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John J. Rosowski, Ph.D.

Concepts

This page shows the publications John Rosowski has written about Ear Canal.
Connection Strength

5.213
  1. Sound pressure distribution within human ear canals: II. Reverse mechanical stimulation. J Acoust Soc Am. 2019 03; 145(3):1569.
    View in: PubMed
    Score: 0.736
  2. The Effect of Ear Canal Orientation on Tympanic Membrane Motion and the Sound Field Near the Tympanic Membrane. J Assoc Res Otolaryngol. 2015 Aug; 16(4):413-32.
    View in: PubMed
    Score: 0.564
  3. Sound pressure distribution within natural and artificial human ear canals: forward stimulation. J Acoust Soc Am. 2014 Dec; 136(6):3132.
    View in: PubMed
    Score: 0.549
  4. Factors that introduce intrasubject variability into ear-canal absorbance measurements. Ear Hear. 2013 Jul; 34 Suppl 1:60S-64S.
    View in: PubMed
    Score: 0.497
  5. Ear-canal reflectance, umbo velocity, and tympanometry in normal-hearing adults. Ear Hear. 2012 Jan-Feb; 33(1):19-34.
    View in: PubMed
    Score: 0.448
  6. Sound pressure distribution and power flow within the gerbil ear canal from 100 Hz to 80 kHz. J Acoust Soc Am. 2007 Oct; 122(4):2154-73.
    View in: PubMed
    Score: 0.334
  7. A mechano-acoustic model of the effect of superior canal dehiscence on hearing in chinchilla. J Acoust Soc Am. 2007 Aug; 122(2):943-51.
    View in: PubMed
    Score: 0.330
  8. Testing a method for quantifying the output of implantable middle ear hearing devices. Audiol Neurootol. 2007; 12(4):265-76.
    View in: PubMed
    Score: 0.322
  9. Effect of Middle-Ear Pathology on High-Frequency Ear Canal Reflectance Measurements in the Frequency and Time Domains. J Assoc Res Otolaryngol. 2019 12; 20(6):529-552.
    View in: PubMed
    Score: 0.193
  10. Chinchilla middle ear transmission matrix model and middle-ear flexibility. J Acoust Soc Am. 2017 05; 141(5):3274.
    View in: PubMed
    Score: 0.162
  11. Middle-ear and inner-ear contribution to bone conduction in chinchilla: The development of Carhart's notch. Hear Res. 2016 10; 340:144-152.
    View in: PubMed
    Score: 0.149
  12. Response of the human tympanic membrane to transient acoustic and mechanical stimuli: Preliminary results. Hear Res. 2016 10; 340:15-24.
    View in: PubMed
    Score: 0.149
  13. Chinchilla middle-ear admittance and sound power: high-frequency estimates and effects of inner-ear modifications. J Acoust Soc Am. 2012 Oct; 132(4):2437-54.
    View in: PubMed
    Score: 0.118
  14. Comparison of ear-canal reflectance and umbo velocity in patients with conductive hearing loss: a preliminary study. Ear Hear. 2012 Jan-Feb; 33(1):35-43.
    View in: PubMed
    Score: 0.112
  15. Middle ear function and cochlear input impedance in chinchilla. J Acoust Soc Am. 2010 Mar; 127(3):1397-410.
    View in: PubMed
    Score: 0.099
  16. Differential intracochlear sound pressure measurements in normal human temporal bones. J Assoc Res Otolaryngol. 2009 Mar; 10(1):23-36.
    View in: PubMed
    Score: 0.091
  17. Cochlear nonlinearities inferred from two-tone distortion products in the ear canal of the alligator lizard. Hear Res. 1984 Feb; 13(2):141-58.
    View in: PubMed
    Score: 0.065
  18. Tests of some common assumptions of ear-canal acoustics in cats. J Acoust Soc Am. 2000 Sep; 108(3 Pt 1):1147-61.
    View in: PubMed
    Score: 0.051
  19. Middle ear pathology can affect the ear-canal sound pressure generated by audiologic earphones. Ear Hear. 2000 Aug; 21(4):265-74.
    View in: PubMed
    Score: 0.051
  20. Acoustic mechanisms that determine the ear-canal sound pressures generated by earphones. J Acoust Soc Am. 2000 Mar; 107(3):1548-65.
    View in: PubMed
    Score: 0.049
  21. Comparison of forward (ear-canal) and reverse (round-window) sound stimulation of the cochlea. Hear Res. 2013 Jul; 301:105-14.
    View in: PubMed
    Score: 0.030
  22. Non-ossicular signal transmission in human middle ears: Experimental assessment of the "acoustic route" with perforated tympanic membranes. J Acoust Soc Am. 2007 Oct; 122(4):2135-53.
    View in: PubMed
    Score: 0.021
  23. A model for signal transmission in an ear having hair cells with free-standing stereocilia. II. Macromechanical stage. Hear Res. 1985; 20(2):139-55.
    View in: PubMed
    Score: 0.017
  24. A model for signal transmission in an ear having hair cells with free-standing stereocilia. I. Empirical basis for model structure. Hear Res. 1985; 20(2):131-8.
    View in: PubMed
    Score: 0.017
  25. Mechanisms of hearing loss resulting from middle-ear fluid. Hear Res. 2004 Sep; 195(1-2):103-30.
    View in: PubMed
    Score: 0.017
  26. Middle-ear mechanics of Type III tympanoplasty (stapes columella): I. Experimental studies. Otol Neurotol. 2003 Mar; 24(2):176-85.
    View in: PubMed
    Score: 0.015
  27. Mammalian ear specializations in arid habitats: structural and functional evidence from sand cat (Felis margarita). J Comp Physiol A Neuroethol Sens Neural Behav Physiol. 2002 Oct; 188(9):663-81.
    View in: PubMed
    Score: 0.015
  28. Relating middle-ear acoustic performance to body size in the cat family: measurements and models. J Comp Physiol A. 2000 May; 186(5):447-65.
    View in: PubMed
    Score: 0.012
Connection Strength

The connection strength for concepts is the sum of the scores for each matching publication.

Publication scores are based on many factors, including how long ago they were written and whether the person is a first or senior author.

Funded by the NIH National Center for Advancing Translational Sciences through its Clinical and Translational Science Awards Program, grant number UL1TR002541.