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| Main Authors: | , , , |
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| Format: | Preprint |
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2025
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2502.08824 |
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| _version_ | 1866929713154359296 |
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| author | Dia, Amadou S. Renaud, Guillaume Chappard, Christine Grimal, Quentin |
| author_facet | Dia, Amadou S. Renaud, Guillaume Chappard, Christine Grimal, Quentin |
| contents | Intracortical US imaging extends B-mode imaging into bone using a dedicated image reconstruction algorithm that corrects for refraction at the bone-soft tissue interfaces. It has shown promising results in a few healthy, predominantly young adults, providing anatomical images of the cortex (periosteal and endosteal surfaces) along with estimations of US wave speed. However, its reliability in older or osteoporotic bones remains uncertain. In this study, we critically assessed the performance of intracortical US imaging ex vivo in bones with various microstructural patterns, including bones exhibiting signs of unbalanced intracortical remodeling. We analyzed factors influencing US image quality, particularly endosteal surface reconstruction, as well as the accuracy of wave speed estimation and its relationship with porosity. We imaged 20 regions of interest from the femoral diaphysis of five elderly donors using a 2.5 MHz US transducer. The reconstructed US images were compared to site-matched high-resolution micro-CT (HR-muCT) images. In samples with moderate porosity, the endosteal surface was accurately identified, and thickness estimates from US and HR-muCT differed by less than 10%. In highly remodeled bones with increased porosity, the reconstructed endosteal surface appeared less bright and was located above the cortex region containing resorption cavities. We observed a decrease in US wave speed with increasing cortical porosity suggesting that the method could discriminate between bones with low porosity (less than 5%) and those with moderate to high porosity (greater than ~10%). This study paves the way for the application of US imaging in diagnosing cortical bone health, particularly for detecting increased cortical porosity and reduced cortical thickness. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2502_08824 |
| institution | arXiv |
| publishDate | 2025 |
| record_format | arxiv |
| spellingShingle | Ultrasound imaging of cortical bone: cortex geometry and measurement of porosity based on wave speed for bone remodeling estimation Dia, Amadou S. Renaud, Guillaume Chappard, Christine Grimal, Quentin Medical Physics Intracortical US imaging extends B-mode imaging into bone using a dedicated image reconstruction algorithm that corrects for refraction at the bone-soft tissue interfaces. It has shown promising results in a few healthy, predominantly young adults, providing anatomical images of the cortex (periosteal and endosteal surfaces) along with estimations of US wave speed. However, its reliability in older or osteoporotic bones remains uncertain. In this study, we critically assessed the performance of intracortical US imaging ex vivo in bones with various microstructural patterns, including bones exhibiting signs of unbalanced intracortical remodeling. We analyzed factors influencing US image quality, particularly endosteal surface reconstruction, as well as the accuracy of wave speed estimation and its relationship with porosity. We imaged 20 regions of interest from the femoral diaphysis of five elderly donors using a 2.5 MHz US transducer. The reconstructed US images were compared to site-matched high-resolution micro-CT (HR-muCT) images. In samples with moderate porosity, the endosteal surface was accurately identified, and thickness estimates from US and HR-muCT differed by less than 10%. In highly remodeled bones with increased porosity, the reconstructed endosteal surface appeared less bright and was located above the cortex region containing resorption cavities. We observed a decrease in US wave speed with increasing cortical porosity suggesting that the method could discriminate between bones with low porosity (less than 5%) and those with moderate to high porosity (greater than ~10%). This study paves the way for the application of US imaging in diagnosing cortical bone health, particularly for detecting increased cortical porosity and reduced cortical thickness. |
| title | Ultrasound imaging of cortical bone: cortex geometry and measurement of porosity based on wave speed for bone remodeling estimation |
| topic | Medical Physics |
| url | https://arxiv.org/abs/2502.08824 |