralateral nas medidas temporais das emissões otoacústicas. Rev CEFAC. 2009;11(Suppl 1).

[17] 17. Berlin CI, Hood LJ, Hurley A, Wen H. The First Jerger Lecture. Contralateral suppression of otoacustic emissions: an index of the function of medial olivocochlear system. Otolaryngol Head Neck Surg. 1994;110(1):3-21.

[18] 18. Ryan S, Kemp DT. The influence of stimulus level on the neural suppression of transient evoked otoacustic. Hear Res. 1996;94(1-2):140-7.

[19] 19. Khalfa S, Collet L. Functional asymmetry of medial olivocochlear system in humans. Towards a peripheral auditory lateralization. Neuroreport. 1996;7(5):993-6.

[20] 20. Fávero ML, Sanchez TG, Bento RF, Nascimento AF. Contralateral suppression of otoacoustic emission in patients with tinnitus. Braz J Otorhinolaryngol. 2006;72(2):223-26.

[21] 21. Rabinovich K. Estudo do efeito de supressão nas emissões otoacústicas evocadas transientes em indivíduos com audição normal e em portadores de esclerose múltipla. [dissertação]. São Paulo: Universidade Federal de São Paulo, Escola Paulista de Medicina; 1999.

[22] 22. Chermak GD, Hall JW 3rd, Musiek FE. Differential diagnosis and management of central auditory processing disorder and attention deficit hyperactivity disorder. J Am Acad Audiol. 1999;10(6):289-303.

[23] 23. Keller WD. Auditory processing disorder or attention-deficit? In: Katz J, Stecker N, Henderson D, editors. Central Auditory Processing: a Transdiciplinary View. St. Louis: Mosby Yearbook; 1992. p.107-14.

[24] 24. Larsen E, Liberman MC. Slow build-up of cochlear suppression during sustained contralateral noise: c¬entral modulation of olivocochlear efferents? Hear Res. 2009;256(1-2):1-10.