Yin, L. et al. Imaging light actions of retinal ganglion cells in the living mouse eye. J. Neurophysiol. 109, 2415– 2421 (2013 ).
Google Scholar.
Charpak, S., Mertz, J., Beaurepaire, E., Moreaux, L. & & Delaney, K. Odor-evoked calcium signals in dendrites of rat mitral cells. Proc. Natl Acad. Sci. U.S.A. 98, 1230– 1234 (2001 ).
Google Scholar.
Barretto, R. P. J. et al. The neural representation of taste quality at the periphery. Nature 517, 373– U511 (2015 ).
Google Scholar.
Kim, Y. S. et al. Coupled activation of main sensory nerve cells adds to persistent discomfort. Nerve Cell 91, 1085– 1096 (2016 ).
Google Scholar.
Imamura, S. & & Adams, J. C. Circulation of gentamicin in the guinea pig inner ear after regional or systemic application. J. Assoc. Res. Otolaryngol. 4, 176– 195 (2003 ).
Google Scholar.
Wang, Q. & & Steyger, P. S. Trafficking of systemic fluorescent gentamicin into the cochlea and hair cells. J. Assoc. Res. Otolaryngol. 10, 205– 219 (2009 ).
Google Scholar.
Tanoshima, R. et al. Analyses of negative drug reactions-nationwide active security network: Canadian Pharmacogenomics Network for Drug Security Database. J. Clin. Pharmacol. 59, 356– 363 (2019 ).
Google Scholar.
Du, X. et al. A hand-guided robotic drill for cochleostomy on human cadavers. Robotic Surg. 5, 13– 18 (2018 ).
Fishman, A. J., Moreno, L. E., Rivera, A. & & Richter, C. P. CO 2 laser fiber soft cochleostomy: advancement of a strategy utilizing human temporal bones and a guinea pig design. Laser Surg. Medication. 42, 245– 256 (2010 ).
Google Scholar.
Ren, D. D. & & Chi, F. L. Speculative research study on thermic results, morphology and function of guinea pig cochlea: a contrast in between the erbium: yttrium– aluminum– garnet laser and co2 laser. Laser Surg. Medication. 40, 407– 414 (2008 ).
Google Scholar.
Cipolla, M. J., Iyer, P., Dome, C., Welling, D. B. & & Bush, M. L. Adjustment and contrast of minimally intrusive cochleostomy methods: a pilot research study. Laryngoscope 122, 1142– 1147 (2012 ).
Google Scholar.
Kiefer, J. et al. Preservation of low-frequency hearing in cochlear implantation. Acta Oto-Laryngol. 124, 272– 280 (2004 ).
Google Scholar.
Dong, W. & & Cooper, N. P. A speculative research study into the acousto-mechanical results of getting into the cochlea. J. R. Soc. User Interface 3, 561– 571 (2006 ).
Google Scholar.
Cooper, N. P. & & Rhode, W. S. Quick taking a trip waves, sluggish taking a trip waves and their interactions in speculative research studies of apical cochlear mechanics. Audit Neurosci. 2, 289– 299 (1996 ).
Ulfendahl, M., Khanna, S. M. & & Flock, A. Results of opening and resealing the cochlea on the mechanical action in the separated temporal bone preparation. Hearing Res. 57, 31– 37 (1991 ).
Google Scholar.
Alyono, J. C., Corrales, C. E., Huth, M. E., Blevins, N. H. & & Ricci, A. J. Advancement and characterization of chemical cochleostomy in the guinea pig. Otolaryngol. Head. Neck Surg. 152, 1113– 1118 (2015 ).
Google Scholar.
Kim, J. & & Ricci, A.J. In vivo real-time imaging exposes megalin as the aminoglycoside gentamicin transporter into cochlea whose inhibition is otoprotective. Proc. Natl Acad. Sci. U.S.A. 119, e2117946119 (2022 ).
Google Scholar.
Lee, H. Y. et al. Noninvasive in vivo imaging exposes distinctions in between tectorial membrane and basilar membrane taking a trip waves in the mouse cochlea. Proc. Natl Acad. Sci. U.S.A. 112, 3128– 3133 (2015 ).
Google Scholar.
Nuttall, A. L., Dolan, D. F. & & Avinash, G. Laser Doppler velocimetry of basilar membrane vibration. Hear. Res. 51, 203– 213 (1991 ).
Google Scholar.
Ruggero, M. A. & & Rich, N. C. Application of a commercially-manufactured Doppler-shift laser velocimeter to the measurement of basilar-membrane vibration. Hear. Res. 51, 215– 230 (1991 ).
Google Scholar.
Ren, T. Longitudinal pattern of basilar membrane vibration in the delicate cochlea. Proc. Natl Acad. Sci. U.S.A. 99, 17101– 17106 (2002 ).
Google Scholar.
Ren, T. Reverse proliferation of noise in the gerbil cochlea. Nat. Neurosci. 7, 333– 334 (2004 ).
Google Scholar.
Dong, W. & & Olson, E. S. Detection of cochlear amplification and its activation. Biophys. J. 105, 1067– 1078 (2013 ).
Google Scholar.
Dallos, P. Reaction attributes of mammalian cochlear hair cells. J. Neurosci. 5, 1591– 1608 (1985 ).
Google Scholar.
Russell, I. J. & & Sellick, P. M. Low-frequency attributes of intracellularly tape-recorded receptor capacities in guinea-pig cochlear hair cells. J. Physiol. 338, 179– 206 (1983 ).
Google Scholar.
Liberman, M. C. Auditory-nerve action from felines raised in a low-noise chamber. J. Acoust. Soc. Am. 63, 442– 455 (1978 ).
Google Scholar.
Lee, H. Y. et al. Two-dimensional cochlear micromechanics determined in vivo show radial tuning within the mouse organ of Corti. J. Neurosci. 36, 8160– 8173 (2016 ).
Google Scholar.
Wang, R. K. & & Nuttall, A. L. Phase-sensitive optical coherence tomography imaging of the tissue movement within the organ of Corti at a subnanometer scale: an initial research study. J. Biomed. Decide. 15, 056005 (2010 ).
Google Scholar.
Jawadi, Z., Applegate, B. E. & & Oghalai, J. S. Optical coherence tomography to determine sound-induced movements within the mouse organ of Corti in vivo. Techniques Mol. Biol. 1427, 449– 462 (2016 ).
Google Scholar.
Kim, J., Xia, A., Grillet, N., Applegate, B. E. & & Oghalai, J. S. Osmotic stabilization avoids cochlear synaptopathy after blast injury. Proc. Natl Acad. Sci. U.S.A. 115, E4853– E4860 (2018 ).
Google Scholar.
McGinley, M. J., Liberman, M. C., Bal, R. & & Oertel, D. Getting synchrony from the asynchronous: settlement for cochlear taking a trip wave hold-ups by the dendrites of specific brainstem nerve cells. J. Neurosci. 32, 9301– 9311 (2012 ).
Google Scholar.
Marker, D.F., Tremblay, M.E., Lu, S.M., Majewska, A.K. & & Gelbard, H.A. A thin-skull window strategy for persistent two-photon in vivo imaging of murine microglia in designs of neuroinflammation. J. Vis. Exp 43, 2059 (2010 ).
Mancini, M. et al. Head and neck veins of the mouse. a magnetic resonance, micro computed tomography and high frequency color Doppler ultrasound research study. PLoS ONE 10, e0129912 (2015 ).
Google Scholar.
