The effects of frequency-dependent attenuation and dispersion on sound speed measurements: applications in human trabecular bone

Sound speed may be measured by comparing the transit time of a broadband ultrasonic pulse transmitted through an object with that transmitted through a reference water path. If the speed of sound in water and the thickness of the sample are known, the speed of sound in the object may be computed. To measure the transit time differential, a marker such as a zero-crossing, may be used. A sound speed difference between the object and water shifts all markers backward or forward. Frequency-dependent attenuation and dispersion may alter the spectral characteristics of the waveform, thereby distorting the locations of markers and introducing variations in sound-speed estimates. Theory is derived to correct for this distortion for Gaussian pulses propagating through linearly attenuating, weakly dispersive media. The theory is validated using numerical analysis, measurements on a tissue mimicking phantom, and on 24 human calcaneus samples in vitro. Variations in soft tissue-like media are generally not exceptionally large for most applications but can be substantial, particularly for high bandwidth pulses propagating through media with high attenuation coefficients. At 500 kHz, variations in velocity estimates in bone can be very substantial, on the order of 40 to 50 m/s because of the high attenuation coefficient of bone. In trabecular bone, the effects of frequency-dependent attenuation are considerable, and the effects of dispersion are negligible.

[1]  M. Ragozzino Analysis of the error in measurement of ultrasound speed in tissue due to waveform deformation by frequency-dependent attenuation. , 1981, Ultrasonics.

[2]  G Van der Perre,et al.  A comparison of time-domain and frequency-domain approaches to ultrasonic velocity measurement in trabecular bone. , 1996, Physics in medicine and biology.

[3]  S. Cummings,et al.  Bone density at various sites for prediction of hip fractures , 1993, The Lancet.

[4]  J.J. Kaufman,et al.  Ultrasonic assessment of human and bovine trabecular bone: a comparison study , 1996, IEEE Transactions on Biomedical Engineering.

[5]  G. Breart,et al.  Ultrasonographic heel measurements to predict hip fracture in elderly women: the EPIDOS prospective study , 1996, The Lancet.

[6]  Sidney Lees,et al.  Distribution of sonic plesio‐velocity in a compact bone sample , 1979 .

[7]  J F Greenleaf,et al.  Measurement and use of acoustic nonlinearity and sound speed to estimate composition of excised livers. , 1986, Ultrasound in medicine & biology.

[8]  P. Laugier,et al.  Ultrasound images of the os calcis: a new method of assessment of bone status , 1993 .

[9]  J.J. Kaufman,et al.  Diffraction effects in insertion mode estimation of ultrasonic group velocity , 1995, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[10]  J. Currey,et al.  Prediction of mechanical properties of the human calcaneus by broadband ultrasonic attenuation. , 1996, Bone.

[11]  W. O’Brien,et al.  Ultrasonic attenuation and velocity properties in rat liver as a function of fat concentration: a study at 100 MHz using a scanning laser acoustic microscope. , 1985, The Journal of the Acoustical Society of America.

[12]  J. Taylor,et al.  Quantitative Heel Ultrasound in 3180 Women Between 45 and 75 Years of Age: Compliance, Normal Ranges and Relationship to Fracture History , 1998, Osteoporosis International.

[13]  P. Laugier,et al.  Velocity dispersion of acoustic waves in cancellous bone , 1998, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.

[14]  R. Strelitzki On the measurement of the velocity of ultrasound in the os calcis using short pulses , 1996 .

[15]  P. Wells Biomedical Ultrasonics , 1977 .

[16]  E. Jaynes,et al.  Kramers–Kronig relationship between ultrasonic attenuation and phase velocity , 1981 .

[17]  J. Wladimiroff,et al.  In vitro measurements of sound velocity in human fetal brain tissue. , 1975, Ultrasound in medicine & biology.

[18]  R. Lakes,et al.  Slow compressional wave propagation in wet human and bovine cortical bone. , 1983, Science.

[19]  C F Njeh,et al.  Orthogonal relationships between ultrasonic velocity and material properties of bovine cancellous bone. , 1996, Medical engineering & physics.

[20]  C F Njeh,et al.  The effect of cortical endplates on ultrasound velocity through the calcaneus: an in vitro study. , 1997, The British journal of radiology.

[21]  C. M. Langton,et al.  Prediction of Human Femoral Bone Strength Using Ultrasound Velocity and BMD: An In Vitro Study , 1997, Osteoporosis International.

[22]  F. Duck Physical properties of tissue , 1990 .

[23]  J. Zagzebski,et al.  Comparison of speed of sound and ultrasound attenuation in the os calcis to bone density of the radius, femur and lumbar spine. , 1989, Clinical physics and physiological measurement : an official journal of the Hospital Physicists' Association, Deutsche Gesellschaft fur Medizinische Physik and the European Federation of Organisations for Medical Physics.

[24]  W D O'Brien,et al.  Correlation of tissue constituents with the acoustic properties of skin and wound. , 1990, Ultrasound in medicine & biology.

[25]  P Rüegsegger,et al.  Do quantitative ultrasound measurements reflect structure independently of density in human vertebral cancellous bone? , 1998, Bone.

[26]  C. Turner,et al.  Calcaneal ultrasonic measurements discriminate hip fracture independently of bone mass , 1995, Osteoporosis International.

[27]  P A Narayana,et al.  A Closed Form Method for the Measurement of Attenuation in Nonlinearly Dispersive Media , 1983, Ultrasonic imaging.

[28]  D H Blankenhorn,et al.  Velocity and attenuation of sound in arterial tissues. , 1982, The Journal of the Acoustical Society of America.

[29]  J W Erdman,et al.  Ultrasonic propagation properties (@ 100 MHz) in excessively fatty rat liver. , 1988, The Journal of the Acoustical Society of America.

[30]  H. Trębacz,et al.  Ultrasound Velocity and Attenuation in Cancellous Bone Samples from Lumbar Vertebra and Calcaneus , 1999, Osteoporosis International.

[31]  S. Lees,et al.  Sonic velocity and attenuation in wet compact cow femur for the frequency range 5 to 100 MHz. , 1992, Ultrasound in medicine & biology.

[32]  C. R. Hill,et al.  Acoustic properties of normal and cancerous human liver-I. Dependence on pathological condition. , 1981, Ultrasound in medicine & biology.

[33]  F Duboeuf,et al.  Ultrasound discriminates patients with hip fracture equally well as dual energy X‐ray absorptiometry and independently of bone mineral density , 1995, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[34]  Ralph W. Barnes,et al.  Ultrasonic attenuation and propagation speed in normal human brain , 1981 .

[35]  R. Lakes,et al.  Ultrasonic wave propagation and attenuation in wet bone. , 1986, Journal of biomedical engineering.

[36]  K. W. Cattermole The Fourier Transform and its Applications , 1965 .

[37]  J. G. Miller,et al.  Interlaboratory comparison of ultrasonic backscatter, attenuation, and speed measurements. , 1999, Journal of ultrasound in medicine : official journal of the American Institute of Ultrasound in Medicine.

[38]  F. Dunn,et al.  Comprehensive compilation of empirical ultrasonic properties of mammalian tissues. , 1978, The Journal of the Acoustical Society of America.

[39]  C C Glüer,et al.  Osteoporosis: association of recent fractures with quantitative US findings. , 1996, Radiology.

[40]  J. A. Evans,et al.  Dependence of the velocity and attenuation of ultrasound in bone on the mineral content. , 1991, Physics in medicine and biology.

[41]  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.

[42]  J. Cauley,et al.  Broadband ultrasound attenuation predicts fractures strongly and independently of densitometry in older women. A prospective study. Study of Osteoporotic Fractures Research Group. , 1997, Archives of Internal Medicine.