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Оглавление1 Barker, D. H., Quittner, A. L., Fink, N. E., Eisenberg, L. S., Tobey, E. A., Niparko, J. K., & Team, C. I. (2009). Predicting behavior problems in deaf and hearing children: The influences of language, attention, and parent–child communication. Development and Psychopathology, 21(2), 373–392.
2 Baudonck, N., Van Lierde, K., Dhooge, I., & Corthals, P. (2011). A comparison of vowel productions in prelingually deaf children using cochlear implants, severe hearing‐impaired children using conventional hearing aids and normal‐hearing children. Folia Phoniatrica et Logopaedica, 63(3), 154–160.
3 Bergeson, T., & Chin, S. (2008). Prosodic utterance production. Unpublished manuscript, Indiana University School of Medicine.
4 Blamey, P., Arndt, P., Bergeron, F., Bredberg, G., Brimacombe, J., Facer, G., … Whitford, L. (1996). Factors affecting auditory performance of postlinguistically deaf adults using cochlear implants. Audiology & Neuro‐Otology, 1(5), 293–306.
5 Blamey, P., Artieres, F., Başkent, D., Bergeron, F., Beynon, A., Burke, E., … Gallégo, S. (2013). Factors affecting auditory performance of postlinguistically deaf adults using cochlear implants: An update with 2251 patients. Audiology and Neurotology, 18(1), 36–47.
6 Blamey, P. J., Maat, B., Baskent, D., Mawman, D., Burke, E., Dillier, N., … Lazard, D. S. (2015). A retrospective multicenter study comparing speech perception outcomes for bilateral implantation and bimodal rehabilitation. Ear and Hearing, 36(4), 408–416.
7 Boonen, N., Kloots, H., & Gillis, S. (2019). Identificeerbaarheid van kinderen met een gehoorbeperking: Een vergelijkende benadering. Dutch Journal of Applied Linguistics. https://doi.org/10.1075/dujal.18017.boo
8 Boons, T., De Raeve, L., Langereis, M., Peeraer, L., Wouters, J., & van Wieringen, A. (2013). Expressive vocabulary, morphology, syntax and narrative skills in profoundly deaf children after early cochlear implantation. Research in Developmental Disabilities, 34(6), 2008–2022.
9 Caselli, M. C., Rinaldi, P., Varuzza, C., Giuliani, A., & Burdo, S. (2012). Cochlear implant in the second year of life: Lexical and grammatical outcomes. Journal of Speech, Language, and Hearing Research, 55(2), 382–394.
10 Chatterjee, M., Christensen, J. A., Kulkarni, A. M., Deroche, M. L., Damm, S. A., Bosen, A. K., … Limb, C. J. (2016). Voice emotion communication by listeners with cochlear implants. Poster 740 presented at 39th Annual Midwinter Meeting of the Association for Research in Otolaryngology, February 20–24, 2016, San Diego, California.
11 Chatterjee, M., Kulkarni, A. M., Siddiqui, R. M., Christensen, J. A., Hozan, M., Sis, J. L., & Damm, S. A. (2019). Acoustics of emotional prosody produced by prelingually deaf children with cochlear implants. Frontiers in Psychology, 10, 2190.
12 Chin, S. B., Bergeson, T. R., & Phan, J. (2012). Speech intelligibility and prosody production in children with cochlear implants. Journal of Communication Disorders, 45(5), 355–366.
13 Colletti, L., Shannon, R., & Colletti, V. (2012). Auditory brainstem implants for neurofibromatosis type 2. Current Opinion in Otolaryngology & Head and Neck Surgery, 20(5), 353–357.
14 Cosetti, M. K., & Waltzman, S. B. (2012). Outcomes in cochlear implantation: Variables affecting performance in adults and children. Otolaryngologic Clinics of North America, 45(1), 155–171.
15 Cupples, L., Ching, T. Y., Button, L., Seeto, M., Zhang, V., Whitfield, J., … Marnane, V. (2018). Spoken language and everyday functioning in 5‐year‐old children using hearing aids or cochlear implants. International Journal of Audiology, 57(suppl. 2), S55–S69.
16 Cysneiros, H. R. S., Leal, M. d. C., Lucena, J. A., & Muniz, L. F. (2016). Relationship between auditory perception and vocal production in cochlear implantees: A systematic review. CoDAS, 28(5). doi:10.1590/2317‐1782/20162015165
17 Dawes, P., Fortnum, H., Moore, D. R., Emsley, R., Norman, P., Cruickshanks, K., … Munro, K. (2014). Hearing in middle age: A population snapshot of 40‐ to 69‐year olds in the United Kingdom. Ear and Hearing, 35(3), 44–51.
18 de Hoog, B. E., Langereis, M. C., van Weerdenburg, M., Keuning, J., Knoors, H., & Verhoeven, L. (2016). Auditory and verbal memory predictors of spoken language skills in children with cochlear implants. Research in Developmental Disabilities, 57, 112–124.
19 Evans, M. K., & Deliyski, D. D. (2007). Acoustic voice analysis of prelingually deaf adults before and after cochlear implantation. Journal of Voice, 21(6), 669–682.
20 Fortunato‐Tavares, T., Befi‐Lopes, D., Bento, R. F., & de Andrade, C. R. F. (2012). Children with cochlear implants: Communication skills and quality of life. Brazilian Journal of Otorhinolaryngology, 78(1), 15–25.
21 Freeman, V., Pisoni, D. B., Kronenberger, W. G., & Castellanos, I. (2017). Speech intelligibility and psychosocial functioning in deaf children and teens with cochlear implants. The Journal of Deaf Studies and Deaf Education, 22(3), 278–289.
22 Friesen, L. M., Shannon, R. V., Baskent, D., & Wang, X. (2001). Speech recognition in noise as a function of the number of spectral channels: Comparison of acoustic hearing and cochlear implants. Journal of the Acoustical Society of America, 110(2), 1150–1163.
23 Gilbers, S., Fuller, C., Gilbers, D., Broersma, M., Goudbeek, M., Free, R., & Baskent, D. (2015). Normal‐hearing listeners’ and cochlear implant users’ perception of pitch cues in emotional speech. Iperception, 6(5). doi:10.1177/0301006615599139
24 Gillis, S. (2018). Speech and language in congenitally deaf children with a cochlear implant. In A. Bar‐On & D. Ravid (Eds.), Handbook of communication disorders: Theoretical, empirical, and applied linguistic perspectives (pp. 765–792). Berlin, Germany: De Gruyter.
25 Goffi‐Gomez, M. V. S., Magalhães, A. T., Brito Neto, R., Tsuji, R. K., de Gomes, M., Q. T., & Bento, R. F. (2012). Auditory brainstem implant outcomes and MAP parameters: Report of experiences in adults and children. International Journal of Pediatric Otorhinolaryngology, 76(2), 257–264.
26 Göthberg, H., Rosenhall, U., Tengstrand, T., Rydberg Sterner, T., Wetterberg, H., Zettergren, A., … Sadeghi, A. (2019). Cross‐sectional assessment of hearing acuity of an unscreened 85‐year‐old cohort—Including a 10‐year longitudinal study of a sub‐sample. Hearing Research, 382, 107797.
27 Guenther, F. H. (2006). Cortical interactions underlying the production of speech sounds. Journal of Communication Disorders, 39(5), 350–365.
28 Hirsh, I. J., Davis, H., Silverman, S. R., Reynolds, E. G., Eldert, E., & Benson, R. W. (1952). Development of materials for speech audiometry. Journal of Speech and Hearing Disorders, 17(3), 321–337.
29 Hoffmann‐Dilloway, E. (2016). Signing and belonging in Nepal. Washington, DC: Gallaudet University Press.
30 Holden, L. K., Finley, C. C., Firszt, J. B., Holden, T. A., Brenner, C., Potts, L. G., … Heydebrand, G. (2013). Factors affecting open‐set word recognition in adults with cochlear implants. Ear and Hearing, 34(3), 342.
31 Holt, C. M., Yuen, I., & Demuth, K. (2017). Discourse strategies and the production of prosody by prelingually deaf adolescent cochlear implant users. Ear and Hearing, 38(2), e101–e108.
32 Hu, B. (2012). Noise‐induced structural damage to the cochlea. In C. G. Le Prell, D. Henderson, R. R. Fay, & A. N. Popper (Eds.), Noise‐induced hearing loss: Scientific advances (pp. 57–86). New York, NY: Springer.
33 Huber, M., & Havas, C. (2019). Restricted speech recognition in noise and quality of life of hearing‐impaired children and adolescents with cochlear implants—Need for studies addressing this topic with valid pediatric quality of life instruments. Frontiers in Psychology, 10, 2085.
34 Hyde, M., & Punch, R. (2011). The modes of communication used by children with cochlear implants and the role of sign in their lives. American Annals of the Deaf, 155(5), 535–549.
35 Jiam, N. T., Caldwell, M., Deroche, M. L., Chatterjee, M., & Limb, C. J. (2017). Voice emotion perception and production in cochlear implant users. Hearing Research, 352, 30–39.
36 Kalathottukaren, R. T., Purdy, S. C., & Ballard, E. (2015). Prosody perception and musical pitch discrimination in adults using cochlear implants. International Journal of Audiology, 54(7), 1–9.
37 Kong, Y.‐Y., & Carlyon, R. P. (2010). Temporal pitch perception at high rates in cochlear implants. The Journal of the Acoustical Society of America, 127(5), 3114–3123.
38 Kort, W., Compaan, E., Schittekatte, M., & Dekker, P. (2010). Clinical evaluation of language fundamentals Nederlandse versie Handleiding (CELF 4, Dutch edition, manual). Amsterdam, The Netherlands: Pearson.
39 Kujawa, S. G., & Liberman, M. C. (2009). Adding insult to injury: Cochlear nerve degeneration after “temporary” noise‐induced hearing loss. The Journal of Neuroscience: The Official Journal of the Society for Neuroscience, 29(45), 14077–14085.
40 Lazard, D., Giraud, A.‐L., Gnansia, D., Meyer, B., & Sterkers, O. (2012). Understanding the deafened brain: Implications for cochlear implant rehabilitation. European Annals of Otorhinolaryngology, Head and Neck Diseases, 129(2), 98–103.
41 Lazard, D. S., Vincent, C., Venail, F., Van de Heyning, P., Truy, E., Sterkers, O., … Blamey, P. J. (2012). Pre‐, per‐ and postoperative factors affecting performance of postlinguistically deaf adults using cochlear implants: A new conceptual model over time. PLoS One, 7(11), e48739.
42 Lee, Y., & Sim, H. (2020). Prosodic control in imitative speech of preschool‐age children with cochlear implants. Clinical Linguistics & Phonetics, 34(6), 536–553.
43 Lehiste, I. (1970). Suprasegmentals. Cambridge, MA: MIT Press.
44 Li, Y.‐L., Lin, Y.‐H., Yang, H.‐M., Chen, Y.‐J., & Wu, J.‐L. (2018). Tone production and perception and intelligibility of produced speech in Mandarin‐speaking cochlear implanted children. International Journal of Audiology, 57(2), 135–142.
45 Liberman, M. C. (2017). Noise‐induced and age‐related hearing loss: New perspectives and potential therapies. F1000Research, 6, 927.
46 Lin, F. R., Yaffe, K., Xia, J., Xue, Q.‐L., Harris, T. B., Purchase‐Helzner, E., … Simonsick, E. M. (2013). Hearing loss and cognitive decline among older adults. JAMA Internal Medicine, 173(4), 293–299.
47 Lund, E. (2016). Vocabulary knowledge of children with cochlear implants: A meta‐analysis. Journal of Deaf Studies and Deaf Education, 21(2), 107–121.
48 Lyxell, B., Wass, M., Sahlen, B., Samuelsson, C., Asker‐Arnason, L., Ibertsson, T., … Hallgren, M. (2009). Cognitive development, reading and prosodic skills in children with cochlear implants. Scandinavian Journal of Psychology, 50(5), 463–474.
49 Mancini, P., Giallini, I., Prosperini, L., D'Alessandro, H. D., Guerzoni, L., Murri, A., … Nicastri, M. (2016). Level of emotion comprehension in children with mid to long term cochlear implant use: How basic and more complex emotion recognition relates to language and age at implantation. International Journal of Pediatric Otorhinolaryngology, 87, 219–232.
50 Mayer, C., & Trezek, B. J. (2017). Literacy outcomes in deaf students with cochlear implants: Current state of the knowledge. The Journal of Deaf Studies and Deaf Education, 23(1), 1–16.
51 Meister, H., Keilmann, A., Leonhard, K., Streicher, B., Müller, L., & Lang‐Roth, R. (2015). Real‐world verbal communication performance of children provided with cochlear implants or hearing aids. Otology & Neurotology, 36(6), 1023–1028.
52 Menard, L., Polak, M., Denny, M., Burton, E., Lane, H., Matthies, M. L., … Vick, J. (2007). Interactions of speaking condition and auditory feedback on vowel production in postlingually deaf adults with cochlear implants. Journal of the Acoustical Society of America, 121(6), 3790–3801.
53 Moberly, A. C., Lowenstein, J. H., & Nittrouer, S. (2016). Word recognition variability with cochlear implants: “Perceptual attention” versus “auditory sensitivity”. Ear and Hearing, 37(1), 14.
54 Monini, S., Banci, G., Barbara, M., Argiro, M. T., & Filipo, R. (1997). Clarion cochlear implant: Short‐term effects on voice parameters. American Journal of Otology, 18(6), 719–725.
55 Morris, D. J., Magnusson, L., Faulkner, A., Jönsson, R., & Juul, H. (2013). Identification of vowel length, word stress and compound words and phrases by postlingually‐deafened cochlear implant listeners. Journal of the American Academy of Audiology, 24(9), 879–890.
56 Nakata, T., Trehub, S. E., & Kanda, Y. (2012). Effect of cochlear implants on children’s perception and production of speech prosody. Journal of the Acoustical Society of America, 131(2), 1307–1314.
57 Nelson, L. H., Herde, L., Munoz, K., White, K. R., & Page, M. D. (2017). Parent perceptions of their child’s communication and academic experiences with cochlear implants. International Journal of Audiology, 56(3), 164–173.
58 O’Halpin, R. (2009). The perception and production of stress and intonation by children with cochlear implants (Unpublished Doctoral dissertation). University College, London.
59 Osberger, M. J., & McGarr, N. S. (1982). Speech production characteristics of the hearing impaired. In N. Lass (Ed.), Speech and language: Advances in basic research and practice (pp. 227–288). New York, NY: Academic Press.
60 Patro, C., & Mendel, L. L. (2018). Gated word recognition by postlingually deafened adults with cochlear implants: Influence of semantic context. Journal of Speech, Language, and Hearing Research, 61(1), 145–158.
61 Peng, S. C. (2005). Perception and production of speech intonation in pediatric cochlear implant recipients and children with normal hearing (Unpublished Doctoral dissertation). University of Iowa.
62 Peng, S. C., Tomblin, J. B., & Turner, C. W. (2008). Production and perception of speech intonation in pediatric cochlear implant recipients and individuals with normal hearing. Ear and Hearing, 29(3), 336–351.
63 Picou, E. M., Singh, G., Goy, H., Russo, F., Hickson, L., Oxenham, A. J., … Launer, S. (2018). Hearing, emotion, amplification, research, and training workshop: Current understanding of hearing loss and emotion perception and priorities for future research. Trends in Hearing, 22. doi:10.1177/2331216518803215
64 Poissant, S. F., Peters, K. A., & Robb, M. P. (2006). Acoustic and perceptual appraisal of speech production in pediatric cochlear implant users. International Journal of Pediatric Otorhinolaryngology, 70(7), 1195–1203.
65 Ramos, Á., Guerra‐Jiménez, G., Rodriguez, C., Borkoski, S., Falcón, J. C., & Perez, D. (2013). Cochlear implants in adults over 60: A study of communicative benefits and the impact on quality of life. Cochlear Implants International, 14(5), 241–245.
66 Rietveld, A. C. M., & van Heuven, V. J. (2016). Algemene fonetiek (4). Bussum, The Netherlands: Coutinho.
67 Rødvik, A. K., von Koss Torkildsen, J., Wie, O. B., Storaker, M. A., & Silvola, J. T. (2018). Consonant and vowel identification in cochlear implant users measured by nonsense words: A systematic review and meta‐analysis. Journal of Speech, Language, and Hearing Research, 61(4), 1023–1050.
68 Ruben, R. J. (2018). Language development in the pediatric cochlear implant patient. Laryngoscope Investigative Otolaryngology, 3(3), 209–213.
69 Rudner, M., Seeto, M., Keidser, G., Johnson, B., & Rönnberg, J. (2019). Poorer speech reception threshold in noise is associated with lower brain volume in auditory and cognitive processing regions. Journal of Speech, Language, and Hearing Research, 62(4S), 1117–1130.
70 Sarant, J. Z., Harris, D. C., Galvin, K. L., Bennet, L. A., Canagasabey, M., & Busby, P. A. (2018). Social development in children with early cochlear implants: Normative comparisons and predictive factors, including bilateral implantation. Ear and Hearing, 39(4), 770–782.
71 Schaette, R., & McAlpine, D. (2011). Tinnitus with a normal audiogram: Physiological evidence for hidden hearing loss and computational model. The Journal of Neuroscience: The Official Journal of the Society for Neuroscience, 31(38), 13452–13457.
72 Scherer, K. R., Banse, R., & Wallbott, H. G. (2001). Emotion inferences from vocal expression correlate across languages and cultures. Journal of Cross‐Cultural Psychology, 32(1), 76–92.
73 See, R. L., Driscoll, V. D., Gfeller, K., Kliethermes, S., & Oleson, J. (2013). Speech intonation and melodic contour recognition in children with cochlear implants and with normal hearing. Otology & Neurotology, 34(3), 490.
74 Sennaroğlu, L., Colletti, V., Lenarz, T., Manrique, M., Laszig, R., Rask‐Andersen, H., … Polak, M. (2016). Consensus statement: Long‐term results of ABI in children with complex inner ear malformations and decision making between CI and ABI. Cochlear Implants International, 17(4), 163–171.
75 Shannon, R. V. (1983). Multichannel electrical stimulation of the auditory nerve in man. I. Basic psychophysics. Hearing Research, 11(2), 157–189.
76 Shannon, R. V. (2002). The relative importance of amplitude, temporal, and spectral cues for cochlear implant processor design. American Journal of Audiology, 11(2), 124–127.
77 Shannon, R. V., Cruz, R. J., & Galvin, J. J. (2011). Effect of stimulation rate on cochlear implant users’ phoneme, word and sentence recognition in quiet and in noise. Audiology & Neuro‐Otology, 16(2), 113–123.
78 Shriberg, L. D., Austin, D., Lewis, B. A., McSweeny, J. L., & Wilson, D. L. (1997). The percentage of consonants correct (PCC) metric: Extensions and reliability data. Journal of Speech, Language, and Hearing Research, 40(4), 708–722.
79 Siegbahn, M., Lundin, K., Olsson, G.‐B., Stillesjö, F., Kinnefors, A., Rask‐Andersen, H., & Nyberg, G. (2014). Auditory brainstem implants (ABIs)—20 years of clinical experience in Uppsala, Sweden. Acta Oto‐Laryngologica, 134(10), 1052–1061.
80 Slepecky, N. (1986). Overview of mechanical damage to the inner ear: Noise as a tool to probe cochlear function. Hearing Research, 22, 307–321.
81 Sundarrajan, M., Tobey, E. A., Nicholas, J., & Geers, A. E. (2019). Assessing consonant production in children with cochlear implants. Journal of Communication Disorders, 84, 105966.
82 Szyfter, W., Pruszewicz, A., Woznica, B., Swidzinski, P., Szymiec, E., & Karlik, M. (1996). The acoustic analysis of voice in patients with multi‐channel cochlear implant. Revue de Laryngologie Otologie Rhinologie, 117(3), 225–227.
83 Torppa, R., & Huotilainen, M. (2019). Why and how music can be used to rehabilitate and develop speech and language skills in hearing‐impaired children. Hearing Research, 380, 108–122.
84 Tremblay, K. L., Pinto, A., Fischer, M. E., Klein, B. E. K., Klein, R., Levy, … Cruickshanks, K. J. (2015). Self‐reported hearing difficulties among adults with normal audiograms: The beaver dam offspring study. Ear and Hearing, 36(6), e290–e299.
85 Ubrig, M. T., Goffi‐Gomez, M. V., Weber, R., Menezes, M. H., Nemr, N. K., Tsuji, D. H., & Tsuji, R. K. (2011). Voice analysis of postlingually deaf adults pre‐ and postcochlear implantation. Journal of Voice, 25(6), 692–299.
86 Uchanski, R. M., & Geers, A. E. (2003). Acoustic characteristics of the speech of young cochlear implant users: A comparison with normal‐hearing age‐mates. Ear and Hearing, 24(1 Suppl), 90S–105S.
87 Verhoeven, J., Hide, O., De Maeyer, S., Gillis, S., & Gillis, S. (2016). Hearing impairment and vowel production. A comparison between normally hearing, hearing‐aided and cochlear implanted Dutch children. Journal of Communication Disorders, 59, 24–39.
88 Waldstein, R. S. (1990). Effects of postlingual deafness on speech production: Implications for the role of auditory feedback. Journal of the Acoustical Society of America, 88(5), 2099–2114.
89 Wang, D., Trehub, S., Volkova, A., & van Lieshout, P. (2013). Child implant users’ imitation of happy‐ and sad‐sounding speech. Frontiers in Psychology, 4(1664‐1078 (Electronic)), 1–8.
90 Wiefferink, C. H., Rieffe, C., Ketelaar, L., De Raeve, L., & Frijns, J. H. M. (2013). Emotion understanding in deaf children with a cochlear implant. Journal of Deaf Studies and Deaf Education, 18(2), 175–186.
91 Wilson, B. S. (2019). The remarkable cochlear implant and possibilities for the next large step forward. Acoustics Today, 15, 53–61.
92 Wilson, B. S., Finley, C. C., Lawson, D. T., Wolford, R. D., & Zerbi, M. (1993). Design and evaluation of a continuous interleaved sampling (CIS) processing strategy for multichannel cochlear implants. Journal of Rehabilitation Research and Development, 30, 110–110.
93 Wilson, I. B., & Cleary, P. D. (1995). Linking clinical variables with health‐related quality of life: A conceptual model of patient outcomes. JAMA, 273(1), 59–65.
94 World Bank. (2019). Life expectancy at birth, total (years). Retrieved from https://data.worldbank.org/indicator/SP.DYN.LE00.IN
95 World Health Organization. (2019). How to use the ICF: A practical manual for using the international classification of functioning, disability and health (ICF). Exposure draft or comment. Geneva, Switzerland: Author. Retrieved from https://www.who.int/classifications/drafticfpracticalmanual.pdf
96 Zeng, F. G. (2002). Temporal pitch in electric hearing. Hearing Research, 174(1–2), 101–106.
