Your search keyword '"Malo, M.K.H."' showing total 2 results

1. Ultrasound backscatter measurements of intact human proximal femurs—Relationships of ultrasound parameters with tissue structure and mineral density.

Author

Malo, M.K.H., Töyräs, J., Karjalainen, J.P., Isaksson, H., Riekkinen, O., and Jurvelin, J.S.

Subjects

*BACKSCATTERING, *FEMUR, *BONE density, *BONE mechanics, *CANCELLOUS bone, *DIAGNOSTIC ultrasonic imaging, *DIAGNOSIS

Abstract

Abstract: Ultrasound reflection and backscatter parameters are related to the mechanical and structural properties of bone in vitro. However, the potential of ultrasound reflection and backscatter measurements has not been tested with intact human proximal femurs ex vivo. We hypothesize that ultrasound backscatter can be measured from intact femurs and that the measured backscattered signal is associated with cadaver age, bone mineral density (BMD) and trabecular bone microstructure. In this study, human femoral bones of 16 male cadavers (47.0±16.1years, range: 21–77years) were investigated using pulse-echo ultrasound measurements at the femoral neck in the antero-posterior direction and at the trochanter major in the anteroposterior and lateromedial directions. Recently introduced ultrasound backscatter parameters, independent of cortical thickness, e.g., time slope of apparent integrated backscatter (TSAB) and mean of the backscatter difference technique (MBD) were obtained and compared with the structural properties of trabecular bone samples, extracted from the locations of ultrasound measurements. Moreover, more conventional backscatter parameters, e.g., apparent integrated backscatter (AIB) and frequency slope of apparent integrated backscatter (FSAB) were analyzed. Bone mineral density of the intact femurs was evaluated using dual energy X-ray absorptiometry (DXA). AIB and MDB measured from the femoral neck correlated significantly (p <0.01) with the neck BMD (R2 =0.44 and 0.45), cadaver age (R2 =0.61 and 0.41) and several structural parameters, e.g., bone volume fraction (R2 =0.33 and 0.39, p <0.05 and p <0.01), respectively. To conclude, ultrasound backscatter parameters, measured from intact proximal femurs, are significantly related (p <0.05) to structural properties and mineral density of trabecular bone. [Copyright &y& Elsevier]

Published

2014

2. Tissue viscoelasticity is related to tissue composition but may not fully predict the apparent-level viscoelasticity in human trabecular bone – An experimental and finite element study.

Author

Ojanen, X., Tanska, P., Malo, M.K.H., Isaksson, H., Väänänen, S.P., Koistinen, A.P., Grassi, L., Magnusson, S.P., Ribel-Madsen, S.M., Korhonen, R.K., Jurvelin, J.S., and Töyräs, J.

Subjects

*CANCELLOUS bone, *BONE mechanics, *VISCOELASTICITY, *TISSUE mechanics, *ACOUSTIC microscopy, *COLLAGEN

Abstract

Trabecular bone is viscoelastic under dynamic loading. However, it is unclear how tissue viscoelasticity controls viscoelasticity at the apparent-level. In this study, viscoelasticity of cylindrical human trabecular bone samples ( n = 11, male, age 18–78 years) from 11 proximal femurs were characterized using dynamic and stress-relaxation testing at the apparent-level and with creep nanoindentation at the tissue-level. In addition, bone tissue elasticity was determined using scanning acoustic microscope (SAM). Tissue composition and collagen crosslinks were assessed using Raman micro-spectroscopy and high performance liquid chromatography (HPLC), respectively. Values of material parameters were obtained from finite element (FE) models by optimizing tissue-level creep and apparent-level stress-relaxation to experimental nanoindentation and unconfined compression testing values, respectively, utilizing the second order Prony series to depict viscoelasticity. FE simulations showed that tissue-level equilibrium elastic modulus ( E eq ) increased with increasing crystallinity ( r = 0.730, p = .011) while at the apparent-level it increased with increasing hydroxylysyl pyridinoline content ( r = 0.718, p = .019). In addition, the normalized shear modulus g 1 ( r = −0.780, p = .005) decreased with increasing collagen ratio (amide III/CH 2 ) at the tissue-level, but increased ( r = 0.696, p = .025) with increasing collagen ratio at the apparent-level. No significant relations were found between the measured or simulated viscoelastic parameters at the tissue- and apparent-levels nor were the parameters related to tissue elasticity determined with SAM. However, only E eq , g 2 and relaxation time τ 1 from simulated viscoelastic values were statistically different between tissue- and apparent-levels ( p < .01). These findings indicate that bone tissue viscoelasticity is affected by tissue composition but may not fully predict the macroscale viscoelasticity in human trabecular bone. [ABSTRACT FROM AUTHOR]

Published

2017