References
- Lotz P, Jakobi H, Kuhl K-D, Haberland E-J. The physiological influence of sound on the cochlea metabolism. Acta Otolaryngol (Stockh) 1981; 91: 445–50
- Haberland E-J, Kuhl K-D, Lotz P. Zu Problemen der perilymphatischen Cochleaperfusion unter besonderer Berücksichtigung der Sauerstoffpartialdruckmessung. Cochleaforschung '77, H Jakobi, K-D Kuhl. (S.) Wiss Beitr Martin-Luther-Univ Halle-Wittenberg, Halle 1979; 123–8, 1979/43 (R50)
- Lowry O H, Passoneau JV. A flexible system of enzymatic analysis. Academic Press, New York, London 1972
- Ernst A, Neumann H J, Haberland E-J, Lotz P. The production of perilymph in perfusion experiments. Cochlear Research 1983, L-P Löbe, P. Lotz. (S.) Wiss Beitr Martin-Luther-Univ Halle-Wittenberg, Halle 1984; 48–50, 1984/32 (R87).
- Lim D J, Kim H-N. The canaliculae perforantes of Schuknecht. Adv Oto-Rhino-Laryngol (Basel) 1983; 31: 85–117
- Tachibana M, Anniko M, Schacht J. Effect of perilymphatically perfused gentamycin on microphonic potential, lipid labeling and morphology of cochlear tissues. Acta Otolaryngol (Stockh) 1983; 96: 31–8
- Kambayashi J, De Mott J E, Comegys T H, Thalmann I, Thalmann R, Marcus NY. Effects of substrate-free vascular perfusion of the cochlea. J Acoust Soc Amer 1979; 66: S47–S47
- Keul J, Doll E, Keppler D. Energy metabolism of human muscle. Karger, Basel, Miinchen 1972
- Huckabee WE. Relationships of pyruvate and lactate during anaerobic metabolism. II. Exercise and formation of O2-debt. J Clin Invest 1958; 37: 255–63.; 264–71, III. Effect of breathing low-oxygen gases. Ibid.
- Lotz P, Haberland E-J, Kuhl K-D. The effect of glycogen in the cochlea metabolism. Inserm. (Paris) 1977; 68: 233–42
- Scheibe F, Haupt H, Rothe E, Hache U. Zur Glukose-, Pyruvat- und Laktatkonzentration von Perilymphe, Blut und Liquor cerebrospinalis unbelasteter und schallbelasteter Meerschweinchen in Äthylurethannarkose. Arch Otorhinolaryngol 1981; 233: 89–97
- Lim D J, Melnick W. Acoustic damage of the cochlea. Arch Otolaryngol 1971; 94: 294–305
- Nuttall A L, Hultcrantz E, Lawrence M. Does loud sound influence the intracochlear oxygen tension?. Hearing Res 1981; 5: 285–93
- Vertes D, Axelsson A, Hornstrand C, Nilsson P. The effect of impulse noise on cochlear vessels. Arch Otolaryngol 1984; 110: 111–15
- Axelsson A, Borg E, Hornstrand C. Noise effects on the vasculature in normotensive and spontaneously hypertensive rats. Acta Otolaryngol (Stockh) 1983; 96: 215–25
- Axelsson A, Vertes D. Histological findings in cochlear vessels after noise. New perspectives on noise-induced hearing loss, RP Hamernik, D Henderson, R Salvi. Raven Press, New York 1982; 49–68
- Misrahy G A, Hildreth K M, Shinabarger E W, Clark L C, Rice EA. Endolymphatic oxygen tension in the cochlea of the guinea pig. J Acoust Soc Amer 1958; 30: 701–4
- Ryan A F, Goodwin P, Woolf N K, Sharp F. Auditory stimulation alters the pattern of 2-deoxyglucose uptake in the inner ear. Brain Res 1982; 234: 213–25
- Canlon B, Schacht J. Acoustic stimulation alters deoxyglucose uptake in the mouse cochlea and inferior colliculus. Hearing Res 1983; 10: 217–26
- Saunders J. Discussion to: Schacht J. Biochemical aspects of noise-induced hearing loss. New perspectives on noise-induced hearing loss, RP Hamernik, D Henderson, R Salvi. Raven Press, New York 1982; 95–102
- Thalmann RR. Quantitative biochemical techniques for studying normal and noise-damaged ears. Effects of noise on hearing, D Henderson, RP Hamernik, DS Dosanjh, JH Mills. Raven Press, New York 1976; 129–55
- Thalmann R, Marcus D C, Thalmann I. Physiological chemistry of the cochlea. Adv Physiol Sci 1981; 16: 127–37
- Escoubet B, Amsallem P, Ferrary E, Tran BaHuy P. Prostaglandin synthesis by the cochlea of the guinea pig. Influence of aspirin, gentamycin, and acoustic stimulation. Prostaglandins 1985; 29: 589–99
- Konishi T, Salt AN. Electrochemical profile for potassium ions across the cochlear hair cell membrane of normal and noise-exposed guinea pigs. Hearing Res 1983; 11: 219–33
- Davis H. An active process in cochlear mechanics. Hearing Res 1983; 9: 79–90
- Wilson JP. Otoacoustic emissions and hearing mechanism. Revue Laryngol 1984; 105: 179–91
- Keidel WD. Resolved and unresolved issues in the physiology of hearing. Audiol Acoustics 1985; 24: 34–48; 78–90
- Borg E, Engström B. Damage to sensory hairs of inner ear cells after exposure to noise in rabbits without outer hair cells. Hearing Res 1984; 11: 1–6
- Meyer C, Biedermann M, Christner A. Früh- und Spätreaktion der Meerschweinchencochlea auf Impulsschall. Anat Anz (Jena) 1985; 158: 5–12
- Cramer W A, Widger W R, Herrmann R G, Trebst A. Topography and function of thylakoid membrane proteins. Trends Biochem Sci (Amsterdam) 1985; 10: 125–9
- Hunter-Duvar I M, Suzuki M, Mount RJ. Anatomical changes in the organ of Corti after acoustic stimulation. New perspectives on noise-induced hearing loss, RP Hamernik, D Henderson, R Salvi. Raven Press, New York 1982; 3–32
- Liberman M C, Mulroy MJ. Acute and chronic effects of acoustic trauma. Ibid.. 105–35
- Flock Å, Strelioff D. Studies on hair cells in isolated coils from the guinea pig cochlea. Hearing Res 1984; 15: 11–8
- Zenner H-P. Biochemical approaches to single outer hair cells. Cochlear Research 1983, L-P Löbe, P Lotz. (S.) Wiss Beitr Martin-Luther-Univ Halle-Wittenberg, Halle 1984; 17–20, 1984/32 (R87)
- Engström B, Flock Å, Borg E. Ultrastructural studies of stereocilia in noise exposed rabbits. Hearing Res 1983; 12: 251–64
- Legouix JP. Mechanisms involved in acoustic trauma: cochlear microphonic data. Revue Laryngol 1984; 105: 193–8