Static and Dynamic Load on Hip Contact of Hip Prosthesis and Thai Femoral Bones
Total hip replacement had been one of the most
successful operations in hip arthritis surgery. The purpose of this
research had been to develop a dynamic hip contact of Thai femoral
bone to analyze the stress distribution on the implant and the strain
distribution on the bone model under daily activities and compared
with the static load simulation. The results showed the different of
maximum von Mises stress 0.14 percent under walking and 0.03
percent under climbing stair condition and the different of equivalent
total strain 0.52 percent under walking and 0.05 percent under
climbing stair condition. The muscular forces should be evaluated
with dynamic condition to reduce the maximum von Mises stress and
equivalent total strain.
[1] E.J. Hellman, W. N. Capello, and J.R. Feinberg. “Omni fit cementless
total hip arthroplasty: a 10-year average follow-up” Clin Orthop. 1999
vol. 364, pp.164-174.
[2] M.M. Alexiades, M.R. Clain and M.J. Bronson. “Prospective study of
porous coated anatomic total hip arthroplasty” Clin Orthop. 1991 vol.
269, pp. 205-208.
[3] B.C. Burkhart, R.B. Bourne and C.H. Rorabeck. “Thigh pain in
cementless total hip arthroplasty: a comparison of two systems at 2
years’ follow-up” Orthop Clin North Am. 1993 vol. 24, pp. 645-653.
[4] P.A. Dowdy, C.H. Rorabeck and R.B. Bourne. “Uncemented total hip
arthroplasty in patients 50 years of age or younger” J. Arthroplasty 1997
vol. 12, pp. 853-862.
[5] W.C. Head, T.H. Mallory and R.H. Emerson Jr. “The proximal porous
coating alternative for primary total hip arthroplasty” Orthopedics 1999
vol. 22, pp. 813-815.
[6] T.H. Mallory, W.C. Head and A.V. Lombardi. “Tapered design for the
cementless total hip arthroplasty femoral component” Clin Orthop 1997
vol. 344, pp. 172-178.
[7] T.H. Mallory, W.C. Head and A.V. Lombardi Jr. “Clinical and
radiographic outcome of a cementless, titanium, plasma spray-coated
total hip arthroplasty femoral component: justification for continuance
of use” J. Arthroplasty 1996 vol. 11, pp. 653-660.
[8] B.D. Mulliken, R.B. Bourne and C.H. Rorabeck. “A tapered titanium
femoral stem inserted without cement in a total hip arthroplasty:
radiographic evaluation and stability” J. Bone Joint Surg Am 1996 vol.
78, pp. 1214-1225. [9] P. Aroonjarattham, K. Aroonjarattham and C. Suvanjumrat. “Effect of
mechanical axis on strain distribution after total knee replacement”
Kasetsart J. (Nat. Sci.) 2014 vol. 48, pp.263-282.
[10] A. Ramos and J.A. Simoes. “Tetrahedral versus hexahedral finite
elements in numerical modeling of the proximal femur” J. Med
Eng&Phy 2006 vol. 28, pp. 916-924.
[11] A. Peraz, A. Mahar, C. Negus, P. Newton, and T.J. Impelluso, “A
computational evaluation of the effect of intramedullary nail material
properties on the stabilization of simulated femoral shaft fracture” J.
Med Eng & Phys 2008 vol. 30, pp.755-760.
[12] M.O. Heller, G. Bergman, J.P. Kassi, L. Claes, N.P. Hass and G.N.
Duda, “Determination of muscle loading at the hip joint for use in preclinical
testing,” J. Biomechanics 2004 vol. 38, pp. 1155-1163.
[13] C. Fabry, S. Herrmann, M. Kaehler, E.D. Klinkenberg, C. Woernle and
R. Bader. “Generation of physiological parameter sets for hip joint
motions and loads during daily life activities for application in wear
simulators of the artificial hip” Med Eng & Phy 2013 vol. 35, pp. 131-
139.
[14] Z. Paul, B. David, E.G. Allan and P. Marcello. “Notching of the
Anterior Femoral Cortex during Total Knee Arthoplasty” J. Arthroplasty
2006 vol. 21, pp. 737-743.
[15] D.G. Chess, R.W. Grainger, T. Phillips, Z.D. Zarzour and B.R.
Sheppard. “The cementless anatomic medullary locking femoral
component: an independent clinical and radiographic assessment” Can J.
Surg 1996 vol. 39, pp. 388-392.
[16] H. Effenberger, T. Ramsauer, G. Bohm, G. Hilzensauer, U. Dorn and F.
Lintner. “Successful hip arthroplasty using cementless titanium implants
in rheumatoid arthritis” Arch Orthop Trauma Surg 2002 vol. 122, pp.
80-87.
[17] J. Black and G. Hastings. 1998 “Handbook of biomaterials properties”
Chapman & Hall, UK.
[18] H.M. Frost. “Bone Mass and the Mechanostat:A Proposal” The
Anatomical Record 1987 vol. 219, pp. 1-9.
[1] E.J. Hellman, W. N. Capello, and J.R. Feinberg. “Omni fit cementless
total hip arthroplasty: a 10-year average follow-up” Clin Orthop. 1999
vol. 364, pp.164-174.
[2] M.M. Alexiades, M.R. Clain and M.J. Bronson. “Prospective study of
porous coated anatomic total hip arthroplasty” Clin Orthop. 1991 vol.
269, pp. 205-208.
[3] B.C. Burkhart, R.B. Bourne and C.H. Rorabeck. “Thigh pain in
cementless total hip arthroplasty: a comparison of two systems at 2
years’ follow-up” Orthop Clin North Am. 1993 vol. 24, pp. 645-653.
[4] P.A. Dowdy, C.H. Rorabeck and R.B. Bourne. “Uncemented total hip
arthroplasty in patients 50 years of age or younger” J. Arthroplasty 1997
vol. 12, pp. 853-862.
[5] W.C. Head, T.H. Mallory and R.H. Emerson Jr. “The proximal porous
coating alternative for primary total hip arthroplasty” Orthopedics 1999
vol. 22, pp. 813-815.
[6] T.H. Mallory, W.C. Head and A.V. Lombardi. “Tapered design for the
cementless total hip arthroplasty femoral component” Clin Orthop 1997
vol. 344, pp. 172-178.
[7] T.H. Mallory, W.C. Head and A.V. Lombardi Jr. “Clinical and
radiographic outcome of a cementless, titanium, plasma spray-coated
total hip arthroplasty femoral component: justification for continuance
of use” J. Arthroplasty 1996 vol. 11, pp. 653-660.
[8] B.D. Mulliken, R.B. Bourne and C.H. Rorabeck. “A tapered titanium
femoral stem inserted without cement in a total hip arthroplasty:
radiographic evaluation and stability” J. Bone Joint Surg Am 1996 vol.
78, pp. 1214-1225. [9] P. Aroonjarattham, K. Aroonjarattham and C. Suvanjumrat. “Effect of
mechanical axis on strain distribution after total knee replacement”
Kasetsart J. (Nat. Sci.) 2014 vol. 48, pp.263-282.
[10] A. Ramos and J.A. Simoes. “Tetrahedral versus hexahedral finite
elements in numerical modeling of the proximal femur” J. Med
Eng&Phy 2006 vol. 28, pp. 916-924.
[11] A. Peraz, A. Mahar, C. Negus, P. Newton, and T.J. Impelluso, “A
computational evaluation of the effect of intramedullary nail material
properties on the stabilization of simulated femoral shaft fracture” J.
Med Eng & Phys 2008 vol. 30, pp.755-760.
[12] M.O. Heller, G. Bergman, J.P. Kassi, L. Claes, N.P. Hass and G.N.
Duda, “Determination of muscle loading at the hip joint for use in preclinical
testing,” J. Biomechanics 2004 vol. 38, pp. 1155-1163.
[13] C. Fabry, S. Herrmann, M. Kaehler, E.D. Klinkenberg, C. Woernle and
R. Bader. “Generation of physiological parameter sets for hip joint
motions and loads during daily life activities for application in wear
simulators of the artificial hip” Med Eng & Phy 2013 vol. 35, pp. 131-
139.
[14] Z. Paul, B. David, E.G. Allan and P. Marcello. “Notching of the
Anterior Femoral Cortex during Total Knee Arthoplasty” J. Arthroplasty
2006 vol. 21, pp. 737-743.
[15] D.G. Chess, R.W. Grainger, T. Phillips, Z.D. Zarzour and B.R.
Sheppard. “The cementless anatomic medullary locking femoral
component: an independent clinical and radiographic assessment” Can J.
Surg 1996 vol. 39, pp. 388-392.
[16] H. Effenberger, T. Ramsauer, G. Bohm, G. Hilzensauer, U. Dorn and F.
Lintner. “Successful hip arthroplasty using cementless titanium implants
in rheumatoid arthritis” Arch Orthop Trauma Surg 2002 vol. 122, pp.
80-87.
[17] J. Black and G. Hastings. 1998 “Handbook of biomaterials properties”
Chapman & Hall, UK.
[18] H.M. Frost. “Bone Mass and the Mechanostat:A Proposal” The
Anatomical Record 1987 vol. 219, pp. 1-9.
@article{"International Journal of Medical, Medicine and Health Sciences:69251", author = "K. Chalernpon and P. Aroonjarattham and K. Aroonjarattham", title = "Static and Dynamic Load on Hip Contact of Hip Prosthesis and Thai Femoral Bones", abstract = "Total hip replacement had been one of the most
successful operations in hip arthritis surgery. The purpose of this
research had been to develop a dynamic hip contact of Thai femoral
bone to analyze the stress distribution on the implant and the strain
distribution on the bone model under daily activities and compared
with the static load simulation. The results showed the different of
maximum von Mises stress 0.14 percent under walking and 0.03
percent under climbing stair condition and the different of equivalent
total strain 0.52 percent under walking and 0.05 percent under
climbing stair condition. The muscular forces should be evaluated
with dynamic condition to reduce the maximum von Mises stress and
equivalent total strain.
", keywords = "Dynamic loading, Static Load, Hip prosthesis, Thai
femur, Femoral bone, Finite Element Analysis.", volume = "9", number = "3", pages = "251-5", }
