Speech auditory brainstem response (speech ABR) in the differential diagnosis of scholastic difficulties☆

Sanfins, Milaine Dominici; Borges, Letícia Reis; Ubiali, Thalita; Colella-Santos, Maria Francisca

doi:10.1016/j.bjorl.2015.05.014

Introduction

Learning spoken and written language depends on the assimilation of acoustic elements and the representation of phonetic characteristics of a language.¹1 Regaçone SF, Gução ACB, Giacheti CM, Romero ACL, Frizzo ACF. Potenciais evocados auditivos de longa latência em escolares com transtornos específicos de aprendizagem. Audiol Commun Res. 2014;19:13-8. Auditory processing, phonological awareness, and auditory discrimination are factors that affect the learning of reading and writing, because they are directly related to receptive hearing.²2 Halliday LF, Bishop DVM. Is poor frequency modulation detection linked to literacy problems? A comparison of specific reading disability and mild to moderate sensorineural hearing loss. Brain Lang. 2006;9:200-13. Researchers have associated the presence of learning disabilities with hearing deficits in children.³3 Cacace AT, McFarland DJ. Central auditory processing disorder in school-aged children: a critical review. J Speech Lang Hear Res. 1998;41:355-73.

After an acoustic stimulation, electrophysiological evaluation of hearing can establish an anatomical and functional correlation in the central auditory nervous system that occurs through the activation of several structures throughout the system. Thus, in cases of learning disabilities, an analysis of the integrity and function of the auditory pathways is recommended.⁴4 Musiek FE, Shinn J, Hare C. Plasticity, auditory training and auditory processing disorders. Semin Hear. 2002;23:263-75.

Speech auditory brainstem response (Speech ABR) testing can be elicited by a wide variety of sound stimuli: click, pure tone, masked tone, and complex sounds (speech). Studies have documented the normal responses using the click stimuli in children with learning disabilities; however, recent studies suggest the presence of alterations in response to speech stimuli, due to the existence of subcortical deficits associated with learning disorders.⁵5 Abrams DA, Nicol T, Zecker SG, Kraus N. Rapid acoustics processing in the auditory brainstem is not related to cortical asymmetry for the syllable rate of speech. Clin Neurophysiol. 2010;121:1343-50.^–⁷7 Johnson KL, Nicol T, Kraus N. The brainstem response to speech: a biological marker of auditory processing. Ear Hear. 2005;26:424-34.

Case report

The subjects selected for this study were individuals with scholastic difficulties with a discrepancy between ability and academic performance. The diagnosis was based on a long and detailed study carried out by a multidisciplinary team, consisting of a psychologist, speech therapist, educational psychologist, physical therapist, psychomotrician, neurologist, and psychiatrist of the Research Laboratory of Learning Disorders, Disabilities, and Attention Deficit Disorder of the Faculdade de Ciências Médicas (Laboratório de Pesquisa em Distúrbios, Dificuldades de Aprendizagem e Transtorno de Atenção da Faculdade de Ciências Médicas – DISAPRE) of the Universidade Estadual de Campinas (UNICAMP), Campinas, São Paulo, Brazil. The diagnosis was finalized after ruling out genetic, organic, psychological, and psychiatric disorders that could cause those alterations. The present study reports two male cases (10 and 11 years old) who were assessed for a Master Degree's dissertation. The parents/guardians were informed of the study goals and signed the free and informed consent form No. 431,184/2013.

A basic audiological evaluation was performed and the results were within the normal range, bilaterally. At the behavioral assessment of auditory processing (AP), an alteration was identified in the auditory abilities of figure-ground for verbal sounds, temporal ordering, and temporal resolution (Table 1), whereas at the AP electrophysiological evaluation, the responses were within the normal range in the ABR (click) and long latency responses (LLR; Table 2) were observed. The results of transient otoacoustic emissions (TOAEs) and distortion product otoacoustic emissions (DPOAEs) were normal bilaterally.

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Table 1
Assessment values of auditory processing.

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Table 2
Values of the performed hearing assessments.

ABR with speech stimuli was carried out with the synthesized syllable /da/, at a rate of 10.9 stimuli per second, provided by the BioMARK™ software of the Biologic device. A total of 6000 stimuli were given in two bursts of 3000, and the analysis was performed on the sum of the tracing. The stimuli were applied through an insertion phone in the right ear at 80 SPL (sound pressure level), because of the known superiority of the left hemisphere for speech processing.⁸8 Hornickel J, Skoe E, Nicol T, Zecker S, Kraus N. Subcortical differentiation of stop consonants relates to reading and speech-in-noise perception. Proc Natl Acad Sci. 2009;106:13022-7.

The stimulus consisted of the consonant /d/ (transient portion – onset) and a short vowel /a/ (sustained portion – frequency following response). The C waveform represents the transition between consonant and vowel, whereas the O wave represents the end of the vowel (Fig. 1). After the collection, the latency and amplitude of the transient portion (V and A waves) and the VA slope (VA amplitude/VA duration) were analyzed using the normative BioMARK™ wave as the basis for analysis. In both cases, abnormal responses were observed in the latency values of the waves V, A, and VA slope (Figs. 2 and 3).

Figure 1
Representation of electrophysiological response to synthesized syllable /da/. Personal file of the investigator of an assessment performed with BioMARK™ software.

Figure 2
Brainstem-evoked response audiometry with speech stimulus and altered responses. Researcher's data from a male patient (10 years old).

Figure 3
Auditory brainstem response (ABR) with speech stimulus and abnormal responses. Researcher's data from a male patient (11 years old).

Discussion

In the analysis of the results, ABR with click stimulus were normal in both cases, in agreement with studies in the literature that indicate that only the processes involved in encoding speech signals in the brainstem region are altered in children with learning disabilities. These results show that the ABR with click and speech stimuli differ in how they stimulate the auditory structures along the central auditory nervous system (CANS), as the different acoustic stimuli reflect distinct neural process.⁵5 Abrams DA, Nicol T, Zecker SG, Kraus N. Rapid acoustics processing in the auditory brainstem is not related to cortical asymmetry for the syllable rate of speech. Clin Neurophysiol. 2010;121:1343-50.^,⁷7 Johnson KL, Nicol T, Kraus N. The brainstem response to speech: a biological marker of auditory processing. Ear Hear. 2005;26:424-34.

In the analysis of ABR with speech stimuli, abnormalities were observed in both cases, with significantly prolonged absolute latency values of V and A waves, as well as of the VA slope. Studies support these findings and describe a difference between the V and A wave latency values in children with learning disabilities when compared to children with normal development. This suggests a rethinking of how speech sounds are encoded and the functional role of the structures responsible for generating these waves (the region of the lateral lemniscus and inferior colliculus).⁵5 Abrams DA, Nicol T, Zecker SG, Kraus N. Rapid acoustics processing in the auditory brainstem is not related to cortical asymmetry for the syllable rate of speech. Clin Neurophysiol. 2010;121:1343-50.^–⁷7 Johnson KL, Nicol T, Kraus N. The brainstem response to speech: a biological marker of auditory processing. Ear Hear. 2005;26:424-34.

The findings of this study suggest the existence of functional impairment in speech processing in the brainstem region, identified by prolonged latencies of V and A waves and VA slope, suggesting that the physiological mechanisms are altered, even without a proven neurobiological abnormality in patients exhibiting scholastic difficulties. As a result of this deficit in speech perception, there is an impairment of the communication and language processes, with consequent degradation of linguistic and paralinguistic information that causes difficulties in academic skills. This can result in severe consequences in quality of life and social interactions and culminate in learning disorders. Thus, there is a negative impact on the processing of fast acoustic signals in the specialized cortical structures, which do not respond to the sound stimulus in a synchronous and organized fashion and thus render the interpretation and understanding of the meaning difficult for children with scholastic difficulties.

Several abnormalities in sound processing can be observed in patients with learning disabilities. Thus different levels of the auditory trajectory should be investigated to establish a differential diagnosis. One way to evaluate the CANS is through behavioral tests; however, the evaluation is time-consuming and requires effective patient participation. For patients with learning difficulties, ABR with speech stimulus is indicated, since it is an objective, practical, and effective test that does not depend on the patient's response and is independent of attention; additionally, it provides an analysis of numerical measures that can be used as a predictor of the degree of the disorder.

According to Chandrasekaran and Kraus,⁹9 Chandrasekaran B, Kraus N. The scalp recorded brainstem response to speech: neural origins and plasticity. Psychophysiology. 2010;47:236-46. the analysis of absolute latency values for ABR with speech stimuli can help differentiate and establish different clinical pictures, and allow for an objective measure of subcortical speech processing. This analysis would be very important in cases of learning disabilities that include several other subgroups of disorders, including scholastic difficulties. Researchers stress that this procedure can be used to evaluate auditory function and provide additional information in the diagnosis of learning disabilities and auditory processing disorders.¹⁰10 Rocha-Muniz CN, Befi-Lopes DM, Schochat E. Sensitivity, specificity and efficiency of speech-evoked BERA. Hear Res. 2014;1:5-22.

The present findings suggest that changes in the perception and processing of auditory information observed in children with scholastic difficulties appear to be the same as those seen in children with learning disabilities. Thus, the authors stress the importance of evaluating children with scholastic difficulties, considering that alterations in speech sound processing appear to be of crucial importance in the learning process. Knowing the magnitude of hearing alterations in these patients may suggest more aggressive actions for the prevention, detection, and treatment of this disorder.

Conclusion

Analysis of these two cases showed the value of using ABR with speech stimuli in the evaluation of children with scholastic difficulties, considering the abnormalities detected in this study. This procedure is objective, fast, and effective. It does not require the patient's conscious participation and provides numerical data that can demonstrate the CANS maturation and, therefore, can function as a biomarker of scholastic difficulties.

The ABR study with speech stimuli is very promising. Further studies with more subjects, would be important to monitor and demonstrate these alterations. Additionally, longitudinal follow-up of these cases would be interesting to assess test accuracy and treatment effectiveness, as well as to investigate and monitor the consequences of impaired speech perception in cases of scholastic difficulties.

☆
Please cite this article as: Sanfins MD, Borges LR, Ubiali T, Colella-Santos MF. Speech-evoked auditory brainstem response in the differential diagnosis of scholastic difficulties. Braz J Otorhinolaryngol. 2017;83:112-6.
Funding This study was funded by FAPESP.
Peer Review under the responsibility of Associação Brasileira de Otorrinolaringologia e Cirurgia Cérvico-Facial.

References

¹
Regaçone SF, Gução ACB, Giacheti CM, Romero ACL, Frizzo ACF. Potenciais evocados auditivos de longa latência em escolares com transtornos específicos de aprendizagem. Audiol Commun Res. 2014;19:13-8.
²
Halliday LF, Bishop DVM. Is poor frequency modulation detection linked to literacy problems? A comparison of specific reading disability and mild to moderate sensorineural hearing loss. Brain Lang. 2006;9:200-13.
³
Cacace AT, McFarland DJ. Central auditory processing disorder in school-aged children: a critical review. J Speech Lang Hear Res. 1998;41:355-73.
⁴
Musiek FE, Shinn J, Hare C. Plasticity, auditory training and auditory processing disorders. Semin Hear. 2002;23:263-75.
⁵
Abrams DA, Nicol T, Zecker SG, Kraus N. Rapid acoustics processing in the auditory brainstem is not related to cortical asymmetry for the syllable rate of speech. Clin Neurophysiol. 2010;121:1343-50.
⁶
Skoe E, Kraus N. Auditory brainstem response to complex sounds: a tutorial. Ear Hear. 2010;31:302-24.
⁷
Johnson KL, Nicol T, Kraus N. The brainstem response to speech: a biological marker of auditory processing. Ear Hear. 2005;26:424-34.
⁸
Hornickel J, Skoe E, Nicol T, Zecker S, Kraus N. Subcortical differentiation of stop consonants relates to reading and speech-in-noise perception. Proc Natl Acad Sci. 2009;106:13022-7.
⁹
Chandrasekaran B, Kraus N. The scalp recorded brainstem response to speech: neural origins and plasticity. Psychophysiology. 2010;47:236-46.
¹⁰
Rocha-Muniz CN, Befi-Lopes DM, Schochat E. Sensitivity, specificity and efficiency of speech-evoked BERA. Hear Res. 2014;1:5-22.

Publication Dates

Publication in this collection
Jan-Feb 2017

History

Received
8 Apr 2015
Accepted
29 May 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ☆
Please cite this article as: Sanfins MD, Borges LR, Ubiali T, Colella-Santos MF. Speech-evoked auditory brainstem response in the differential diagnosis of scholastic difficulties. Braz J Otorhinolaryngol. 2017;83:112-6.

[2] Funding This study was funded by FAPESP.

[3] Peer Review under the responsibility of Associação Brasileira de Otorrinolaringologia e Cirurgia Cérvico-Facial.

Procedures	Case 1		Case 2
	Right ear	Left ear	Right ear	Left ear
DD	87.5%	92.5%	100%	95%
FPT (naming)	48.27%	58.62%	43.33%	26.66%
GIN%	71.66%	58.33%	73.33%	65%
GIN	4 ms	8 ms	5 ms	6 ms
SSI (relation – 15 dB)	70%	50%	60%	30%
Speech in noise	88%	80%	84%	72%

Procedures	Case 1		Case 2
	Right ear	Left ear	Procedures	Right ear
Mean of 500, 1000, and 2000 Hz	5 dB	5 dB	10 dB	5 dB
SRT (dB)	5 dB	5 dB	10 dB	5 dB
SRI (%)	100%	96%	96%	100%
Tympanogram	Type A	Type A	Type A	Type A
Ipsilateral and contralateral acoustic reflexes	Present	Present	Present	Present
TOAEs	Present	Present	Present	Present
DPOAEs	Present	Present	Present	Present
AP	Altered	Altered	Altered	Altered
ABR (click)	Normal	Normal	Normal	Normal
ABR (speech)	Altered	Unrealized	Altered	Unrealized
LLR	Normal	Normal	Normal	Normal

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