A Simplified Solid Mechanical and Acoustic Model for Human Middle Ear
Human middle-ear is the key component of the
auditory system. Its function is to transfer the sound waves through
the ear canal to provide sufficient stimulus to the fluids of the inner
ear. Degradation of the ossicles that transmit these sound waves from
the eardrum to the inner ear leads to hearing loss. This problem can
be overcome by replacing one or more of these ossicles by middleear
prosthesis. Designing such prosthesis requires a comprehensive
knowledge of the biomechanics of the middle-ear. There are many
finite element modeling approaches developed to understand the
biomechanics of the middle ear. The available models in the
literature, involve high computation time. In this paper, we propose a
simplified model which provides a reasonably accurate result with
much less computational time. Simulation results indicate a
maximum sound pressure gain of 10 dB at 5500 Hz.
[1] Neil R. Carlson, Physiology of behaviour, Pearson International Edition,
10th edition, Allyn & Bacon Publish,Boston, 2010.
[2] Breelove, et al., Biological Psychology, 5th edition, Sinauer Associates
Publication, Sinauer Associates and Sumanas Inc., 2007.
[3] M. Bance, A. Campos, L. Wong, D. Morris, and R. van Wijhe, "How
does prosthesis head size affect vibration transmission in
ossiculoplasty?" Journal of Otolaryngology, vol. 137, no. 1, pp. 70-73,
2007.
[4] S. E. Voss and W. T. Peake, "Non-ossicular signal transmission in
human middle ears: experimental assessment of the "acoustic route"
with perforated tympanic membranes," Journal of the Acoustical Society
of America, vol. 122, no. 4, pp. 2135-2153, 2007.
[5] C. Dai, M.W. Wood, and R. Z. Gan, "Combined effect of fluid and
pressure on middle ear function," Journal of Hearing Research, vol. 236,
no. 1-2, pp. 22-32, 2008.
[6] Yu-Hsuan Wen, Lee-Ping Hsu, Peir-Rong Chen, Chia-Fone Lee,
"Design Optimization of Cartilage Myringoplasty using Finite Element
Analysis," Tzu Chi Med J, vol. 18, no. 5, 2006.
[7] J. Tenney, M. A. Arriaga, D. A. Chen, and R. Arriaga, "Enhanced
hearing in heat-activated-crimping prosthesis stapedectomye," Journal
of Otolaryngology, vol. 138, no. 4, pp. 513-517, 2008.
[8] Yao Wen-juan, Ma Jian-wei, Hu-Bao-lin, "Numerical Model on Sound-
Solid Coupling in Human Ear and Study on Sound Pressure of
Tympanic Membrane," Mathematical Problems in Engineering, pp. 1-13,
2011.
[9] Williams, K.R.; Lesser, T.H.J., "A finite element analysis of the natural
frequencies of vibration of the human tympanic membrane," I. Br J
Audiol, vol. 24, pp. 319-327, 1990.
[10] Beer, H.J., Bornitz, M., Drescher, J., Schmidt, R., Hardtke, H.J., "Finite
element modeling of the human eardrum and applications," Huttenbrink
KB (ed), Middle ear mechanics in research and otosurgery, Department
of Oto-Rhino-Laryngology, Dresden University of Technology,
Dresden, Germany, pp. 40-47, 1996.
[11] Prendergast, P.J.; Ferris, P.; Rice, H.J.; Blayney, A.W., "Vibro-acoustic
modeling of the outer and middle ear using the finite element method,"
Audiol Neurootol, vol. 4, pp. 185-191, 1999.
[12] Q. Sun, K.H. Chang, K.J. Dormer, K.D. Jr. Robert, R.Z. Gan, "An
advanced computer-aided geometric modeling and fabrication method
for human middle ear," Med Engineering Physics, vol. 24, pp. 595-606,
2002.
[13] Kirikae I., "The structure and function of the middle ear," University of
Tokyo Press, Tokyo, 1960.
[14] Speirs, A.D., Hotz, M.A., Oxland, T.R., Hausler, R., Nolte, L.-P.,
"Biomechanical properties of sterilized human auditory ossicles," J
Biomech vol. 32, pp. 485-491, 1999.
[15] Herrmann, G., Liebowitz, H., "Mechanics of bone fractures. In:
Liebowitz H (ed.) Fracture: an advanced treatise," Academic Press, New
York, pp. 772-840, 1972.
[1] Neil R. Carlson, Physiology of behaviour, Pearson International Edition,
10th edition, Allyn & Bacon Publish,Boston, 2010.
[2] Breelove, et al., Biological Psychology, 5th edition, Sinauer Associates
Publication, Sinauer Associates and Sumanas Inc., 2007.
[3] M. Bance, A. Campos, L. Wong, D. Morris, and R. van Wijhe, "How
does prosthesis head size affect vibration transmission in
ossiculoplasty?" Journal of Otolaryngology, vol. 137, no. 1, pp. 70-73,
2007.
[4] S. E. Voss and W. T. Peake, "Non-ossicular signal transmission in
human middle ears: experimental assessment of the "acoustic route"
with perforated tympanic membranes," Journal of the Acoustical Society
of America, vol. 122, no. 4, pp. 2135-2153, 2007.
[5] C. Dai, M.W. Wood, and R. Z. Gan, "Combined effect of fluid and
pressure on middle ear function," Journal of Hearing Research, vol. 236,
no. 1-2, pp. 22-32, 2008.
[6] Yu-Hsuan Wen, Lee-Ping Hsu, Peir-Rong Chen, Chia-Fone Lee,
"Design Optimization of Cartilage Myringoplasty using Finite Element
Analysis," Tzu Chi Med J, vol. 18, no. 5, 2006.
[7] J. Tenney, M. A. Arriaga, D. A. Chen, and R. Arriaga, "Enhanced
hearing in heat-activated-crimping prosthesis stapedectomye," Journal
of Otolaryngology, vol. 138, no. 4, pp. 513-517, 2008.
[8] Yao Wen-juan, Ma Jian-wei, Hu-Bao-lin, "Numerical Model on Sound-
Solid Coupling in Human Ear and Study on Sound Pressure of
Tympanic Membrane," Mathematical Problems in Engineering, pp. 1-13,
2011.
[9] Williams, K.R.; Lesser, T.H.J., "A finite element analysis of the natural
frequencies of vibration of the human tympanic membrane," I. Br J
Audiol, vol. 24, pp. 319-327, 1990.
[10] Beer, H.J., Bornitz, M., Drescher, J., Schmidt, R., Hardtke, H.J., "Finite
element modeling of the human eardrum and applications," Huttenbrink
KB (ed), Middle ear mechanics in research and otosurgery, Department
of Oto-Rhino-Laryngology, Dresden University of Technology,
Dresden, Germany, pp. 40-47, 1996.
[11] Prendergast, P.J.; Ferris, P.; Rice, H.J.; Blayney, A.W., "Vibro-acoustic
modeling of the outer and middle ear using the finite element method,"
Audiol Neurootol, vol. 4, pp. 185-191, 1999.
[12] Q. Sun, K.H. Chang, K.J. Dormer, K.D. Jr. Robert, R.Z. Gan, "An
advanced computer-aided geometric modeling and fabrication method
for human middle ear," Med Engineering Physics, vol. 24, pp. 595-606,
2002.
[13] Kirikae I., "The structure and function of the middle ear," University of
Tokyo Press, Tokyo, 1960.
[14] Speirs, A.D., Hotz, M.A., Oxland, T.R., Hausler, R., Nolte, L.-P.,
"Biomechanical properties of sterilized human auditory ossicles," J
Biomech vol. 32, pp. 485-491, 1999.
[15] Herrmann, G., Liebowitz, H., "Mechanics of bone fractures. In:
Liebowitz H (ed.) Fracture: an advanced treatise," Academic Press, New
York, pp. 772-840, 1972.
@article{"International Journal of Medical, Medicine and Health Sciences:54521", author = "Adarsh Venkataraman Ganesan and Sundaram Swaminathan and Rama Jayaraj", title = "A Simplified Solid Mechanical and Acoustic Model for Human Middle Ear", abstract = "Human middle-ear is the key component of the
auditory system. Its function is to transfer the sound waves through
the ear canal to provide sufficient stimulus to the fluids of the inner
ear. Degradation of the ossicles that transmit these sound waves from
the eardrum to the inner ear leads to hearing loss. This problem can
be overcome by replacing one or more of these ossicles by middleear
prosthesis. Designing such prosthesis requires a comprehensive
knowledge of the biomechanics of the middle-ear. There are many
finite element modeling approaches developed to understand the
biomechanics of the middle ear. The available models in the
literature, involve high computation time. In this paper, we propose a
simplified model which provides a reasonably accurate result with
much less computational time. Simulation results indicate a
maximum sound pressure gain of 10 dB at 5500 Hz.", keywords = "Ear, Ossicles, COMSOL, Stapes.", volume = "7", number = "1", pages = "40-5", }
