SUMMARY: Two longitudinal transmitted waves, fast and slow waves, were observed by employing a new quantitative ultrasound (QUS) method. The trabecular bone measurements generated by this method reflect three-dimensional structural information, and the new QUS parameters were able to identify vertebral fractures. INTRODUCTION: The aims were to identify new quantitative ultrasound (QUS) parameters that based on new QUS method reflecting not only bone volume but also the microstructures of trabecular bone ex vivo and to observe how much they predict fracture risk in vivo. METHODS: Ex vivo measurement: Three human femoral heads were used for the experiment. Attenuation of the slow wave, attenuation of the fast wave, speed of the slow wave, speed of the fast wave (SOFW), bone mass density of trabecular bone, and elastic modulus of the trabecular bone (EMTb) of each specimen were obtained using a new QUS method and compared with three-dimensional structural parameters measured by micro-computed tomography. In vivo measurement: Eighty-nine volunteers were enrolled, and the bone status in the distal radius was measured using a new QUS method. These parameters were compared with data evaluated by peripheral quantitative computed tomography and dual X-ray absorptiometry. RESULTS: Ex vivo measurement: SOFW and EMTb showed correlations with the parameter of trabecular anisotropy. In vivo measurement: The new QUS parameters were able to identify vertebral fractures. CONCLUSION: The newly developed QUS technique reflects the three-dimensional structure and is a promising method to evaluate fracture risk.
SUMMARY: Two longitudinal transmitted waves, fast and slow waves, were observed by employing a new quantitative ultrasound (QUS) method. The trabecular bone measurements generated by this method reflect three-dimensional structural information, and the new QUS parameters were able to identify vertebral fractures. INTRODUCTION: The aims were to identify new quantitative ultrasound (QUS) parameters that based on new QUS method reflecting not only bone volume but also the microstructures of trabecular bone ex vivo and to observe how much they predict fracture risk in vivo. METHODS: Ex vivo measurement: Three human femoral heads were used for the experiment. Attenuation of the slow wave, attenuation of the fast wave, speed of the slow wave, speed of the fast wave (SOFW), bone mass density of trabecular bone, and elastic modulus of the trabecular bone (EMTb) of each specimen were obtained using a new QUS method and compared with three-dimensional structural parameters measured by micro-computed tomography. In vivo measurement: Eighty-nine volunteers were enrolled, and the bone status in the distal radius was measured using a new QUS method. These parameters were compared with data evaluated by peripheral quantitative computed tomography and dual X-ray absorptiometry. RESULTS: Ex vivo measurement: SOFW and EMTb showed correlations with the parameter of trabecular anisotropy. In vivo measurement: The new QUS parameters were able to identify vertebral fractures. CONCLUSION: The newly developed QUS technique reflects the three-dimensional structure and is a promising method to evaluate fracture risk.
Authors: J L Hernández; F Marin; J González-Macías; A Díez-Pérez; J Vila; S Giménez; B Galán; M S Arenas; F Suárez; L Gayola; G Guillén; T Sagredo; R Belenguer; A Moron; E Arriaza Journal: Calcif Tissue Int Date: 2004-04 Impact factor: 4.333
Authors: Claus C Glüer; Richard Eastell; David M Reid; Dieter Felsenberg; Christian Roux; Reinhard Barkmann; Wolfram Timm; Tilo Blenk; Gabi Armbrecht; Alison Stewart; Jackie Clowes; Friederike E Thomasius; Sami Kolta Journal: J Bone Miner Res Date: 2004-03-01 Impact factor: 6.741
Authors: H Sai; G Iguchi; T Tobimatsu; K Takahashi; T Otani; K Horii; I Mano; I Nagai; H Iio; T Fujita; K Yoh; H Baba Journal: Osteoporos Int Date: 2010-06-01 Impact factor: 4.507