J.P. Roux

Do ultrasound measurements on the os calcis reflect more the bone microarchitecture than the bone mass?: A two-dimensional histomorphometric study

Few studies have analyzed the relationship between ultrasound measurements (US) and corresponding histomorphometric parameters of the calcaneus. To address this question we have compared US and histomorphometric parameters in 17 whole human os calcis from amputation or necropsy. Speed of sound (SOS), broadband ultrasound attenuation (BUA), and bone mineral density (BMD) were measured on the whole foot at the calcaneal site using an Achilles device and a DPX-L densitometer (Lunar). The os calcis was dissected and a 1-cm-wide transcortical parallelepiped extracted with a biopsy needle, focused on the center of the measured area. Histomorphometry was performed on undecalcified biopsies. Structural and connectivity parameters were measured on 7-microns-thick sections with both automatic (Biocom) and semiautomatic analyzers (Ibas 1, Kontron). We found that all ultrasonic and densitometric parameters reflected the true amount of bone and were correlated with only some of the parameters reflecting bone microarchitecture. From stepwise regression analysis, we found that 68%, 67%, 72%, and 74% of the variance of SOS, BUA stiffness, and BMD, respectively, were explained significantly by trabeculae thickness only. Ultrasonic measurements appear to reflect bone quantity rather than bone microarchitecture. The current conclusion is fairly negative with respect to the ability of ultrasound to assess structural parameters, but our limited sample size did not give enough power to our study to reach statistically significant correlations. In addition, the calcaneus is anisotropic and the ultrasound interaction in bone is a three-dimensional phenomenon. So, a three-dimensional study rather than a two-dimensional one should be performed.

High-resolution computed tomography for architectural characterization of human lumbar cancellous bone: relationships with histomorphometry and biomechanics.

Abstract: The aim of the present study on human vertebral cancellous bone was to validate structural parameters measured with high-resolution (150 μm) computed tomography (HRCT) by referring to histomorphometry and to try to predict mechanical properties of bone using HRCT. Two adjacent vertical cores were removed from the central part of human L2 vertebral body taken after necropsy in 22 subjects aged 47–95 years (10 women, 12 men; mean age 79 ± 14 years). The right core was used for structural analysis performed by both HRCT and histomorphometry. Two cancellous bone specimens were extracted from the left core: a cube for HRCT and a compression test, and a cylinder for a shear test. Significant correlations were found between HRCT and histomorphometric measurements (BV/TV, trabecular thickness, separation and number, and node-strut analysis), but with higher values for most of the tomographic parameters (BV/TV and trabecular thickness determined by HRCT were overestimated by a factor 3.5 and 2.5 respectively, as compared with histomorphometry). The maximum compressive strength and Young’s modulus were highly correlated (ρ= 0.99, p<0.0005). Significant correlation was obtained between bone mineral density (determined using dual-energy X-ray absorptiometry) and the maximum compressive strength (ρ= 0.64, p= 0.002). In addition the maximum compressive strength and architectural parameters determined by HRCT or histomorphometry showed significant correlations (e.g., for HRCT, BV/TV: ρu2009=u20090.88, p<0.0005, N.Nd/TV: ρ= 0.73, p<0.001). The shear strength was significantly correlated with BV/TV (ρ= 0.62, p= 0.002), Tb.Sp (ρ=−0.58, p= 0.004) and TSL (ρ= 0.55, p= 0.006) measured by HRCT. In conclusion, an HRCT system with 150 μm resolution is not sufficient to predict the true values of the structural parameters measured by histomorphometry, although high correlations were found between the two methods. However, we showed that a resolution of 150 μm allowed us to predict the mechanical properties of human cancellous bone. In vivo peripheral systems with such a resolution should be of interest and would deliver an acceptable radiation dose to the patient.

Fractal Analysis of Bone Texture on Os Calcis Radiographs Compared with Trabecular Microarchitecture Analyzed by Histomorphometry

Abstract. Microarchitecture of trabecular bone is an important determinant of bone fragility; to date, its evaluation requires bone biopsy with histomorphometry analysis. Methods of noninvasive characterization of trabecular bone microarchitecture are in development and we have developed and validated a bone texture analysis applied to bone radiographs and based on fractal geometry. The aim of our study was to compare this fractal analysis of trabecular bone texture on radiographs to the trabecular microarchitecture analyzed by bone histomorphometry on os calcis biopsies. Thirty eight ossa calcis from 19 human cadavers were studied. Fractal analysis of the trabecular bone of os calcis radiographs was performed by the maximum likelihood estimator following the fractional brownian motion model. The ossa calcis were dissected, then transcortical biopsy cores focused on the fractal analysis region of interest were obtained. Structural and connectivity parameters were measured with both automatic and semiautomatic analyzers. We have found a significant relationship between the fractal Hmean parameter and structural histomorphometric indices; the best correlation was found with trabecular separation (r =−0.55; P= 0.0004). Based on a stepwise regression analysis, trabecular spacing and trabeculae number together would explain 38% of the variance of the fractal parameter. Although the relationship with connectivity indices was poor, our fractal analysis of os calcis trabecular bone texture on radiographs seemed to partially reflect the trabecular bone microarchitecture.

Mechanical Properties of Ewe Vertebral Cancellous Bone Compared With Histomorphometry and High-Resolution Computed Tomography Parameters

The goal of the present study was to determine if a high-resolution computed tomography (HRCT) system with 150 microns resolution was sufficient to predict mechanical properties in ewe lumbar vertebrae. To answer this question, we used a triangular comparison between: HRCT; biomechanics (compression and shear tests); and histomorphometry, which was the reference method for the measurements of morphometric parameters. Two dissected lumbar vertebrae (L-4 and L-5) from 32 ewes were used. Both compressive and shear properties correlated significantly with amount of bone and structural parameters evaluated by histomorphometry (bone volume/tissue volume, trabecular thickness, trabecular separation), but no significant correlation was found with the trabecular number. With our shear test involving the trabecular architecture itself more significant correlations were found with the node-strut analysis parameters than from the compressive test. Significant correlations were also found between HRCT and histological parameters (bone volume/tissue volume, bone surface/bone volume, trabecular separation, trabecular number, total strut length, number of nodes, and number of termini). Correlations between HRCT structural parameters and mechanical properties on L-4 were of the same magnitude as the correlations between the histomorphometric structural parameters and mechanical results on L-5 but with the remarkable advantage the HRCT is a noninvasive method. In spite of the resolution (150 microns) of our HRCT system, which entailed mainly an enlargement of the thinnest trabeculae or their loss during the segmentation process, we obtained coherent relationships between mechanical and tomographic parameters. The thinnest trabeculae probably had little effect on the mechanical strength. Also, this type of resolution allows us to consider the possibility of perfecting an in vivo HRCT system. However, physical density and bone mineral density correlated much better with strength than either classical histomorphometric or tomographic parameters. The current conclusion is fairly negative with respect to the ability of HRCT to assess mechanical properties nondestructively as compared with dual-energy X-ray absorptiometry. But, the noninvasive nature of the imaging modality and the capacity for three-dimensional imaging at arbitrary orientation make HRCT a promising tool in the quantitative assessment of cancellous architecture.

Automatic-interactive measurement of resorption cavities in transiliac bone biopsies and correlation with deoxypyridinoline

Measuring bone resorption accurately by histomorphometry of bone biopsies is a challenge. Several techniques have been proposed including the measurement of eroded surfaces and resorption depth, but they have not been compared between themselves nor with biochemical assessment of bone resorption. In addition, there is a need for a rapid method that could be used more routinely. We describe here an automatic interactive method using a color analyzer (Visiolab, BIOCOM, France) with a specific software for the evaluation of erosion depth, eroded volume, eroded surface, osteoclast number, and surface. Thirty transiliac undecalcified bone biopsies stained with Goldners trichrome were used in this study, taken from subjects suffering from osteoporosis or primary hyperparathyroidism. At the time of the biopsy a 2 h fasting morning urine sample was collected for measurement by HPLC of total deoxypyridinoline, the most sensitive marker of bone resorption. There was a highly significant correlation between maximum erosion depth measured directly and the one calculated according to the count of eroded lamellae (E. F. Eriksen, et al. Metab Bone Dis Relat Res 5:243-252; 1984) (r = 0.76; p = 0.0001). A significant correlation was found between urinary deoxypyridinoline and eroded volume/bone volume in cancellous and endocortical bone measured with the automatic interactive technique (r = 0.48; p = 0.007). In contrast, other histological indexes of bone resorption did not correlate with urinary deoxypyridinoline. The volume of resorption cavities appears to be the most valid index of bone resorption rate as it was correlated with the urinary excretion of total deoxypyridinoline.(ABSTRACT TRUNCATED AT 250 WORDS)