Prediction of backscatter coefficient in trabecular bones using a numerical model of three-dimensional microstructure.

A model of ultrasonic backscattering for cancellous bone saturated by water is proposed. This model assumes that scattering is caused by the solid trabeculae and describes the cancellous bone as a weak scattering medium. The backscatter coefficient is related to the spatial Fourier transform of bone microarchitecture and to the density and compressibility fluctuations between the solid trabeculae and the saturating fluid. The computations of the model make use of three-dimensional numerical images of bone microarchitecture, obtained by tomographic reconstructions with a 10 microm spatial resolution. With this model, the predictions of the frequency dependence and of the magnitude of the backscatter coefficient are reasonably accurate. The theoretical predictions are compared to experimental data obtained on 19 specimens. An accuracy error of approximately 1 dB was found (difference between the averaged experimental values and theoretical predictions). One limit of the model may come from inaccurate values of trabecular bone characteristics needed for the computations (density and longitudinal velocity), which are yet to be precisely determined for human trabecular bone. However, the model is only slightly sensitive to variations of bone material properties. It was found that an accuracy error of 2.2 dB at maximum resulted from inaccurate a priori values of bone material properties. A computation of the elastic mean free path in the medium suggests that multiple scattering plays a minor role in the working frequency bandwidth (0.4-1.2 MHz). It follows from these results that a weak scattering medium model may be appropriate to describe scattering from trabecular bone.

[1]  J. Faran Sound Scattering by Solid Cylinders and Spheres , 1951 .

[2]  C R Hill,et al.  The use of angular acoustic scattering measurements to estimate structural parameters of human and animal tissues. , 1986, The Journal of the Acoustical Society of America.

[3]  R C Waag,et al.  Spectral power determinations of compressibility and density variations in model media and calf liver using ultrasound. , 1989, The Journal of the Acoustical Society of America.

[4]  S. Palmer,et al.  The interaction of ultrasound with cancellous bone. , 1991, Physics in medicine and biology.

[5]  T J Hall,et al.  Identifying acoustic scattering sources in normal renal parenchyma from the anisotropy in acoustic properties. , 1991, Ultrasound in medicine & biology.

[6]  J. Williams Ultrasonic wave propagation in cancellous and cortical bone: prediction of some experimental results by Biot's theory. , 1992, The Journal of the Acoustical Society of America.

[7]  J. Thoen,et al.  Propagation of ultrasonic pulses through trabecular bone , 1994 .

[8]  M. Insana,et al.  Modeling acoustic backscatter from kidney microstructure using an anisotropic correlation function. , 1995, The Journal of the Acoustical Society of America.

[9]  G Berger,et al.  In vitro assessment of the relationship between acoustic properties and bone mass density of the calcaneus by comparison of ultrasound parametric imaging and quantitative computed tomography. , 1997, Bone.

[10]  A. Hosokawa,et al.  Ultrasonic wave propagation in bovine cancellous bone. , 1997, The Journal of the Acoustical Society of America.

[11]  A. Hosokawa,et al.  Acoustic anisotropy in bovine cancellous bone. , 1998, The Journal of the Acoustical Society of America.

[12]  P H Nicholson,et al.  A model for ultrasonic scattering in cancellous bone based on velocity fluctuations in a binary mixture. , 1998, Physiological measurement.

[13]  B. Garra,et al.  Assessment of bone density using ultrasonic backscatter. , 1998, Ultrasound in medicine & biology.

[14]  P R White,et al.  Ultrasonic propagation in cancellous bone: a new stratified model. , 1999, Ultrasound in medicine & biology.

[15]  K. Wear Frequency dependence of ultrasonic backscatter from human trabecular bone: theory and experiment. , 1999, The Journal of the Acoustical Society of America.

[16]  P Cloetens,et al.  A synchrotron radiation microtomography system for the analysis of trabecular bone samples. , 1999, Medical physics.

[17]  M. Bouxsein,et al.  Scattering of ultrasound in cancellous bone: predictions from a theoretical model. , 2000, Journal of biomechanics.

[18]  K. Wear,et al.  The relationship between ultrasonic backscatter and bone mineral density in human calcaneus , 2000, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[19]  P. Laugier,et al.  Phase and group velocities of fast and slow compressional waves in trabecular bone. , 2000, The Journal of the Acoustical Society of America.

[20]  F. Peyrin,et al.  Frequency dependence of ultrasonic backscattering in cancellous bone: autocorrelation model and experimental results. , 2000, The Journal of the Acoustical Society of America.

[21]  K. Wear,et al.  Anisotropy of ultrasonic backscatter and attenuation from human calcaneus: implications for relative roles of absorption and scattering in determining attenuation. , 2000, The Journal of the Acoustical Society of America.

[22]  R Porcher,et al.  Ultrasonic Backscatter and Transmission Parameters at the Os Calcis in Postmenopausal Osteoporosis , 2001, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[23]  F Peyrin,et al.  Ultrasonic characterization of human cancellous bone using transmission and backscatter measurements: relationships to density and microstructure. , 2002, Bone.

[24]  M. Bouxsein,et al.  Bone marrow influences quantitative ultrasound measurements in human cancellous bone. , 2002, Ultrasound in medicine & biology.