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  • About Us
    • Welcome to HESP
    • People
    • HESP Initiatives
    • Diversity and Inclusion Efforts in HESP
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  • Undergraduate
    • Welcome to our Undergraduate Program!
    • How To Declare
    • Resources and Opportunities for Students
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    • Welcome to our Graduate Programs!
    • Prospective Students
    • Current Students
    • Resources and Opportunities for Students
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Publications related to Assistive Technology-Rehab for Speech, Language, and Hearing

HESP Clinic
  • Tinnemore, Doyle, and Goupell (2024) “Temporal speech cue perception in listeners with cochlear implants depends on the time between those cues and previous sound energy,” J. Acoust. Soc. Am. 156, 2851-2859.
  • Zhou M, Soleimanpour R, Mahajan A, Anderson S. Hearing Aid Delay Effects on Neural Phase Locking. Ear Hear. 2024 Jan-Feb 01;45(1):142-150. doi: 10.1097/AUD.0000000000001408. Epub 2023 Jul 12 Hearing Aid Delay Effects.pdf1.45 MB
  • Xie, Gaskins, Tinnemore, Shader, Gordon-Salant, Anderson, and Goupell. (2024). “Spectral degradation and carrier sentences increase age-related temporal processing deficits in a cue-specific manner,” J. Acoust. Soc. Am. 155, 3983-3994.
  • Blackmon, A., Goupell, M. J., Bakke, M., and Stakhovskaya, O. A. (2024) “Reduced memory spans and ear dominance using dichotic digits in bimodal cochlear-implant users,” JASA Express Lett. 054403.
  • Ezenwa, A. C., Goupell, M. J., and Gordon-Salant, S. (2024) “Cochlear-implant listeners benefit from training with time-compressed speech, even at advanced ages,” JASA Express Lett. 4, 054402.
  • Menon, K. N., Hoon-Starr, M., Shilton, K., & Hoover, E. C. (2024). Over-the-counter hearing aids challenge the core values of traditional audiology. Journal of Speech, Language, and Hearing Research, 67(2), 657-667.
  • Cleary, DeRoy Milvae, Nguyen, Bernstein, and Goupell. (2023). “Effect of experimentally introduced interaural frequency mismatch on sentence identification in bilateral cochlear-implant listeners,” JASA Express Lett. 3 (4), 044401.
  • Mayo, P. G., Brown, A., D., and Goupell, M. J. (2023). “Wave interference at the contralateral ear helps explain non-monotonic envelope interaural time differences as a function of azimuth,” JASA Express Lett. 3 (3), 034403.
  • Menon, K. N., Hoon-Starr, M., Shilton, K., & Hoover, E. C. (2023). Core values in the traditional provision of hearing healthcare. Journal of Speech, Language, and Hearing Research, 66(2) 750-764.
  • Gibbs, B., II, Bernstein, J. G. W, Brungart, D., and Goupell, M. J. (2022). “Better-ear glimpsing in bilateral cochlear-implant users,” J. Acoust. Soc. Am. 152, 1230-1246.
  • Tinnemore, A. R., Montero, L., Gordon-Salant, S., and Goupell, M. J. (2022) “The intelligibility of time-compressed speech as a function of age in listeners with cochlear implants or normal hearing,” Front. Aging. Neurosci. 14, 887581.
  • Goupell et al. (2022). “Computed-tomography estimates of interaural mismatch in insertion depth and scalar location in bilateral cochlear-implant users,” Otol. Neurotol. 43, 666-675.
  • Karawani H, Jenkins K, Anderson S. Neural Plasticity Induced by Hearing Aid Use. Front Aging Neurosci. 2022 May 19;14:884917. doi: 10.3389/fnagi.2022.884917. Neural plasticity induced by hearing aid use.pdf3.6 MB
  • Jaekel, B. J., Weinstein, S., Newman, R. S., and Goupell, M. J. (2022). “Impacts of device and signal processing factors on perceptual restoration in cochlear-implant users,” J. Acoust. Soc. Am. 151, 2898-2915.
  • Johnson, A A.; Bentley, D M.; Munson, B; Edwards, J. (2021). Effects of Device Limitations on Acquisition of the /t/-/k/ Contrast in Children With Cochlear Implants, Ear and Hearing, 43(2), 519-530.
  • Shader, M. J., Kwon, B. J., Gordon-Salant, S, and Goupell, M. J. (2022). “Open-set phoneme recognition performance with varied temporal cues in younger and older cochlear-implant users,” J. Sp. Lang. Hear. Res. 65, 1196-1211.
  • Anderson, S., DeVries, L., Smith, E., Goupell, M. J., and Gordon-Salant, S. (2022) “Rate discrimination training may partially restore temporal processing abilities from age-related deficits,” J. Assoc. Res. Otolaryngol., 23, 771-786.
  • Bernstein et al. (2021). “Interaural place-of-stimulation mismatch estimates using CT scans and binaural perception, but not pitch, are consistent in cochlear-implant users,” J. Neurosci. 41, 10161-10178.
  • Goupell, M. J., Best, V., and Colburn, H. S. (2021) “Intracranial lateralization bias observed in the presence of symmetrical hearing thresholds,” JASA Express Lett. 1 (10), 104401.
  • Heffner, C., Jaekel, B. N., Newman, R. S., and Goupell, M. J. (2021). “Accuracy and cue use in word segmentation for cochlear-implant listeners and normal-hearing listeners presented vocoded speech,” J. Acoust. Soc. Am. 150, 2935-2951.
  • Kraemer, I. & Kolberg, E. (2021). Disability invisibility in academia -- how to support disabled people in research and beyond. Acoustics Today, 17(3), 75-78. Kraemer & Kolberg (2021) - Disability invisibility in academia.pdf164.27 KB
  • Palandrani, K. N., Hoover, E. C., Stavropoulos, T., Seitz, A. R., Isarangura, S., Gallun, F. J., & Eddins, D. A. (2021). Temporal integration of monaural and dichotic frequency modulation. The Journal of the Acoustical Society of America, 150(2),745-758. Palandrani et al. (2021) - Temporal integration of monaural and dichotic frequency modulation.pdf1.98 MB
  • Ortiz, J. A. (2021). Using nonword repetition to identify language impairment in bilingual children: A meta-analysis of diagnostic accuracy. American Journal of Speech-Language Pathology. (epub ahead of print.) https://doi.org/10.1044/2021_AJSLP-20-00237
  • Bieber, R., Tinnemore, A.,Yeni-Koshian, G., & Gordon-Salant, S. (2021). Younger and older adults show non-linear, stimulus-dependent performance during early stages of auditory training for non-native English. Journal of the Acoustical Society of America 149, 4348- 4365. DOI: 10.1121/10.0005279
  • Cychosz, M., Erskine, M., Munson, B. & Edwards, J. (2021). A lexical advantage in four-year-old children's word repetition. J. Child Language, 48(1), 31-54.

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