Harvard Catalyst Profiles

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Jeffrey Tao Cheng, Ph.D.

Co-Author

This page shows the publications co-authored by Jeffrey Cheng and John Rosowski.
Connection Strength

6.646
  1. The onset of nonlinear growth of middle-ear responses to high intensity sounds. Hear Res. 2021 06; 405:108242.
    View in: PubMed
    Score: 0.957
  2. Tympanic membrane surface motions in forward and reverse middle ear transmissions. J Acoust Soc Am. 2019 01; 145(1):272.
    View in: PubMed
    Score: 0.818
  3. 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: 0.633
  4. Motion of the surface of the human tympanic membrane measured with stroboscopic holography. Hear Res. 2010 May; 263(1-2):66-77.
    View in: PubMed
    Score: 0.438
  5. Limitations of present models of blast-induced sound power conduction through the external and middle ear. J Acoust Soc Am. 2019 11; 146(5):3978.
    View in: PubMed
    Score: 0.433
  6. 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: 0.308
  7. Optical coherence tomographic measurements of the sound-induced motion of the ossicular chain in chinchillas: Additional modes of ossicular motion enhance the mechanical response of the chinchilla middle ear at higher frequencies. Hear Res. 2020 10; 396:108056.
    View in: PubMed
    Score: 0.229
  8. High-Speed Holographic Shape and Full-Field Displacement Measurements of the Tympanic Membrane in Normal and Experimentally Simulated Pathological Ears. Appl Sci (Basel). 2019 Jul 02; 9(14).
    View in: PubMed
    Score: 0.212
  9. Sound pressure distribution within human ear canals: II. Reverse mechanical stimulation. J Acoust Soc Am. 2019 03; 145(3):1569.
    View in: PubMed
    Score: 0.207
  10. Combined high-speed holographic shape and full-field displacement measurements of tympanic membrane. J Biomed Opt. 2018 09; 24(3):1-12.
    View in: PubMed
    Score: 0.200
  11. 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: 0.167
  12. In-plane and out-of-plane motions of the human tympanic membrane. J Acoust Soc Am. 2016 Jan; 139(1):104-17.
    View in: PubMed
    Score: 0.166
  13. Three-dimensional vibrometry of the human eardrum with stroboscopic lensless digital holography. J Biomed Opt. 2015 May; 20(5):051028.
    View in: PubMed
    Score: 0.159
  14. Full-field transient vibrometry of the human tympanic membrane by local phase correlation and high-speed holography. J Biomed Opt. 2014 Sep; 19(9):96001.
    View in: PubMed
    Score: 0.151
  15. Comparisons of the mechanics of partial and total ossicular replacement prostheses with cartilage in a cadaveric temporal bone preparation. Acta Otolaryngol. 2014 Aug; 134(8):776-84.
    View in: PubMed
    Score: 0.149
  16. Aligning digital holography images of tympanic membrane motion. J Acoust Soc Am. 2014 Apr; 135(4):2416.
    View in: PubMed
    Score: 0.147
  17. Digital holographic measurements of shape and 3D sound-induced displacements of Tympanic Membrane. Opt Eng. 2013 Oct 01; 52(10):101916.
    View in: PubMed
    Score: 0.142
  18. Wave motion on the surface of the human tympanic membrane: holographic measurement and modeling analysis. J Acoust Soc Am. 2013 Feb; 133(2):918-37.
    View in: PubMed
    Score: 0.136
  19. Assessing eardrum deformation by digital holography. SPIE Newsroom. 2013 Jan 09.
    View in: PubMed
    Score: 0.135
  20. Measurements of three-dimensional shape and sound-induced motion of the chinchilla tympanic membrane. Hear Res. 2013 Jul; 301:44-52.
    View in: PubMed
    Score: 0.134
  21. New data on the motion of the normal and reconstructed tympanic membrane. Otol Neurotol. 2011 Dec; 32(9):1559-67.
    View in: PubMed
    Score: 0.125
  22. Middle ear mechanics of cartilage tympanoplasty evaluated by laser holography and vibrometry. Otol Neurotol. 2009 Dec; 30(8):1209-14.
    View in: PubMed
    Score: 0.109
  23. Motion of the tympanic membrane after cartilage tympanoplasty determined by stroboscopic holography. Hear Res. 2010 May; 263(1-2):78-84.
    View in: PubMed
    Score: 0.109
  24. Computer-assisted time-averaged holograms of the motion of the surface of the mammalian tympanic membrane with sound stimuli of 0.4-25 kHz. Hear Res. 2009 Jul; 253(1-2):83-96.
    View in: PubMed
    Score: 0.104
  25. Multiple angle digital holography for the shape measurement of the unpainted tympanic membrane. Opt Express. 2020 Aug 17; 28(17):24614-24628.
    View in: PubMed
    Score: 0.057
  26. Mapping the phase and amplitude of ossicular chain motion using sound-synchronous optical coherence vibrography. Biomed Opt Express. 2018 Nov 01; 9(11):5489-5502.
    View in: PubMed
    Score: 0.050
  27. Design, fabrication, and in vitro testing of novel three-dimensionally printed tympanic membrane grafts. Hear Res. 2016 10; 340:191-203.
    View in: PubMed
    Score: 0.042
  28. Viscoelastic properties of the human tympanic membrane studied with stroboscopic holography and finite element modeling. Hear Res. 2014 Jun; 312:69-80.
    View in: PubMed
    Score: 0.037
  29. Simultaneous 3D imaging of sound-induced motions of the tympanic membrane and middle ear ossicles. Hear Res. 2013 Oct; 304:49-56.
    View in: PubMed
    Score: 0.035
  30. Holographic otoscope for nanodisplacement measurements of surfaces under dynamic excitation. Scanning. 2011 Sep-Oct; 33(5):342-52.
    View in: PubMed
    Score: 0.031
  31. Optoelectronic holographic otoscope for measurement of nano-displacements in tympanic membranes. J Biomed Opt. 2009 May-Jun; 14(3):034023.
    View in: PubMed
    Score: 0.026
Connection Strength
The connection strength for co-authors is the sum of the scores for each of their shared publications.

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.