Compressive Properties of a Synthetic Bone Substitute for Vertebral Cancellous Bone
Transpedicular screw fixation in spinal fractures,
degenerative changes, or deformities is a well-established procedure.
However, important rate of fixation failure due to screw bending,
loosening, or pullout are still reported particularly in weak bone stock
in osteoporosis. To overcome the problem, mechanism of failure has
to be fully investigated in vitro. Post-mortem human subjects are less
accessible and animal cadavers comprise limitations due to different
geometry and mechanical properties. Therefore, the development of a
synthetic model mimicking the realistic human vertebra is highly
demanded. A bone surrogate, composed of Polyurethane (PU) foam
analogous to cancellous bone porous structure, was tested for 3
different densities in this study. The mechanical properties were
investigated under uniaxial compression test by minimizing the end
artifacts on specimens. The results indicated that PU foam of 0.32
g.cm-3 density has comparable mechanical properties to human
cancellous bone in terms of young-s modulus and yield strength.
Therefore, the obtained information can be considered as primary
step for developing a realistic cancellous bone of human vertebral
body. Further evaluations are also recommended for other density
groups.
[1] F. Denis, "The three column spine and its significance in the
classification of acute thoracolumbar spinal injuries",Spine, vol.8(8),pp.
817-831, 1983.
[2] R.F. McLain, E. Sparling and D.R. Benson, "Early failure of shortsegment
pedicle instrumentation for thoracolumbar fractures. A
preliminary report",The Journal of bone and joint surgery, American
vol. 75(2), pp. 162, 1993.
[3] T.A. Zdeblick, D. N. Kunz, et al., "Pedicle screw pullout strength:
correlation with insertional torque",Spine, vol. 18(12), pp. 1673, 1993.
[4] M. M. Panjabi, "Biomechanical evaluation of spinal fixation devices: I.
A conceptual framework",Spine, vol.13(10), pp. 1129, 1988.
[5] B.Sandén, et al., "The significance of radiolucent zones surrounding
pedicle screws: Definition of screw loosening in spinal
instrumentation",Journal of Bone and Joint Surgery, British vol.86(3),
pp. 457,2004.
[6] S.I. Esses, B.L. Sachs, and V. Dreyzin, "Complications associated with
the technique of pedicle screw fixation. A selected survey of ABS
members",Spine, vol. 18(15), pp. 2231, 1993.
[7] C. A. Dickman, et al., "Transpedicular screw-rod fixation of the lumbar
spine: operative technique and outcome in 104 cases".Journal of
neurosurgery, vol.77(6), pp. 860-870, 1992.
[8] R. A. Lehman Jr, et al., "Straight-forward versus anatomic trajectory
technique of thoracic pedicle screw fixation: a biomechanical
analysis",Spine, vol. 28(18),pp. 2058, 2003.
[9] M.H. Krag, et al., "Morphometry of the thoracic and lumbar spine
related to transpedicular screw placement for surgical spinal
fixation",Spine, vol. 13(1), pp. 27, 1988.
[10] T. Lund, et al., "Interbody cage stabilisation in the lumbar spine:
biomechanical evaluation of cage design, posterior instrumentation and
bone density",Journal of Bone and Joint Surgery, British vol.80(2),pp.
351, 1998.
[11] J. Aerssens, et al., "Interspecies differences in bone composition,
density, and quality: potential implications for in vivo bone
research",Endocrinology, vol.139(2), pp. 663, 1998.
[12] ASTM.F 1839-01,"Standard specification for rigid polyurethane foam
for use as a standard material for testing orthopedic devices and
instruments", 2007.
[13] A.G.Au, et al., "A New Bone Surrogate Model for Testing Interbody
Device Subsidence",Spine, vol. 36(16), pp. 1289-1296, 2011.
[14] R. F. McLain, et al., "The effect of bone quality on pedicle screw
loading in axial instability: A synthetic model",Spine, vol. 22(13),pp.
1454, 1997.
[15] J. Szivek, M. Thomas, and J. Benjamin, "Technical note.
Characterization of a synthetic foam as a model for human cancellous
bone",Journal of Applied Biomaterials, vol. 4(3),pp. 269-272, 1993.
[16] J.A. Szivek, J.D. Thompson, and J.B. Benjamin, "Characterization of
three formulations of a synthetic foam as models for a range of human
cancellous bone types",Journal of Applied Biomaterials, vol. 6(2),pp.
125-128, 1995.
[17] M.S. Thompson, et al., "Compressive and shear properties of
commercially available polyurethane foams",Journal of biomechanical
engineering, vol.125,pp. 732, 2003.
[18] R.P. Heaney,"Is there a role for bone quality in fragility
fractures?"Calcified Tissue International, vol. 53,pp. 3-6, 1993.
[19] M. D. Grynpas, D. Chachra, and K. Lundon, "Bone quality in animal
models of osteoporosis",Drug development research, vol. 49(3),pp. 146-
158, 2000.
[20] G.Bell, et al., "Variations in strength of vertebrae with age and their
relation to osteoporosis",Calcified Tissue International, vol. 1(1),pp. 75-
86, 1967.
[21] E.F.Morgan, et al., "Nonlinear behavior of trabecular bone at small
strains",Journal of biomechanical engineering, vol. 123,pp. 1, 2001.
[22] K.Dupuis, "├ëtude des facteurs influen├ºant l-évaluation du comportement
mécanique de l-os par tomodensitométrie", M.Sc. Dissertation, ├ëcole de
Technologie Superieure, Unpublished.
[23] T.M. Keaveny, et al., "Systematic and random errors in compression
testing of trabecular bone",Journal of orthopaedic research, vol.
15(1),pp. 101-110, 1997.
[24] T. M. Keaveny, et al., "Trabecular bone exhibits fully linear elastic
behavior and yields at low strains",Journal of biomechanics, vol.
27(9),pp. 1127-1129, 1131-1136, 1994.
[25] ASTM.D 1621-00,"Standard Test Method for Compressive Properties
Of Rigid Cellular Plastics", 2007.
[26] P. Patel, D. Shepherd, and D. Hukins, "Compressive properties of
commercially available polyurethane foams as mechanical models for
osteoporotic human cancellous bone",BMC Musculoskeletal Disorders,
vol. 9(1),pp. 137, 2008.
[27] D.L. Kopperdahl, and T.M. Keaveny, "Yield strain behavior of
trabecular bone",Journal of biomechanics, vol. 31(7),pp. 601-608, 1998.
[28] R. M.Lin, K. H. Tsai, and G.L. Chang, "Distribution and regional
strength of trabecular bone in the porcine lumbar spine",Clinical
Biomechanics, vol. 12(5),pp. 331-336, 1997.
[29] J. Teo, et al., "Relationship between CT intensity, micro-architecture
and mechanical properties of porcine vertebral cancellous bone",Clinical
Biomechanics, vol. 21(3),pp. 235-244, 2006.
[30] B.Li, and R.M. Aspden, "Composition and mechanical properties of
cancellous bone from the femoral head of patients with osteoporosis or
osteoarthritis",Journal of Bone and Mineral Research, vol. 12(4),pp.
641-651, 1997.
[1] F. Denis, "The three column spine and its significance in the
classification of acute thoracolumbar spinal injuries",Spine, vol.8(8),pp.
817-831, 1983.
[2] R.F. McLain, E. Sparling and D.R. Benson, "Early failure of shortsegment
pedicle instrumentation for thoracolumbar fractures. A
preliminary report",The Journal of bone and joint surgery, American
vol. 75(2), pp. 162, 1993.
[3] T.A. Zdeblick, D. N. Kunz, et al., "Pedicle screw pullout strength:
correlation with insertional torque",Spine, vol. 18(12), pp. 1673, 1993.
[4] M. M. Panjabi, "Biomechanical evaluation of spinal fixation devices: I.
A conceptual framework",Spine, vol.13(10), pp. 1129, 1988.
[5] B.Sandén, et al., "The significance of radiolucent zones surrounding
pedicle screws: Definition of screw loosening in spinal
instrumentation",Journal of Bone and Joint Surgery, British vol.86(3),
pp. 457,2004.
[6] S.I. Esses, B.L. Sachs, and V. Dreyzin, "Complications associated with
the technique of pedicle screw fixation. A selected survey of ABS
members",Spine, vol. 18(15), pp. 2231, 1993.
[7] C. A. Dickman, et al., "Transpedicular screw-rod fixation of the lumbar
spine: operative technique and outcome in 104 cases".Journal of
neurosurgery, vol.77(6), pp. 860-870, 1992.
[8] R. A. Lehman Jr, et al., "Straight-forward versus anatomic trajectory
technique of thoracic pedicle screw fixation: a biomechanical
analysis",Spine, vol. 28(18),pp. 2058, 2003.
[9] M.H. Krag, et al., "Morphometry of the thoracic and lumbar spine
related to transpedicular screw placement for surgical spinal
fixation",Spine, vol. 13(1), pp. 27, 1988.
[10] T. Lund, et al., "Interbody cage stabilisation in the lumbar spine:
biomechanical evaluation of cage design, posterior instrumentation and
bone density",Journal of Bone and Joint Surgery, British vol.80(2),pp.
351, 1998.
[11] J. Aerssens, et al., "Interspecies differences in bone composition,
density, and quality: potential implications for in vivo bone
research",Endocrinology, vol.139(2), pp. 663, 1998.
[12] ASTM.F 1839-01,"Standard specification for rigid polyurethane foam
for use as a standard material for testing orthopedic devices and
instruments", 2007.
[13] A.G.Au, et al., "A New Bone Surrogate Model for Testing Interbody
Device Subsidence",Spine, vol. 36(16), pp. 1289-1296, 2011.
[14] R. F. McLain, et al., "The effect of bone quality on pedicle screw
loading in axial instability: A synthetic model",Spine, vol. 22(13),pp.
1454, 1997.
[15] J. Szivek, M. Thomas, and J. Benjamin, "Technical note.
Characterization of a synthetic foam as a model for human cancellous
bone",Journal of Applied Biomaterials, vol. 4(3),pp. 269-272, 1993.
[16] J.A. Szivek, J.D. Thompson, and J.B. Benjamin, "Characterization of
three formulations of a synthetic foam as models for a range of human
cancellous bone types",Journal of Applied Biomaterials, vol. 6(2),pp.
125-128, 1995.
[17] M.S. Thompson, et al., "Compressive and shear properties of
commercially available polyurethane foams",Journal of biomechanical
engineering, vol.125,pp. 732, 2003.
[18] R.P. Heaney,"Is there a role for bone quality in fragility
fractures?"Calcified Tissue International, vol. 53,pp. 3-6, 1993.
[19] M. D. Grynpas, D. Chachra, and K. Lundon, "Bone quality in animal
models of osteoporosis",Drug development research, vol. 49(3),pp. 146-
158, 2000.
[20] G.Bell, et al., "Variations in strength of vertebrae with age and their
relation to osteoporosis",Calcified Tissue International, vol. 1(1),pp. 75-
86, 1967.
[21] E.F.Morgan, et al., "Nonlinear behavior of trabecular bone at small
strains",Journal of biomechanical engineering, vol. 123,pp. 1, 2001.
[22] K.Dupuis, "├ëtude des facteurs influen├ºant l-évaluation du comportement
mécanique de l-os par tomodensitométrie", M.Sc. Dissertation, ├ëcole de
Technologie Superieure, Unpublished.
[23] T.M. Keaveny, et al., "Systematic and random errors in compression
testing of trabecular bone",Journal of orthopaedic research, vol.
15(1),pp. 101-110, 1997.
[24] T. M. Keaveny, et al., "Trabecular bone exhibits fully linear elastic
behavior and yields at low strains",Journal of biomechanics, vol.
27(9),pp. 1127-1129, 1131-1136, 1994.
[25] ASTM.D 1621-00,"Standard Test Method for Compressive Properties
Of Rigid Cellular Plastics", 2007.
[26] P. Patel, D. Shepherd, and D. Hukins, "Compressive properties of
commercially available polyurethane foams as mechanical models for
osteoporotic human cancellous bone",BMC Musculoskeletal Disorders,
vol. 9(1),pp. 137, 2008.
[27] D.L. Kopperdahl, and T.M. Keaveny, "Yield strain behavior of
trabecular bone",Journal of biomechanics, vol. 31(7),pp. 601-608, 1998.
[28] R. M.Lin, K. H. Tsai, and G.L. Chang, "Distribution and regional
strength of trabecular bone in the porcine lumbar spine",Clinical
Biomechanics, vol. 12(5),pp. 331-336, 1997.
[29] J. Teo, et al., "Relationship between CT intensity, micro-architecture
and mechanical properties of porcine vertebral cancellous bone",Clinical
Biomechanics, vol. 21(3),pp. 235-244, 2006.
[30] B.Li, and R.M. Aspden, "Composition and mechanical properties of
cancellous bone from the femoral head of patients with osteoporosis or
osteoarthritis",Journal of Bone and Mineral Research, vol. 12(4),pp.
641-651, 1997.
@article{"International Journal of Medical, Medicine and Health Sciences:60748", author = "H. N. Mehmanparast and J.M. Mac-Thiong. and Y. Petit", title = "Compressive Properties of a Synthetic Bone Substitute for Vertebral Cancellous Bone", abstract = "Transpedicular screw fixation in spinal fractures,
degenerative changes, or deformities is a well-established procedure.
However, important rate of fixation failure due to screw bending,
loosening, or pullout are still reported particularly in weak bone stock
in osteoporosis. To overcome the problem, mechanism of failure has
to be fully investigated in vitro. Post-mortem human subjects are less
accessible and animal cadavers comprise limitations due to different
geometry and mechanical properties. Therefore, the development of a
synthetic model mimicking the realistic human vertebra is highly
demanded. A bone surrogate, composed of Polyurethane (PU) foam
analogous to cancellous bone porous structure, was tested for 3
different densities in this study. The mechanical properties were
investigated under uniaxial compression test by minimizing the end
artifacts on specimens. The results indicated that PU foam of 0.32
g.cm-3 density has comparable mechanical properties to human
cancellous bone in terms of young-s modulus and yield strength.
Therefore, the obtained information can be considered as primary
step for developing a realistic cancellous bone of human vertebral
body. Further evaluations are also recommended for other density
groups.", keywords = "Cancellous bone, Pedicle screw, Polyurethane foam,
Synthetic bone", volume = "6", number = "5", pages = "171-4", }
