Fractal analysis of radiographs: assessment of trabecular bone structure and prediction of elastic modulus and strength.

The purpose of this study was to determine whether fractal dimension of radiographs provide measures of trabecular bone structure which correlate with bone mineral density (BMD) and bone biomechanics, and whether these relationships depend on the technique used to calculate the fractal dimension. Eighty seven cubic specimen of human trabecular bone were obtained from the vertebrae and femur. The cubes were radiographed along all three orientations--superior-inferior (SI), medial-lateral (ML), and anterior-posterior (AP), digitized, corrected for background variations, and fractal based techniques were applied to quantify trabecular structure. Three different techniques namely, semivariance, surface area, and power spectral methods were used. The specimens were tested in compression along three orientations and the Young's modulus (YM) was determined. Compressive strength was measured along the SI direction. Quantitative computed tomography was used to measure trabecular BMD. High-resolution magnetic-resonance images were used to obtain three-dimensional measures of trabecular architecture such as the apparent bone volume fraction, trabecular thickness, spacing, and number. The measures of trabecular structure computed in the different directions showed significant differences (p<0.05). The correlation between BMD, YM, strength, and the fractal dimension were direction and technique dependent. The trends of variation of the fractal dimension with BMD and biomechanical properties also depended on the technique and the range of resolutions over which the data was analyzed. The fractal dimension showed varying trends with bone mineral density changes, and these trends also depended on the range of frequencies over which the fractal dimension was measured. For example, using the power spectral method the fractal dimension increased with BMD when computed over a lower range of spatial frequencies and decreased for higher ranges. However, for the surface area technique the fractal dimension increased with increasing BMD. Fractal measures showed better correlation with trabecular spacing and number, compared to trabecular thickness. In a multivariate regression model inclusion of some of the fractal measures in addition to BMD improved the prediction of strength and elastic modulus. Thus, fractal based texture analysis of radiographs are technique dependent, but may be used to quantify trabecular structure and have a potentially valuable impact in the study of osteoporosis.

[1]  J C Netelenbos,et al.  An analysis of bone structure in patients with hip fracture. , 1987, Bone and mineral.

[2]  X Ouyang,et al.  Texture analysis of direct magnification radiographs of vertebral specimens: correlation with bone mineral density and biomechanical properties. , 1997, Academic radiology.

[3]  S. Goldstein,et al.  The direct examination of three‐dimensional bone architecture in vitro by computed tomography , 1989, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[4]  M. Giger,et al.  Multifractal radiographic analysis of osteoporosis. , 1994, Medical physics.

[5]  B. L. Cox,et al.  Fractal Surfaces: Measurement and Applications in the Earth Sciences , 1993 .

[6]  R. Harba,et al.  Fractal organization of trabecular bone images on calcaneus radiographs , 1994, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[7]  A. Law,et al.  Detecting osteoporosis using dental radiographs: a comparison of four methods. , 1996, Journal of the American Dental Association.

[8]  S. Majumdar,et al.  Evaluation of technical factors affecting the quantification of trabecular bone structure using magnetic resonance imaging. , 1995, Bone.

[9]  M. Yaffe,et al.  Characterisation of mammographic parenchymal pattern by fractal dimension. , 1990, Physics in medicine and biology.

[10]  J S Arnold,et al.  Amount and quality of trabecular bone in osteoporotic vertebral fractures. , 1973, Clinics in endocrinology and metabolism.

[11]  W. Hayes,et al.  Prediction of vertebral body compressive fracture using quantitative computed tomography. , 1985, The Journal of bone and joint surgery. American volume.

[12]  Raj Acharya,et al.  Analysis of bone X-rays using morphological fractals , 1993, IEEE Trans. Medical Imaging.

[13]  E. Gelsema,et al.  Unraveling the Role of Structure and Density in Determining Vertebral Bone Strength , 1997, Calcified Tissue International.

[14]  S. Majumdar,et al.  Impact of spatial resolution on the prediction of trabecular architecture parameters. , 1998, Bone.

[15]  C. Simmons,et al.  Trabecular bone morphology from micro‐magnetic resonance imaging , 1996, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[16]  S. Majumdar,et al.  Morphometric texture analysis of spinal trabecular bone structure assessed using orthogonal radiographic projections. , 1998, Medical physics.

[17]  S. Ott,et al.  Should women get screening bone mass measurements? , 1986, Annals of internal medicine.

[18]  Y H Chang,et al.  Fractal Analysis of Trabecular Patterns in Projection Radiographs: An Assessment , 1994, Investigative radiology.

[19]  J. Rho,et al.  The characterization of broadband ultrasound attenuation and fractal analysis by biomechanical properties. , 1997, Bone.

[20]  The radiographic trabecular bone pattern during menopause. , 1993, Bone.

[21]  N. Fazzalari,et al.  FRACTAL DIMENSION AND ARCHITECTURE OF TRABECULAR BONE , 1996, The Journal of pathology.

[22]  R. L. Webber,et al.  Fractal dimension from radiographs of peridental alveolar bone. A possible diagnostic indicator of osteoporosis. , 1992, Oral surgery, oral medicine, and oral pathology.

[23]  S. Majumdar,et al.  Fractal geometry and vertebral compression fractures , 1994, Journal of Bone and Mineral Research.

[24]  R. Mann,et al.  Characterization of microstructural anisotropy in orthotropic materials using a second rank tensor , 1984 .