Principales
références |
|
Sur les cellules ciliées externes en général |
Revues
a1. SPOENDLIN,
H. Anatomy of cochlear innervation. Am.
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a2. Pujol R.
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Ouvrages
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a12. DALLOS,
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a21. RUSSELL, I.J., SELLICK, P.M. Intracellular studies
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a22. DALLOS, P., SANTOS-SACCHI, J., FLOCK, Å Intracellular recordings
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a23. DALLOS, P. Response characteristics of mammalian cochlear hair cells. J. Neurosci. 5,
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a24. ASHMORE,
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of guinea pig cochlea. Nature
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a25. PUJOL R., LENOIR M., LADRECH S., TRIBILLAC, F. and REBILLARD G.,
1991 - Correlation within and across species between the length of outer
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Press, pp. 45-52 |
|
Sur
les synapses |
Revues
b1. SPOENDLIN,
H. Innervation patterns in the organ of Corti of the cat. Acta Otolaryngol.
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b2. SPOENDLIN, H. Anatomy of cochlear innervation. Am. J. Otolaryngol. 6, 453-467,1985
b3. PUJOL, R., LENOIR, M. The four types of synapses
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b4. ALTSCHULER, R.A., FEX, J. Efferent neurotransmitters.
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aussi
b11. WARR, W.B., GUINAN, J.J., Jr. Efferent innervation
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b12. BERGLUND, A.M., RYUGO, D.K. () Hair cell innervation by spiral ganglion
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microscopy distinguishes at least three types of efferent synapses in
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|
Sur
le couplage mécanique CCE /cellules annexes |
Revues
c1. Pujol
R, (1990) Neurobiologie de la cochlée. Médecine/Sciences,
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aussi
c11. VATER M., LENOIR M. and PUJOL R., 1992, Ultrastructure
of the horseshoe bat's organ of Corti. II. Transmission electron microscopy. J. Comp. Neurol., 318, 380-391
c12. Zhao HB, Santos-Sacchi J, 1999. Auditory collusion and a coupled
couple of outer hair cells, Nature May 27;399(6734):359-62 |
|
Sur
la membrane latérale des CCE |
d1. BROWNELL
WE, BADER CR, BERTRAND D, DE RIBAUPIERRE Y (1985) Evoked mechanical
responses of isolated cochlear outer hair cells. Science 227:194-196.
d2. KACHAR, B., BROWNELL, W.E., ALTSCHULER, R., FEX, J. Electrokinetic shape
changes of cochlear outer hair cells. Nature 322, 365-367, 1986.
d3. Holley
MC, Ashmore JF, A cytoskeletal spring in cochlear
outer hair cells. Nature. 1988,335(6191):635-7.
d4. Kalinec,
F., M.C. Holley, K.H. Iwasa, D.J. Lim & B. Kachar. 1992. A Membrane-Based
Force Generation Mechanism in Auditory Sensory Cells. Proc.
Natl. Acad. Sci. USA 89: 8671-8675.
d5. Huang
G, Santos-Sacchi J, 1994. Motility voltage sensor of the outer hair
cell resides within the lateral plasma membrane. Proc
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d6. Tolomeo,
J.A., C.R. Steele & M.C. Holley. 1996. Mechanical properties of
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d7. Le
Grimellec C, Vater M, Lenoir M, Giocondi MC and Pujol R, 1999. High
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|
Sur
la physiologie et les mécanismes actifs |
Revues
e1. SANTOS-SACCHI,
J. Cochlear physiology. In: Physiology of the Ear, A.F. Jahn and J.
Santos-Sacchi, eds, Raven Press, New York, pp. 271-293, 1988.
e2. DALLOS, P. The active cochlea. J.
Neurosc., 12, 4575-4585, 1992.
e3. DULON
D, ARAN JM (1990) Aspects cellulaires et moléculaires de la transduction
mécano-sensorielle dans l'oreille interne. Médecine/Sciences
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e4. Ashmore
JF, Kolston PJ, Hair cell based amplification in the cochlea. Curr
Opin Neurobiol 1994 Aug;4(4):503-8
e5. ULFENDAHL,
M. Mechanical responses of the mammalian cochlea. Prog. Neurobiol., 53, 331-380, 1997.
e6. Ashmore J, Geleoc GS Hearing in
the fast lane. Curr
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...et aussi
e11. GOLD T (1948) Hearing. The physical basis of the action of the
cochlea. Proc R Soc Edinburgh [Biol Sci] 135:492-498.
e12. BROWNELL WE, BADER CR, BERTRAND D, DE RIBAUPIERRE Y (1985) Evoked
mechanical responses of isolated cochlear outer hair cells. Science
227:194-196.
e13. KACHAR, B., BROWNELL, W.E., ALTSCHULER, R., FEX, J. Electrokinetic shape
changes of cochlear outer hair cells. Nature
322, 365-367, 1986.
e14. ASHMORE
JF (1987) A fast motile response in guinea-pig outer hair cells: the
cellular basis of the cochlear amplifier. J
Physiol (Lond). 1987 Jul;388:323-47.
e15. Zenner HP, Motility of
outer hair cells as an active, actin-mediated process. Acta
Otolaryngol. (Stockh.) 105, 39-44, 1988
e16. Dulon D, Zajic G. and Schacht J, Increase in intracellular free
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e17. Dulon D, Zajic G, Schacht J, Differential motile response of isolated
inner and outer hair cells to stimulation by potassium and calcium ions. Hear
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e18. Mammano F, Kros CJ, Ashmore JF, Patch clamped
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e19. Dallos
P, Evans BN, Hallworth R. Nature of the motor element in electrokinetic
shape changes of cochlear outer hair cells. Nature.
1991 Mar 14;350(6314):155-7.
e20. Dallos P, He DZ, Lin X, Sziklai I, Mehta S, Evans
BN, Acetylcholine, outer hair cell electromotility, and the cochlear
amplifier. J
Neurosci 1997 Mar 5;17(6):2212-26
e21. Geleoc GS, Casalotti SO, Forge A, Ashmore JF. A sugar
transporter as a candidate for the outer hair cell motor. Nat
Neurosci. 1999 Aug;2(8):713-9.
e22. Zheng
J, Shen W, He DZ, Long KB, Madison LD, Dallos P. Prestin
is the motor protein of cochlear outer hair cells. Nature.
2000 May 11;405(6783):149-55
e23. Liberman
MC, Gao J, He DZ, Wu X, Jia S, Zuo J. Prestin is required for electromotility
of the outer hair cell and for the cochlear amplifier. Nature.
2002 Sep 19;419(6904):300-4.
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|
Sur
les oto-émissions |
Revues
f1. Zurek
PM, (1985) Acoustic emissions from the ear: a summary of results from
humans and animals. J. Acoust. Soc. Amer., 78: 340-344
f2. Bonfils
P, Uziel A and Pujol R, (1988) Evoked otoacoustic emissions: a fundamental
and clinical survey. ORL J Otorhinolaryngol Relat
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R, 1990. Otoacoustic emissions: an overview. Advances
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f4. Norton
SJ, Application of transient evoked otoacoustic emissions to pediatric
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aussi
f11.GOLD
T (1948) Hearing: The physical basis of the action of the cochlea. Proc
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f12. KEMP Otoacoustic emissions, travelling waves and cochlear mechanisms. Hear Res 1986;22:95-104
f13. WILSON JP (1980) Evidence for a cochlear origin for acoustic re-emissions
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...et
aussi
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