References
- Aiken S. & Picton T. 2008. Envelope and spectral frequency-following responses to vowel sounds. Hear Res, 245, 35–47.
- Anderson S., Skoe E., Chandrasekaran B., Zecker S. & Kraus N. 2010. Brainstem correlates of speech-in-noise perception in children. Hear Res, 270, 151–157.
- Anderson S., Parbery-Clark A., White-Schwoch T. & Kraus N. 2015. Development of subcortical speech representation in infant humans. J Acoust Soc Am, 137, 3346–3355.
- Carcagno S. & Plack C.J. 2011. Subcortical plasticity following perceptual learning in a pitch discrimination task. J Assoc Res Otolaryngol, 12, 89–100.
- Chandrasekaran B., Krishnan A. & Gandour J. 2008. Relative influence of musical and linguistic experience on early cortical processing of pitch contours. Brain Lang, 108, 1–9.
- Fu Q.-J., Zeng F.-G., Shannon R. & Soli S. 1998. Importance of tonal envelope cues in Chinese speech recognition. J Acoust Soc Am, 104, 505–510.
- Greenwood D. 1990. A cochlear frequency-position function for several species: 29 years later. J Acoust Soc Am, 87, 2592–2605.
- Hornickel J., Anderson S., Skoe E., Yi H. & Kraus N. 2012. Subcortical representation of speech fine structure relates to reading ability. Neuroreport, 23, 6–9.
- Hornickel J., Chandrasekaran B., Zecker S. & Kraus N. 2011. Auditory brainstem measures predict reading and speech-in-noise perception school-age children. Behav Brain Res, 216, 597–605.
- Hornickel J. & Kraus N. 2013. Unstable representation of sound: A biological marker of dyslexia. J Neurosci, 33, 3500–3504.
- Jeng F.-C., Schnabel E.A., Dickman B.M., Hu J., Li X. et al. 2010. Early maturation of frequency-following responses to voice pitch in infants with normal hearing. Percept Mot Skills, 111, 765–784.
- Jeng F.-C., Hu J., Dickman B.M., Lin C.-Y., Lin C.-D. et al. 2011a. Evaluation of two algorithms for detecting human frequency-following responses to voice pitch. Int J Audiol, 50, 14–26.
- Jeng F.-C., Hu J., Dickman B.M., Montgomery-Reagan K., Tong M. et al. 2011b. Cross-linguistic comparison of frequency-following responses to voice pitch in American and Chinese neonates and adults. Ear Hear, 32, 699–707.
- Kraus N. & Nicol T. 2005. Brainstem origins for cortical ‘what’ and ‘where’ pathways in the auditory system. Trends Neurosci, 28, 176–181.
- Krishnan A., Gandour J.T., Bidelman G.M. & Swaminathan J. 2009. Experience-dependent neural representation of dynamic pitch in the brainstem. Neuroreport, 20, 408–413.
- Krishnan A., Xu Y., Gandour J. T. & Cariani P.A. 2004. Human frequency-following response: Representation of pitch contours in Chinese tones. Hear Res, 189, 1–12.
- Krishnan A., Xu Y., Gandour J. & Cariani P. 2005. Encoding of pitch in the human brainstem is sensitive to language experience. Cogn Brain Res, 25, 161–168.
- Lomber S. & Malhotra S. 2008. Double dissociation of ‘what’ and ‘where’ processing in auditory cortex. Nat Neurosci, 11, 609–616.
- Luo X., Padilla M. & Landsberger D.M. 2012. Pitch contour identification with combined place and temporal cues using cochlear implants. J Acoust Soc Am, 131, 1325–1336.
- Musacchia G., Sams M., Skoe E. & Kraus N. 2007. Musicians have enhanced subcortical auditory and audiovisual processing of speech and music. Proc Natl Acad Sci, 104, 15894–15898.
- Parbery-Clark A., Skoe E. & Kraus N. 2009. Musical experience limits the degradative effects of background noise on the neural processing of sound. J Neurosci, 29, 14100–14107.
- Russo N., Nicol T., Zecker S., Hayes E. & Kraus N. 2005. Auditory training improves neural timing in the human brainstem. Behav Brain Res, 156, 95–103.
- Russo N., Hornickel J., Nicol T., Zecker S. & Kraus N. 2010. Biological changes in auditory function following training in children with autism spectrum disorders. Behav Brain Funct, 6, 1–8.
- Shannon R.V., Zeng F.-G., Kamath V., Wygonski J. & Ekelid M. 1995. Speech recognition with primarily temporal cues. Science, 270, 303–304.
- Skoe E. & Kraus N. 2010. Auditory brain stem response to complex sounds: A tutorial. Ear Hear, 31, 302–324.
- Skoe E., Krizman J., Spitzer E. & Kraus N. 2015. Prior experience biases subcortical sensitivity to sound patterns. J Cogn Neurosci, 27, 124–140.
- Smith Z., Delgutte B. & Oxenham A. 2002. Chimaeric sounds reveal dichotomies in auditory perception. Nature, 416, 87–90.
- Song J.H., Skoe E., Wong P.C.M. & Kraus N. 2008. Plasticity in the adult human auditory brainstem following short-term linguistic training. J Cognitive Neurosci, 20, 1892–1902.
- Strait D.L., Kraus N., Skoe E. & Ashley R. 2009. Musical experience and neural efficiency- effects of training on subcortical processing of vocal expressions of emotion. Eur J Neurosc, 29, 661–668.
- Strait D. & Kraus N. 2013. Biological impact of auditory expertise across the life span: Musicians as a model of auditory learning. Hear Res, 308, 109–121.
- Swaminathan J., Krishnan A., Gandour J.T. & Xu Y. 2008a. Applications of static and dynamic iterated rippled noise to evaluate pitch encoding in the human auditory brainstem. IEEE Trans Biomed Eng, 55, 281–287.
- Swaminathan J., Krishnan A. & Gandour J.T. 2008b. Pitch encoding in speech and nonspeech contexts in the human auditory brainstem. Neuroreport, 19, 1163–1167.
- Wang W.-J., Wu X.-H. & Li L. 2008. The dual-pathway model of auditory signal processing. Neuroscience, 24, 179–182.
- Wang S., Mannell R., Newall P. & Han D. 2011. Contribution of spectral cues to Mandarin lexical tone recognition in normal-hearing and hearing-impaired Mandarin Chinese speakers. Ear Hear, 32, 97–103.
- Wong P.C.M., Skoe E., Russo N.M., Dees T. & Kraus N. 2007. Musical experience shapes human brainstem encoding of linguistic pitch patterns. Nat Neurosci, 10, 420–422.
- Xu L. & Pfingst B. 2003. Relative importance of temporal envelope and fine structure in lexical-tone perception. J Acoust Soc Am, 114, 3024–3027.
- Xu L. & Pfingst B. 2008. Spectral and temporal cues for speech recognition: Implications for auditory prostheses. Hear Res, 242, 132–140.
- Zeng F.-G. 2012. Tonal language processing. Acoustics Today, 8, 26–28.
- Zhang F., Benson C. & Fu Q.-J. 2013. Cortical encoding of pitch contour changes in cochlear implant users: A mismatch negativity study. Audiol Neurootol, 18, 275–288.