Reproducibility of 3D micro-CT gray-scale and structural dimension data in longitudinal studies

Repeated micro-CT scanning of a number of iliac crest biopsies enabled us to quantitate the variation in CT image gray-scale and spatial geometry due to variables such as specimen orientation, projection magnification, voxel size and slight differences in x-ray photon energy in each of the different scans. Using the micro-CT scanner on beamline X2B at the Brookhaven National Laboratory's National Synchrotron Light Source, we rescanned several iliac crest bone biopsy specimens, and a test phantom made of calcium hydroxyapatite, at repeated scanning sessions and evaluated the reproducibility of the spatial geometry and gray-scale haracteristics of the specimens. This scanner consists of a Bragg diffiaction source of monochromatic x-rays, a computer controlled high precision specimen rotation and translation stage assembly, and a fluorescent crystal and CCD array system for imaging the specimen at each of the angles of view around its axis of rotation during the scanning sequence. The 3-D micro-CT images consisted of up to 1024x24002, 4 μm, cubic voxels, each with 16-bit gray-scale. We also reconstructed the images at 16,32 and 48 μm voxel resolution. Partial volume effects at the surface of the bone were diminished by 'eroding' the surface voxels in the 4 μm images, but significantly changed the outcome at greater voxel size. Reproducibility of the mineral content of bone, at mean bone opacity value, was ± 28.8 mg/cm3, i.e., 2.56%, in a 4 μm cubic voxel at the 95% confidence level.

[1]  Graham R. Davis Image quality in x-ray microtomography , 1997, Optics & Photonics.

[2]  P Cloetens,et al.  A synchrotron radiation microtomography system for the analysis of trabecular bone samples. , 1999, Medical physics.

[3]  S M Jorgensen,et al.  Long-term risedronate treatment normalizes mineralization and continues to preserve trabecular architecture: sequential triple biopsy studies with micro-computed tomography. , 2006, Bone.

[4]  L. Feldkamp,et al.  Practical cone-beam algorithm , 1984 .

[5]  U. Bonse,et al.  3D computed X-ray tomography of human cancellous bone at 8 microns spatial and 10(-4) energy resolution. , 1994, Bone and mineral.

[6]  G M Owen,et al.  A theoretical analysis of the accuracy of single-energy CT bone-mineral measurements , 1988, Physics in medicine and biology.

[7]  E. Ritman,et al.  The effect of risedronate on bone mineralization as measured by micro-computed tomography with synchrotron radiation: correlation to histomorphometric indices of turnover. , 2005, Bone.

[8]  L. Grodzins,et al.  Optimum energies for x-ray transmission tomography of small samples. Applications of synchrotron radiation to computerized tomography I , 1983 .

[9]  B. Flannery,et al.  Three-Dimensional X-ray Microtomography , 1987, Science.

[10]  M. Hahn,et al.  High Spatial Resolution Imaging of Bone Mineral Using Computed Microtomography: Comparison with Microradiography and Undecalcified Histologic Sections , 1993, Investigative radiology.

[11]  Paul J. Thomas,et al.  Synchrotron-based micro-CT of in-situ biological basic functional units and their integration , 1997, Optics & Photonics.