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Neurophysiological aspects of brainstem processing of speech stimuli in audiometric-normal geriatric population

Published online by Cambridge University Press:  23 December 2016

M S Ansari*
Affiliation:
Department of Audiology, Ali Yavar Jung National Institute of Speech and Hearing Disabilities (Divyangjan), Mumbai, India
R Rangasayee
Affiliation:
Technical Director, Dr S R Chandrasekhar Institute of Speech & Hearing, Bangalore, India
M A H Ansari
Affiliation:
Department of Physiology, Grant Medical College & Sir J J Groups of Hospitals, Mumbai, India
*
Address for correspondence: Mr Mohammad Shamim Ansari, Ali Yavar Jung National Institute for the Hearing Handicapped, K C Marg, Bandra (W), Mumbai 400050, Maharashtra, India. E-mail: [email protected]

Abstract

Objective:

Poor auditory speech perception in geriatrics is attributable to neural de-synchronisation due to structural and degenerative changes of ageing auditory pathways. The speech-evoked auditory brainstem response may be useful for detecting alterations that cause loss of speech discrimination. Therefore, this study aimed to compare the speech-evoked auditory brainstem response in adult and geriatric populations with normal hearing.

Methods:

The auditory brainstem responses to click sounds and to a 40 ms speech sound (the Hindi phoneme |da|) were compared in 25 young adults and 25 geriatric people with normal hearing. The latencies and amplitudes of transient peaks representing neural responses to the onset, offset and sustained portions of the speech stimulus in quiet and noisy conditions were recorded.

Results:

The older group had significantly smaller amplitudes and longer latencies for the onset and offset responses to |da| in noisy conditions. Stimulus-to-response times were longer and the spectral amplitude of the sustained portion of the stimulus was reduced. The overall stimulus level caused significant shifts in latency across the entire speech-evoked auditory brainstem response in the older group.

Conclusion:

The reduction in neural speech processing in older adults suggests diminished subcortical responsiveness to acoustically dynamic spectral cues. However, further investigations are needed to encode temporal cues at the brainstem level and determine their relationship to speech perception for developing a routine tool for clinical decision-making.

Type
Main Articles
Copyright
Copyright © JLO (1984) Limited 2016 

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References

1 Tremblay, KL, Piskosz, M, Souza, P. Effects of age and age-related hearing loss on the neural representation of speech cues. Clin Neuropathol 2003;114:1332–43Google Scholar
2 Van Rooij, JC, Plomp, R, Orlebeke, JF. Auditive and cognitive factors in speech perception by elderly listeners. I: Development of test battery. J Acoust Soc Am 1989;86:1294–309Google Scholar
3 van Rooij, JC, Plomp, R. Auditive and cognitive factors in speech perception by elderly listeners. III. Additional data and final discussion. J Acoust Soc Am 1992 ;91:1028–33Google Scholar
4 Humes, LE. Speech understanding in the elderly. J Am Acad Audiol 1996;7:161–7Google Scholar
5 Dubno, JR, Lee, FS, Matthews, LJ, Mills, JH. Age-related and gender-related changes in monaural speech recognition. J Speech Lang Hear Res 1997;40:444–52Google Scholar
6 Martini, A, Comacchio, F, Magnavita, V. Auditory evoked responses (ABR, MLR, SVR) and brain mapping in the elderly. Acta Otolaryngol Suppl 1991;476:97104 Google Scholar
7 Ottaviani, F, Maurizi, M, D'alatri, L, Almadori, G. Auditory brainstem responses in the aged. Acta Otolaryngol Suppl 1991;476:110–13Google Scholar
8 Pichora-Fuller, MK, Schneider, BA, MacDonald, E, Pass, HE, Brown, S. Temporal jitter disrupts speech intelligibility: a simulation of auditory aging. Hear Res 2007;223:114–21Google Scholar
9 Lister, JJ, Maxfield, ND, Pitt, GJ, Gonzalez, VB. Auditory evoked response to gaps in noise: older adults. Int J Audiol 2011;50:211–25Google Scholar
10 Tremblay, KL, Billings, C, Rohila, N. Speech evoked cortical potentials: effects of age and stimulus presentation rate. J Am Acad Audiol 2004;15:226–37Google Scholar
11 Tremblay, K, Ross, B. Effects of age and age-related hearing loss on the brain. J Commun Disord 2007;40:305–12CrossRefGoogle ScholarPubMed
12 Tremblay, KL, Billings, CJ, Friesen, LM, Souza, PE. Neural representation of amplified speech sounds. Ear Hear 2006;2:93103 Google Scholar
13 Harkrider, AW, Plyler, PN, Hedrick, MS. Effects of hearing loss and spectral shaping on identification and neural response patterns of stop-consonant stimuli. J Acoust Soc Am 2006;120:915–25Google Scholar
14 Oku, T, Hasegewa, M. The influence of aging on auditory brainstem response and electrocochleography in the elderly. ORL J Otorhinolaryngol Relat Spec 1997;59:141–6Google Scholar
15 Rosenhall, UL, Björkman, G, Pedersen, K, Kall, A. Brain-stem auditory evoked potentials in different age groups. Electroencephalogr Clin Neurophysiol 1985;62:426–30Google Scholar
16 Rosenhall, U, Pedersen, K, Dotevall, M. Effects of presbycusis and other types of hearing loss on auditory brainstem responses. Scand Audiol 1986;15:179–85Google Scholar
17 Jerger, J, Johnson, K. Interactions of age, gender, and sensorineural hearing loss on ABR latency. Ear Hear 1988;9:168–76Google Scholar
18 Johnson, KL, Nicol, TG, Kraus, N. Brain stem response to speech: a biological marker of auditory processing. Ear Hear 2005;26:424–34Google Scholar
19 Akhoun, I, Gallégo, S, Moulin, A, Ménard, M, Veuillet, E, Berger-Vachon, C et al. The temporal relationship between speech auditory brainstem responses and the acoustic pattern of the phoneme /ba/ in normal-hearing adults. Clin Neurophysiol 2008;119:922–33Google Scholar
20 Chandrasekaran, B, Kraus, N. The scalp-recorded brainstem response to speech: neural origins and plasticity. Psychophysiology 2010;47:236–46Google Scholar
21 Song, JH, Banai, K, Russo, NM, Kraus, N. On the relationship between speech- and non speech-evoked auditory brainstem responses. Audiol Neurootol 2006;11:233–41Google Scholar
22 Russo, N, Nicol, T, Trommer, B, Zecker, S, Kraus, N. Brainstem transcription of speech is disrupted in children with autism spectrum disorders. Dev Sci 2009;12:557–67Google Scholar
23 Wible, B, Nicol, T, Kraus, N. Correlation between brainstem and cortical auditory processes in normal and language-impaired children. Brain 2005;128:417–23Google Scholar
24 Hall, JW. New handbook of auditory evoked responses. Boston: Pearson 2007;221–60Google Scholar
25 Krishnan, A. Human frequency-following responses: representation of steady-state synthetic vowels. Hear Res 2002;166:192201 Google Scholar
26 Russo, N, Nicol, T, Musacchia, G, Kraus, N. Brainstem responses to speech syllables. Clin Neurophysiol 2004;115:2021–30Google Scholar
27 Kraus, N, Nicol, T. Brainstem origins for cortical ‘what’ and ‘where’ pathways in the auditory system. Trends Neurosci 2005;28:176–81Google Scholar
28 Clinard, CG, Tremblay, KL, Krishnan, AR. Aging alters the perception and physiological representation of frequency: evidence from human frequency-following response recordings. Hear Res 2010;264:4855 Google Scholar
29 Vander Werff, KR, Burns, KS. Brain stem responses to speech in younger and older adults. Ear Hear 2011;32:168–80Google Scholar