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Differentiation of cochlear pathophysiology in ears damaged by salicylate or a pure tone using a nonlinear systems identification technique
1.Ashmore, J. F. (1987). “A fast motile response in guinea-pig outer hair cells: the cellular basis of the cochlear amplifier,” J. Physiol. (London) 338, 323–347.
2.Bendat, J. S. , and Palo, P. (1990). “Practical techniques for nonlinear system analysis/identification,” Sound Vib.24, 28–33.
3.Bendat, J. S., and Piersol, A. G. (1986). Random Data: Analysis and Measurement Procedures (Wiley, New York), 2nd ed.
4.Brundin, L. , and Russell, I. (1994). “Tuned phasic and tonic motile responses of isolated outer hair cells to direct mechanical stimulation of the cell body,” Hearing Res. 73, 35–45.
5.Chertoff, M. E. , and Brownell, W. E. (1994). “Characterization of cochlear outer hair cell turgor,” Am. J. Physiol. 266, C467–C479.
6.Chertoff, M. E. , and Chen, J. (1996). “An in-situ calibration procedure for click stimuli,” J. Am. Acad. Audiol. 7, 130–136.
7.Chertoff, M. E. , Steele, T. , Ator, G. A. , and Bian, L. (1996). “Characterizing cochlear mechano-electric transduction using a nonlinear system identification procedure,” J. Acoust. Soc. Am. 100, 3741–3753.
8.Chertoff, M. E. , Steele, T. C. , and Bian, L. (1997). “Characterizing cochlear mechano-electric transduction in ears damaged with pure tones,” J. Acoust. Soc. Am. 102, 441–450.
9.Clark, J. A. , and Pickles, J. O. (1996). “The effects of moderate and low levels of acoustic overstimulation on stereocilia and their tip links in the guinea pig,” Hearing Res. 99, 119–128.
10.Cody, A. R. , and Russell, I. J. (1988). “Acoustically induced hearing loss: Intracellular studies in the guinea pig cochlea,” Hearing Res. 35, 59–70.
11.Cohen, J. (1988). “The effect size index: f,” in Statistical Power Analysis for the Behavioral Sciences (Erlbaum, Hillsdale, NJ), 2nd ed., pp. 274–288.
12.Dew, L. A. , Owen, Jr., R. G. , and Mulroy, M. J. (1993). “Changes in size and shape of auditory hair cells in vivo during noise-induced temporary threshold shift,” Hearing Res. 66, 99–107.
13.Didier, A. , Miller, J. M. , and Nuttall, A. L. (1993). “The vascular component of sodium salicylate ototoxicity in the guinea pig,” Hearing Res. 69, 199–206.
14.Dieler, R. , Shehata-Dieler, W. E. , and Brownell, W. E. (1991). “Concomitant salicylate-induced alterations of outer hair cell subsurface cisternae and electromotility,” J. Neurocytol.20, 637–653.
15.Douek, E. E. , Dodson, H. C. , and Bannister, L. H. (1983). “The effects of sodium salicylate on the cochlea of guinea pigs,” J. Laryngol. Otol. 93, 793–799.
16.Dulon, D. , Aran, J. M. , and Schacht, J. (1988). “Potassium-depolarization induces motility in isolated outer hair cells by an osmotic mechanism,” Hearing Res. 32, 123–130.
17.Fitzgerald, J. J. , Robertson, D. , and Johnstone, B. M. (1993). “Effects of intra-cochlear perfusion of salicylates on cochlear microphonic and other auditory responses in the guinea pig,” Hearing Res. 67, 147–156.
18.Frank, G. , and Kössl, M. (1996). “The acoustic two-tone distortions and and their possible relation to changes in the operating point of the cochlear amplifier,” Hearing Res. 98, 104–115.
19.Gao, W.-Y. , Ding, D.-L. , Zheng, X.-Y. , Ruan, F.-M. , and Liu, Y.-J. (1992). “A comparison of changes in the stereocilia between temporary and permanent hearing loss in acoustic trauma,” Hearing Res. 62, 27–41.
20.Honrubia, V. , and Ward, P. H. (1968). “Longitudinal distribution of the cochlear microphonics inside the cochlear duct (guinea pig),” J. Acoust. Soc. Am. 44, 951–958.
21.Howard, J. , and Hudspeth, A. J. (1988). “Compliance of the hair bundle associated with gating of mechanoelectrical transduction channels in the bull-frog’s saccular hair cell,” Neuron 1, 189–199.
22.Iwasa, K. H. (1993). “Effect of stress on the membrane capacitance of the auditory outer hair cell,” Biophys. J. 65, 492–498.
23.Johnstone, B. M. , Patuzzi, R. , Syka, J. , and Sykova, E. (1989). “Stimulus-related potassium changes in the organ of Corti of guinea-pig,” J. Physiol. (London) 408, 77–92.
24.Kakehata, S. , and Santos-Sacchi, J. (1996). “Effects of salicylate and lanthanides on outer hair cell motility and associated gating charge,” J. Neurosci. 16, 4881–4889.
25.Kirk, D. L. , Moleirinho, A. , and Patuzzi, R. B. (1997). “Microphonic and DPOAE measurements suggest a micromechanical mechanism for the ‘bounce’ phenomenon following low-frequency tones,” Hearing Res. 112, 69–86.
26.Kirk, D. L. , and Patuzzi, R. B. (1997). “Transient changes in cochlear potentials and DPOAEs after low-frequency tones: the ‘two-minute bounce’ revisited,” Hearing Res. 112, 49–68.
27.Kujawa, S. G. , Fallon, M. , and Bobbin, R. P. (1992). “Intracochlear salicylate reduces low-intensity acoustic and cochlear microphonic distortion products,” Hearing Res. 64, 73–80.
28.LePage, E. L. (1987). “Frequency-dependent self-induced bias of the basilar membrane and its potential for controlling sensitivity and tuning in the mammalian cochlea,” J. Acoust. Soc. Am. 82, 139–154.
29.Liberman, M. C. , and Dodds, L. W. (1987). “Acute ultrastructural changes in acoustic trauma: Serial-section reconstruction of stereocilia and cuticular plates,” Hearing Res. 26, 45–64.
30.Marascuilo, L. A., and Serlin, R. C. (1988). Statistical Methods for the Social and Behavioral Sciences (Freeman, New York).
31.McFadden, D. , and Plattsmier, H. S. (1983). “Aspirin can potentiate the temporary hearing loss induced by intense sounds,” Hearing Res. 9, 295–316.
32.Patuzzi, R. (1995). “Monitoring cochlear homeostasis with automatic analysis of the low-frequency cochlear microphonic,” in Active Hearing, edited by Å. Flock, D. Ottoson, and M. Ulfendahl (Elsevier, New York), pp. 141–153.
33.Puel, J-L. , Bobbin, R. P. , and Fallon, M. (1990). “Salicylate, mefenamate, meclofenate, and quinine on cochlear potentials,” Otolaryngol.-Head Neck Surg. 102, 66–73.
34.Ruggero, M. A. , Rich, N. C. , Recio, A. , Narayan, S. S. , and Robles, L. (1997). “Basilar-membrane responses to tones at the base of the chinchilla cochlea,” J. Acoust. Soc. Am. 101, 2151–2163.
35.Russell, I. J. , and Schauz, C. (1995). “Salicylate ototoxicity: effects on the stiffness and electromotility of outer hair cells isolated from the guinea pig cochlea,” Aud. Neurosci. 1, 309–319.
36.Santos-Sacchi, J. , and Dilger, J. P. (1988). “Whole-cell currents and mechanical responses of isolated outer hair cells,” Hearing Res. 35, 143–150.
37.Saunders, J. C., Canlon, B., and Flock, Å. (1986). “Mechanical changes in stereocilia following overstimulation: observation and possible mechanisms,” in Basic and Applied Aspects of Noise-Induced Hearing Loss, edited by R. J. Salvi, D. Henderson, R. P. Hamernik, and V. Colleti (Plenum, New York), pp. 11–30.
38.Saunders, J. C. , Cohen, Y. E. , and Szymko, Y. M. (1991). “The structural and functional consequences of acoustic injury in the cochlea and peripheral auditory system: A five year update,” J. Acoust. Soc. Am. 90, 136–146.
39.Shehata, W. E. , Brownell, W. E. , and Dieler, R. (1991). “Effects of salicylate on shape, electromotility and membrane characteristics of isolated outer hair cells from guinea pigs,” Acta Oto-Laryngol. 111, 707–718.
40.Stypulkowski, P. H. (1990). “The mechanisms of salicylate ototoxicity,” Hearing Res. 46, 13–46.
41.Young, M. A. (1993). “Supplementing tests of statistical significance: variation accounted for,” J. Speech Hear. Res. 36, 644–656.
42.Zhang, M. , and Zwislocki, J. J. (1996). “Intensity-dependent peak shift in cochlear transfer functions at the cellular level, its elimination by sound exposure, and its possible underlying mechanisms,” Hearing Res. 96, 46–58.
43.Zimmermann, U. , and Fermin, C. (1996). “Shape deformation of the organ of Corti associated with length changes of outer hair cell,” Acta Oto-Laryngol. 116, 395–400.
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