Trabecular Texture Analysis Using Fractal Metrics for Bone Fragility Assessment
The purpose of this study is the discrimination of 28
postmenopausal with osteoporotic femoral fractures from an agematched
control group of 28 women using texture analysis based on
fractals. Two pre-processing approaches are applied on radiographic
images; these techniques are compared to highlight the choice of the
pre-processing method. Furthermore, the values of the fractal
dimension are compared to those of the fractal signature in terms of
the classification of the two populations. In a second analysis, the
BMD measure at proximal femur was compared to the fractal
analysis, the latter, which is a non-invasive technique, allowed a
better discrimination; the results confirm that the fractal analysis of
texture on calcaneus radiographs is able to discriminate osteoporotic
patients with femoral fracture from controls. This discrimination was
efficient compared to that obtained by BMD alone. It was also
present in comparing subgroups with overlapping values of BMD.
[1] R. Huang, Q. Rong, X. Han, Y. Li, “The effects of cod bone gelatin on
trabecular microstructure and mechanical properties of cancellous bone,”
Acta Mechanica Solida Sinica, vol. 28, no. 1, pp. 1–10, 2015.
[2] J. Montoya, M. Giner, C. Miranda, A.Vázquez, J. R. Caeiro, D. Guede,
R. Pérez-Cano, “Microstructural trabecular bone from patients with
osteoporotic hip fracture or osteoarthritis: Its relationship with bone
mineral density and bone remodelling markers,” Maturitas, vol. 79, no.
3, pp. 299–305, 2014
[3] N. A. Valous, F. Mendoza, D. Sun, P. Allen, “Texture appearance
characterization of pre-sliced pork ham images using fractal metrics:
Fourier analysis dimension and lacunarity,” Food Research
International, vol. 42, , pp. 353–362, 2009.
[4] G. Dougherty, G.M. Henebry, “Lacunarity analysis of spatial pattern in
CT images of vertebral trabecular bone for assessing osteoporosis,”
Medical Engineering & Physics, vol. 24, pp. 129–138, 2002.
[5] K. Harrar, L. Hamami, E. Lespessailles, R. Jennane, “Piecewise Whittle
Estimator for Bone Radiograph Characterization,” Biomed. Signal
Proces. vol. 8, no. 6, pp. 657–666, 2013.
[6] D. Sanchez-Molina, J. Velazquez-Ameijide, V. Quintana, C. Arregui-
Dalmases, J.R. Crandall, D. Subit, J.R. Kerrigan, “Fractal dimension and
mechanical properties of human cortical bone,” Medical Engineering &
Physics, vol. 35, no. 5, pp. 576–582, 2013.
[7] L. Pothuaud, E. Lespessailles, R. Harba, R. Jennane, V. Royan, E.
Eynard, C.L. Benhamou, “Fractal analysis of trabecular bone texture on
radiographs: discriminant value in postmenopausal osteoporosis,”
Osteoporosis International, vol. 8, pp. 618–625, 1998.
[8] C.L. Benhamou, E. Lespessailles, G. Jacquet, R. Harba, R. Jennane, T.
Loussot, D. Tourliere, W. Ohley, “Fractal organization of trabecular
bone images on calcaneus radiographs,” Journal of Bone and Mineral
Research, vol. 9, pp. 1909–1918, 1994.
[9] N. Otsu, “A Threshold Selection Method from Gray-Level Histograms,”
IEEE Transactions on Systems, Man, and Cybernetics, vol. 9, no. 1, pp.
62-66, 1979.
[10] D. Marr, E.C. Hildreth, “Theory of edge detection,” Biological sciences,
vol. 207, no. 1167, pp. 187–190, 1980.
[11] E.C. Hildreth, “The detection of intensity changes by computer and
biological vision systems,” Computer Graphics and Image Processing,
vol. 22, pp. 1–27, 1983.
[12] B.B. Mandelbrot, The fractal geometry of nature. Freeman. new York,
1983.
[13] J. Li, Q. Du, C. Sun, “An improved box-counting method for image
fractal dimension estimation,” Pattern Recognition, vol. 42, no. 11, pp.
2460-2469, 2009.
[14] K.J. Falkoner, Techniques in Fractal Geometry. John Wiley & Sons,
Ltd. Chichester, 1997.
[15] A.P. Pentland, “Fractal-based description of natural scenes,” IEEE
Transactions on Pattern Analysis and Machine Intelligence, vol. 6, no.
6, pp. 661–74, 1984.
[16] J. Feder, 1988. Fractals Plenum. Press, New York.
[17] J.A. Lynch, D.J. Hawkes, J.C. Buckland-Wright, “Analysis of texture in
macroradiographs of osteoarthritic knees using the fractal signature,”
Physics in Medecine and Biology, vol. 36, pp. 709-722, 1996.
[18] S. Majumdar, R. S. Weinstein, R. R. Prasad, H. K. Genant, “The fractal
dimension of trabecular bone: a measure of trabecular structure,”
Calcified Tissue International, vol. 52, no. 168, 1993.
[19] E.A. Messent, J.C. Buckland-Wright, G.M. Blake, “Fractal analysis of
trabecular bone in knee osteoarthritis (OA) is a more sensitive marker of
disease status than bone mineral density (BMD),” Calcif Tissue Int. vol.
76, no. 6, pp.419-25, 2005.
[20] J.C. Buckland-Wright, J.A. Lynch, D.G. Macfarlane, “Fractal signature
analysis measures cancellous bone organization in macroradiographs of
patients with knee osteoarthritis,” Ann Rheum Dis, vol. 55, pp. 749–755,
1996.
[21] E. Lespessailles, C. Chappard, N. Bonnet, C.L. Benhamou, “Techniques
for evaluating bone microarchitecture,” Joint Bone Spine, vol. 73, pp.
254–261, 2006.
[22] W.G.M. Geraets, J.G.C. Verheij, P.F. van der Stelt, K. Horner, C. Lindh,
K. Nicopoulou-Karayianni, R. Jacobs, E.J. Harrison, J.E. Adams, H.
Devlin, “Prediction of bone mineral density with dental radiographs,”
Bone, vol. 40, pp. 1217–1221, 2007.
[23] M.E. Kersh, P.K. Zysset, D.H. Pahr, U. Wolfram, D. Larsson, M.G.
Pandy, Measurement of structural anisotropy in fe W. D. Doyle,
“Magnetization reversal in films with biaxial anisotropy,” in 1987 Proc.
INTERMAG Conf., pp. 2.2-1–2.2-6.
[24] K. Harrar, R. Jennane, “Quantification of Trabecular Bone Porosity on
X-Ray Images”, 4th International Conference on Industrial and
Intelligent Information (ICIII 2015), 18-19 May 2015, Roma, Italy.
[1] R. Huang, Q. Rong, X. Han, Y. Li, “The effects of cod bone gelatin on
trabecular microstructure and mechanical properties of cancellous bone,”
Acta Mechanica Solida Sinica, vol. 28, no. 1, pp. 1–10, 2015.
[2] J. Montoya, M. Giner, C. Miranda, A.Vázquez, J. R. Caeiro, D. Guede,
R. Pérez-Cano, “Microstructural trabecular bone from patients with
osteoporotic hip fracture or osteoarthritis: Its relationship with bone
mineral density and bone remodelling markers,” Maturitas, vol. 79, no.
3, pp. 299–305, 2014
[3] N. A. Valous, F. Mendoza, D. Sun, P. Allen, “Texture appearance
characterization of pre-sliced pork ham images using fractal metrics:
Fourier analysis dimension and lacunarity,” Food Research
International, vol. 42, , pp. 353–362, 2009.
[4] G. Dougherty, G.M. Henebry, “Lacunarity analysis of spatial pattern in
CT images of vertebral trabecular bone for assessing osteoporosis,”
Medical Engineering & Physics, vol. 24, pp. 129–138, 2002.
[5] K. Harrar, L. Hamami, E. Lespessailles, R. Jennane, “Piecewise Whittle
Estimator for Bone Radiograph Characterization,” Biomed. Signal
Proces. vol. 8, no. 6, pp. 657–666, 2013.
[6] D. Sanchez-Molina, J. Velazquez-Ameijide, V. Quintana, C. Arregui-
Dalmases, J.R. Crandall, D. Subit, J.R. Kerrigan, “Fractal dimension and
mechanical properties of human cortical bone,” Medical Engineering &
Physics, vol. 35, no. 5, pp. 576–582, 2013.
[7] L. Pothuaud, E. Lespessailles, R. Harba, R. Jennane, V. Royan, E.
Eynard, C.L. Benhamou, “Fractal analysis of trabecular bone texture on
radiographs: discriminant value in postmenopausal osteoporosis,”
Osteoporosis International, vol. 8, pp. 618–625, 1998.
[8] C.L. Benhamou, E. Lespessailles, G. Jacquet, R. Harba, R. Jennane, T.
Loussot, D. Tourliere, W. Ohley, “Fractal organization of trabecular
bone images on calcaneus radiographs,” Journal of Bone and Mineral
Research, vol. 9, pp. 1909–1918, 1994.
[9] N. Otsu, “A Threshold Selection Method from Gray-Level Histograms,”
IEEE Transactions on Systems, Man, and Cybernetics, vol. 9, no. 1, pp.
62-66, 1979.
[10] D. Marr, E.C. Hildreth, “Theory of edge detection,” Biological sciences,
vol. 207, no. 1167, pp. 187–190, 1980.
[11] E.C. Hildreth, “The detection of intensity changes by computer and
biological vision systems,” Computer Graphics and Image Processing,
vol. 22, pp. 1–27, 1983.
[12] B.B. Mandelbrot, The fractal geometry of nature. Freeman. new York,
1983.
[13] J. Li, Q. Du, C. Sun, “An improved box-counting method for image
fractal dimension estimation,” Pattern Recognition, vol. 42, no. 11, pp.
2460-2469, 2009.
[14] K.J. Falkoner, Techniques in Fractal Geometry. John Wiley & Sons,
Ltd. Chichester, 1997.
[15] A.P. Pentland, “Fractal-based description of natural scenes,” IEEE
Transactions on Pattern Analysis and Machine Intelligence, vol. 6, no.
6, pp. 661–74, 1984.
[16] J. Feder, 1988. Fractals Plenum. Press, New York.
[17] J.A. Lynch, D.J. Hawkes, J.C. Buckland-Wright, “Analysis of texture in
macroradiographs of osteoarthritic knees using the fractal signature,”
Physics in Medecine and Biology, vol. 36, pp. 709-722, 1996.
[18] S. Majumdar, R. S. Weinstein, R. R. Prasad, H. K. Genant, “The fractal
dimension of trabecular bone: a measure of trabecular structure,”
Calcified Tissue International, vol. 52, no. 168, 1993.
[19] E.A. Messent, J.C. Buckland-Wright, G.M. Blake, “Fractal analysis of
trabecular bone in knee osteoarthritis (OA) is a more sensitive marker of
disease status than bone mineral density (BMD),” Calcif Tissue Int. vol.
76, no. 6, pp.419-25, 2005.
[20] J.C. Buckland-Wright, J.A. Lynch, D.G. Macfarlane, “Fractal signature
analysis measures cancellous bone organization in macroradiographs of
patients with knee osteoarthritis,” Ann Rheum Dis, vol. 55, pp. 749–755,
1996.
[21] E. Lespessailles, C. Chappard, N. Bonnet, C.L. Benhamou, “Techniques
for evaluating bone microarchitecture,” Joint Bone Spine, vol. 73, pp.
254–261, 2006.
[22] W.G.M. Geraets, J.G.C. Verheij, P.F. van der Stelt, K. Horner, C. Lindh,
K. Nicopoulou-Karayianni, R. Jacobs, E.J. Harrison, J.E. Adams, H.
Devlin, “Prediction of bone mineral density with dental radiographs,”
Bone, vol. 40, pp. 1217–1221, 2007.
[23] M.E. Kersh, P.K. Zysset, D.H. Pahr, U. Wolfram, D. Larsson, M.G.
Pandy, Measurement of structural anisotropy in fe W. D. Doyle,
“Magnetization reversal in films with biaxial anisotropy,” in 1987 Proc.
INTERMAG Conf., pp. 2.2-1–2.2-6.
[24] K. Harrar, R. Jennane, “Quantification of Trabecular Bone Porosity on
X-Ray Images”, 4th International Conference on Industrial and
Intelligent Information (ICIII 2015), 18-19 May 2015, Roma, Italy.
@article{"International Journal of Medical, Medicine and Health Sciences:70673", author = "Khaled Harrar and Rachid Jennane", title = "Trabecular Texture Analysis Using Fractal Metrics for Bone Fragility Assessment", abstract = "The purpose of this study is the discrimination of 28
postmenopausal with osteoporotic femoral fractures from an agematched
control group of 28 women using texture analysis based on
fractals. Two pre-processing approaches are applied on radiographic
images; these techniques are compared to highlight the choice of the
pre-processing method. Furthermore, the values of the fractal
dimension are compared to those of the fractal signature in terms of
the classification of the two populations. In a second analysis, the
BMD measure at proximal femur was compared to the fractal
analysis, the latter, which is a non-invasive technique, allowed a
better discrimination; the results confirm that the fractal analysis of
texture on calcaneus radiographs is able to discriminate osteoporotic
patients with femoral fracture from controls. This discrimination was
efficient compared to that obtained by BMD alone. It was also
present in comparing subgroups with overlapping values of BMD.", keywords = "Osteoporosis, fractal dimension, fractal signature,
bone mineral density.", volume = "9", number = "9", pages = "683-6", }
