Correlation of ultrasound phase with physical skull properties.

Noninvasive treatment of brain disorders using focused ultrasound (US) requires a reliable model for predicting the distortion of the field due to the skull using physical parameters obtained in vivo. Previous studies indicate that control of US phase alone is sufficient for producing a focus through the skull using a phased US array. The present study concentrates on identifying methods to estimate phase distortion. This will be critical for the future clinical use of noninvasive brain therapy. Ten ex vivo human calvaria were examined. Each sample was imaged in water using computerized tomography (CT). The information was used to determine the inner and outer skull surfaces, thickness as a function of position, and internal structure. Phase measurement over a series of points was obtained by placing a skull fragment between a transducer and a receiver with the skull normal to the transducer. Correlation was found between the skull thickness and the US phase shift. A linear fit of the data follows that predicted by a homogeneous skull when average speed of sound 2650 m/s was used. Large variance (SD = 60 degrees, mean = 50 degrees ) indicates the additional role of internal bone speed and density fluctuations. In an attempt to reduce the variance, the skull was first studied as a three-layer structure. Next, density-dependent bone speed fluctuation was introduced to both the single-layer and three-layer models. It was determined that adjustment of the mean propagation speeds using density improves the overall phase prediction. Results demonstrate that it is possible to use thickness and density information from CT images to predict the US phase distortion induced by the skull accurately enough for therapeutic aberration correction. In addition, the measurements provide coefficients for phase dependence on skull thickness and density that can be used in clinical treatments.

[1]  G E Trahey,et al.  Phased array ultrasound imaging through planar tissue layers. , 1986, Ultrasound in medicine & biology.

[2]  Gregory T. Clement,et al.  A hemisphere array for non-invasive ultrasound brain therapy and surgery. , 2000, Physics in medicine and biology.

[3]  J. Barger,et al.  Acoustical properties of the human skull. , 1978, The Journal of the Acoustical Society of America.

[4]  P. P. Lele,et al.  An analysis of lesion development in the brain and in plastics by high-intensity focused ultrasound at low-megahertz frequencies. , 1972, The Journal of the Acoustical Society of America.

[5]  K Hynynen,et al.  The potential of transskull ultrasound therapy and surgery using the maximum available skull surface area. , 1999, The Journal of the Acoustical Society of America.

[6]  F A Jolesz,et al.  Demonstration of potential noninvasive ultrasound brain therapy through an intact skull. , 1998, Ultrasound in medicine & biology.

[7]  W J FRY,et al.  Production of focal destructive lesions in the central nervous system with ultrasound. , 1954, Journal of neurosurgery.

[8]  K. Hynynen,et al.  Focusing of therapeutic ultrasound through a human skull: a numerical study. , 1998, The Journal of the Acoustical Society of America.

[9]  K. Wear Temperature dependence of ultrasonic attenuation in human calcaneus. , 2000, Ultrasound in medicine & biology.

[10]  K. Watkin,et al.  A new predictive ultrasound modality of cranial bone thickness , 1997, 1997 IEEE Ultrasonics Symposium Proceedings. An International Symposium (Cat. No.97CH36118).

[11]  F. Fry,et al.  Transkull focal lesions in cat brain produced by ultrasound. , 1981, Journal of neurosurgery.

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

[13]  Gregory T. Clement,et al.  The role of internal reflection in transskull phase distortion. , 2001, Ultrasonics.

[14]  Gregory T. Clement,et al.  Investigation of a large-area phased array for focused ultrasound surgery through the skull. , 2000, Physics in medicine and biology.

[15]  F. Fry,et al.  Further studies of the transkull transmission of an intense focused ultrasonic beam: lesion production at 500 kHz. , 1980, Ultrasound in medicine & biology.

[16]  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.

[17]  J.-L. Thomas,et al.  Ultrasonic beam focusing through tissue inhomogeneities with a time reversal mirror: application to transskull therapy , 1996, IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control.