medigraphic.com

2006, Number 1

<< Back

Rev Mex Ing Biomed 2006; 27 (1)

Cochlear implants: Development and perspectives

Martínez REA, Cano OSD, Garcerán HV

Language: Spanish
References: 61
Page: 45-54
PDF size: 158.11 Kb.


ABSTRACT

The development and implementation of Cochlear Implant devices have lead to a useful alternative for partial re-establishment of profoundly deaf people. The Cochlear Implant has been highly concerned with the combined efforts of the scientists from several areas as bioengineering, speech recognition, medicine and signal processing. This paper pretends to make an updated review about the novel technology used in cochlear prosthesis as well as the perspectives and tendencies of this knowledge area.


REFERENCES

  1. Ian CB. Spatiotemporal coding of sound in the auditory nerve for cochlear implants. Doctor of Philosophy Department of Otolaryngology, University of Melbourne, 1997.

  2. Landy MS. Course of Perception. 2004. http://www.cns.nyu.edu/~msl/courses/0022/

  3. Loizou P. Introduction to cochlear implants. IEEE Engineering in Medicine and Biology Magazine, 1999; 18(1): 1-36.

  4. Moore JA, Teagle HFB. An introduction to cochlear implant technology, activation, and programming. Language Speech and Hearing Services in Schools, 2002; 33(3).

  5. Loizou PC. Signal processing for cochlear prosthesis: a tutorial review. Proceedings of the 40th Midwest Symposium on Circuits and Systems (IEEE MWSCAS’97), 1998; 2(1): 881-885.

  6. Ay SU, Fan-Gang Zeng, Sheu BJ. Hearing with bionic ears [cochlear implant devices]. Circuits and Devices Magazine, IEEE, 1997; 13(3): 18-23.

  7. Walliker JR. Cochlear Implants. Technology for the Hearing Impaired-State of the Art and Future Trends, IEE Colloquium on, 1988; 12-12.

  8. Hanekom JJ, Van Schalkwyk JJD. The South Africa bionic ear-description and preliminary results. Proceedings of Southern African Conference on Communications and Signal Processing (COMSIG 1989), 1989; 59-64.

  9. Morris LR, Barszczewski P. Algorithms, hardware, and software for a digital signal processor microcomputer-based speech processor in a multielectrode cochlear implant system. IEEE Transaction on Biomedical Engineering, 1989; 36(6): 573-584.

  10. Salthouse CD, Sarpeshkar R. A practical micropower programmable bandpass filter for use in bionic ears. IEEE Journal of Solid-State Circuits, 2003; 38(1): 63-70.

  11. Rubinstein JT, Turner C. A novel acoustic simulation of cochlear implant hearing: effects of temporal fine structure. Proceedings of the First International IEEE EMBS, Conference on Neural Engineering, 2003; 142-145.

  12. Bogli H, Dillier N. Digital Speech Processor For The Nucleus 22-channel Cochlear Implant. Engineering in Medicine and Biology Society, Proceedings of the Annual International Conference of the IEEE, 1991; 13(-): 1901-1902.

  13. Loizou PC. Mimicking the human ear. Signal Processing Magazine, IEEE, 1998; 15(5): 101-130.

  14. Loizou PC. Signal-processing techniques for cochlear implants. Engineering in Medicine and Biology Magazine, IEEE, 1999; 18(3): 34-46.

  15. Pasanisi E, Bacciu A, Vincenti V, Guida M, Berghenti MT, Barbot A, Panu F, Bacciu S. Comparison of speech perception benefits with SPEAK and ACE coding strategies in pediatric Nucleus CI24M cochlear implant recipients. International Journal of Pediatric Otorhinolaryngology, 2002; 64(2): 159-163.

  16. Tong Y C, Chang JS, Harrison JM, Hugien J, Clark G M. Two speech processing schemes for the University of Melbourne multi-channel cochlear implant prosthesis. Circuits and Systems, 1989., IEEE International Symposium on, 1989; 2(-): 1051-1054.

  17. Schatzer R, Wilson BS, Lopez PEA, Zerbi M, Wolford RD, Lawson DT. A novel CI speech processing structure for closer Mimicking of normal auditory functions. 2004.

  18. Schatzer R, Wilson B, Wolford R, Lawson D. Speech Processors for Auditory Prostheses. Sixth Quarterly Progress Report. 2003. http://www.rti.org/publications.cfm?nav=91&objectid=F33F30D0-45D7-4A85-A3CBE2261DE9E650

  19. Hearing and Balance. 22-3-1996. http://www.neurophys.wisc.edu/~ychen/textbook/textindex.html

  20. Fundamentals of Hearing & Speech Science. 2004. http://www.d.umn.edu/~floven/courses/csd3105/syllabus.html

  21. McDermott H. An advanced multiple channel cochlear implant. IEEE Transactions on Biomedical Engineering, 1989; 36(7): 789-797.

  22. Dettmer R. The all-electric ear. IEE Review, 1988; 34(5): 195-198.

  23. Hruby J, Sedlak S, Picka J, Topol M, Klier E. Evaluation and measurements at the cochlear implantations. Engineering in Medicine and Biology Society, Proceedings of the Annual International Conference of the IEEE, 1988; 4(-): 1543-1544.

  24. Advanced Bionics Corporation. CLARION TM. Multi Strategy Cochlear Implant. Version 2.0. (12740 San Fernando Road Sylmar, California 91342-3728), 1996.

  25. Advanced Bionics Corporation. Advanced Bionic. 2004. http://www.cochlear.com/Spanish/

  26. MED-EL. MED-EL. 2004. http://www.medel.com/LANG/SPA/

  27. Nucleus. NUCLEUS. 2004. http://www.cochlear.com/spanish/

  28. Anderson I, Weichbold V, D’Haese PSC, Szuchnik J, Quevedo MS, Martin J, Dieler WS, Phillips L. Cochlear implantation in children under the age of two—what do the outcomes show us? International Journal of Pediatric Otorhinolaryngology, 2004; 68(4): 425-431.

  29. Arnoldner C, Baumgartner WD, Gstoettner W, Egelierler B, Czerny C, Steiner E, Hamzavi J. Audiological performance after cochlear implantation in children with inner ear malformations”, International Journal of Pediatric Otorhinolaryngology, 2004; 68(4): 457-467.

  30. Calmels MN, Saliba I, Wanna G, Cochard N, Fillaux J, Deguine O, Fraysse B. Speech perception and speech intelligibility in children after cochlear implantation. International Journal of Pediatric Otorhinolaryngology, 2004; 68(3): 347-351.

  31. Lisiecka-Bielanowicz M, Szuchnik J, Ratynska J, Szkielkowska A. Physiotherapy of breathing as an element of multidisciplinary rehabilitation of children using cochlear implants. International Congress Series, 2003; 1240 375-378.

  32. Lorens A, Skarzynski H, Piotrowska A, Walkowiak A, Sliwa L, Kochanek K. Objective methods of postoperative tests in cochlear implant patients. International Congress Series, 2003; 1240 379-383.

  33. Hassanzadeh S, Farhadi M, Daneshi A, Emamdjomeh H. The effects of age on auditory speech perception development in cochlear-implanted prelingually deaf children. Otolaryngology - Head and Neck Surgery, 2002; 126(5): 524-527.

  34. Kirk KI, Miyamoto RT, Ying EA, Perdew AE, Zuganelis H. Cochlear implantation in young children: Effects of age at implantation and communication mode. Volta Review, 2002; 102(4): 127-144.

  35. Kirk KI, Miyamoto RT, Lento CL, Ying E, O’Neill T, Fears B. Effects of age at implantation in young children. Annals of Otology Rhinology and Laryngology, 2002; 111(5): 69-73.

  36. Balkany TJ, Hodges AV, Eshraghi AA, Butts S, Bricker K, Lingvai J, Polak M, King J. Cochlear implants in children- A review. Acta Oto-Laryngologica, 2002; 122(4): 356-362.

  37. Waltzman SB, Cohen NL, Green J, Roland JT. Long-term effects of cochlear implants in children. Otolaryngology-Head and Neck Surgery, 2002; 126(5): 505-511.

  38. Vermeire K, Brokx JPL, Van de Heyning PH, Cochet E, Carpentier H. Bilateral cochlear implantation in children. International Journal of Pediatric Otorhinolaryngology, 2003; 67(1): 67-70.

  39. Brademann G, Muller-Deile J, Maa[ss] J, Frese K, Vogel A, Kortmann T, Maune S. Is the bilateral cochlear implantation necessary for avoidance of auditory deprivation in deaf children? International Congress Series, 2003; 1254 301-306.

  40. Loizou PC. Introduction to cochlear implants. IEEE Engineering in Medicine and Biology Magazine, 1999; 18(1): 32-42.

  41. Loizou PC. Signal processing for cochlear implants and low-rate speech coding. Speech Coding, 2000. Proceedings. 2000 IEEE Workshop on, 2000; 68-68.

  42. Lawson D, Wolford R, Blake W, Schatzer R. Speech Processors for Auditory Prostheses. First Quarterly Progress Report. First Quarterly Progress Report, 2002; 1-38.

  43. Miller A, Abbas PJ, Nourski KV, Hu N, Robinson BK. Electrode configuration influences action potential initiation site and ensemble stochastic response properties. Hearing Research, 2003; 175(1-2): 200-214.

  44. Jamieson L, Ajayi F, Costa A, Martin J, Raine CH. Use of the TEMPO+ behind-the-ear speech processor and COMBI40+ cochlear implant with very young children”, International Congress Series, 2003; 1240 391-397.

  45. Aschendorff A, Klenzner T, Hamad M, Kubalek R, Richter B, Laszig R. Perimodiolar electrodes-radiological and histological findings. International Congress Series, 2003; 1240 361-364.

  46. Zeng FG, Fu QJ, Morse R. Human hearing enhanced by noise. Brain Research, 2000; 869(1-2): 251-255.

  47. Morse RP, Evans EF. Additive noise can enhance temporal coding in a computational model of analogue cochlear implant stimulation. Hearing Research, 1999; 133(1-2): 107-119.

  48. Morse RP, Meyer GF. The practical use of noise to improve speech coding by analogue cochlear implants. Chaos, Solitons & Fractals, 2000; 11(12): 1885-1894.

  49. Matsuoka AJ, Abbas PJ, Rubinstein JT, Miller CA. The neuronal response to electrical constant-amplitude pulse train stimulation: additive Gaussian noise. Hearing Research, 2000; 149(1-2): 129-137.

  50. Behnam SE, Zeng FG. Noise improves suprathreshold discrimination in cochlear-implant listeners. Hearing Research, 2003; 186(1-2): 91-93.

  51. Kuchta J, Otto SR, Shannon RV, Hitselberger WE, Brackmann DE. The multichannel auditory brainstem implant: how many electrodes make sense? Journal of Neurosurgery, 2004; 100(1): 16-23.

  52. Schwartz MS, Hitselberger WE, Otto SR, Brackmann DE, Shannon RV. Brainstem auditory implants. Operative Techniques in Otolaryngology-Head and Neck Surgery, 2003; 14(4): 282-287.

  53. Szyfter W, Pruszewicz A, Karlik M, Kawczynski M, Sekula A, Swidzinski P, Magierska M. Poznan’s program of cochlear and brainstem implantation: a general review. European Archives of Oto-Rhino-Laryngology, 2003; 260(8): 460-463.

  54. Colletti V, Carner M, Fiorino FG, Miorelli V, Guida M, Sacchetto L. Can an auditory brainstem implant make up for cochlear implant failure? Otolaryngology - Head and Neck Surgery, 2003; 129(2): 136-136.

  55. Colletti V, Fiorino F, Carner M, Sacchetto L, Miorelli V, Orsi A. Auditory brainstem implantation: The University of Verona experience. Otolaryngology - Head and Neck Surgery, 2002; 127(1): 84-96.

  56. Sollmann WP, Laszig R, Marangos N, Charachon R, Ramsden R, Fraysse B, Lazorthes Y, Sterkers O, Rey A, Lenarz T. Electrical stimulation of the cochlear nucleus. First results of the European auditory brainstem implant clinical trial. Clinical Neurology and Neurosurgery, 1997; 99(Supplement 1): S109-S109.

  57. Colletti V, Fiorino F, Sacchetto L, Miorelli V, Carner M. Hearing habilitation with auditory brainstem implantation in two children with cochlear nerve aplasia. International Journal of Pediatric Otorhinolaryngology, 2001; 60(2): 99-111.

  58. Jack Xin, Yingyong QI, Li Deng. Time Domain Computation Of A Nonlinear Nonlocal Cochlear Model With Applications To Multitone Interaction In Hearing. Comm. Math. SCI., 2003; 1(2): 211-227.

  59. Lopez-Poveda EA, Meddis R. A human nonlinear cochlear filterbank. J. Acoust. Soc. Am. 2001; 110(6): 3107-3118.

  60. Meddis R, Lowel POM, Lopez-Poveda EA. A computational algorithm for computing nonlinear auditory frequency selectivity. Journal Acoustic Society of America, 2001; 109(6): 2852-2861.

  61. Xuedong Z, Heinz MG, Ian CB, Carney LH. A phenomenological model for the responses of auditorynerve fibers: I. Nonlinear tuning with compression and suppression. Acoustical Society of America, 2001; 648-670.




2020     |     www.medigraphic.com