期刊
APPLIED SCIENCES-BASEL
卷 12, 期 10, 页码 -出版社
MDPI
DOI: 10.3390/app12105283
关键词
medical beamforming; phase aberration correction; medical tissue characterization; pulse-echo ultrasound; medical signal and image processing
类别
资金
- German Ministry of Science and Education (BMBF KMUi grant) [13GW0234]
- German Ministry of Economic Affairs and Energy (BMWi) [03THW08H01]
- Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) [INST 335/555-1]
- Charite-Universitatsmedizin Berlin
- Open Access Publication Fund of Charite-Universitatsmedizin Berlin
- German Research Foundation (DFG)
The study aims to improve multi-focus imaging technique by correcting phase aberration caused by bone geometry, leading to more accurate and precise measurements of cortical thickness and sound velocity.
Delay-and-sum (DAS) beamforming of backscattered echoes is used for conventional ultrasound imaging. Although DAS beamforming is well suited for imaging in soft tissues, refraction, scattering, and absorption, porous mineralized tissues cause phase aberrations of reflected echoes and subsequent image degradation. The recently developed refraction corrected multi-focus technique uses subsequent focusing of waves at variable depths, the tracking of travel times of waves reflected from outer and inner cortical bone interfaces, the estimation of the shift needed to focus from one interface to another to determine cortical thickness (Ct.Th), and the speed of sound propagating in a radial bone direction (Ct.nu(11)). The method was validated previously in silico and ex vivo on plate shaped samples. The aim of this study was to correct phase aberration caused by bone geometry (i.e., curvature and tilt with respect to the transducer array) and intracortical pores for the multi-focus approach. The phase aberration correction methods are based on time delay estimation via bone geometry differences to flat bone plates and via the autocorrelation and cross correlation of the reflected ultrasound waves from the endosteal bone interface. We evaluate the multi-focus approach by incorporating the phase aberration correction methods by numerical simulation and one experiment on a human tibia bone, and analyze the precision and accuracy of measuring Ct.Th and Ct.nu(11). Site-matched reference values of the cortical thickness of the human tibia bone were obtained from high-resolution peripheral computed tomography. The phase aberration correction methods resulted in a more precise (coefficient of variation of 5.7%) and accurate (root mean square error of 6.3%) estimation of Ct.Th, and a more precise (9.8%) and accurate (3.4%) Ct.nu(11) estimation, than without any phase aberration correction. The developed multi-focus method including phase aberration corrections provides local estimations of both cortical thickness and sound velocity and is proposed as a biomarker of cortical bone quality with high clinical potential for the prevention of osteoporotic fractures.
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