Dr. Md Murad Hossain Profile

Dr. Md Murad Hossain

at Univ of North Carolina at Chapel Hill

SPIE Involvement:

Author

Area of Expertise:

Elastography , Ultrasound imaging , Motion Tracking , Medical Image Processing

Websites:

Personal Website | Company Website

Publications (3)

Proceedings Article | 15 March 2019 Paper

On the feasibility of quantifying mechanical anisotropy in transversely isotropic elastic materials using acoustic radiation force (ARF)-induced displacements

Md Murad Hossain, Caterina Gallippi

Proceedings Volume 10955, 109550D (2019) https://doi.org/10.1117/12.2511765

KEYWORDS: Point spread functions, Signal attenuation, Anisotropy, Finite element methods, Acoustics, Kidney, Acousto-optics, In vivo imaging, Muscle dysfunction

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Many soft tissues, including skeletal muscle and kidney, can be modeled astransversely isotropic (TI) materials defined by an axis of symmetry (AoS) perpendicular to a plane of isotropy. In such materials, mechanical properties differ along versus across the AoS. The degree of mechanical anisotropy in TI materials was previously assessed as the ratio of peak displacement (PD) achieved when the long axis of an asymmetric acoustic radiation force (ARF) excitation point spread function (PSF) was aligned along versus across the material’s AoS, but the measurement was qualitative. The objectives of this work were: (i) to derive an empirical model describing the relationship between the PD ratio and shear moduli ratio; (ii) to investigate the impact of ARF excitation PSF aberration due to speed of sound (c), attenuation (α), and dimension of ARF excitation PSF on the empirical model; and (iii) to estimate mechanical anisotropy in excised pig biceps femoris muscles and in vivo pig kidney using the empirical model. The empirical model was derived by simulating ARF Impulse (ARFI) imaging of ‘train’ TI materials (shear moduli ratios varying from 1.0 to 10 in steps of 0.75) and validated on ‘test’ materials (shear moduli ratios varying from 1.25 to 8.75 in steps of 0.75) using finite element method (FEM) models. Siemens VF73 transducer parameter with lateral F/1.5 was simulated for ARFI imaging. The speed of sound and attenuation was set to1540 ms^-1 and 0.5 dB/cm/MHZ, respectively for train materials and was set to1540 or 1620 ms^-1 and 0.5 or 1.0 dB/cm/MHZ, respectively for test materials. To find the impact of ARF excitation PSF dimension, a matrix array was simulated and the lateral and elevational F/# was set to 2.0 and 3.4, respectively for train materials and was set to 2.0 or 3.0 and 3.4 or 5.1, respectively for test materials. Ultrasound tracking of FEM displacements was performed in Field II with an SNR of 30 dB. The average absolute percent error in predicting shear moduli ratio of all ‘test’ materials was 1.6%. The empirical model was not impacted by the deviation from expected attenuation, sound speed, and ARF excitation PSF dimension. Shear moduli ratios derived using the empirical model matched those derived from shear wave elasticity imaging (SWEI) in pig muscle (model: 4.44 ± 0.47 and SWEI: 4.38 ± 0.27), renal medulla (model: 1.31 ± 0.07 and SWEI: 1.32 ± 0.04) and renal cortex (model: 2.0 ± 0.19 and SWEI: 1.99 ± 0.06). These results suggest the feasibility of using the PD empirical model to quantify mechanical anisotropy in biological tissues.

Proceedings Article | 21 March 2014 Paper

Three dimensional level set based semiautomatic segmentation of atherosclerotic carotid artery wall volume using 3D ultrasound imaging

Md. Murad Hossain, Khalid AlMuhanna, Limin Zhao, Brajesh Lal, Siddhartha Sikdar

Proceedings Volume 9034, 90344B (2014) https://doi.org/10.1117/12.2043975

KEYWORDS: Image segmentation, Laser induced breakdown spectroscopy, Arteries, 3D image processing, Ultrasonography, Image processing algorithms and systems, Independent component analysis, Simulation of CCA and DLA aggregates, Algorithm development, Reconstruction algorithms

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Proceedings Article | 13 March 2013 Paper

Semiautomatic segmentation of atherosclerotic carotid artery lumen using 3D ultrasound imaging

Md. Murad Hossain, Khalid AlMuhanna , Limin Zhao, Brajesh Lal, Siddhartha Sikdar

Proceedings Volume 8669, 86694A (2013) https://doi.org/10.1117/12.2007030

KEYWORDS: Image segmentation, Arteries, Laser induced breakdown spectroscopy, 3D image processing, Ultrasonography, Independent component analysis, Simulation of CCA and DLA aggregates, Image processing algorithms and systems, Visualization, Speckle

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Carotid atherosclerosis is a major cause of stroke. Imaging and monitoring plaque progression in 3D can better classify disease severity and potentially identify plaque vulnerability to rupture. In this study we propose to validate a new semiautomatic carotid lumen segmentation algorithm based on 3D ultrasound imaging that is designed to work in the presence of poor boundary contrast and complex 3D lumen geometries. Our algorithm uses a distance regularized level set evolution with a novel initialization and stopping criteria to localize the lumen-intima boundary (LIB). The external energy used in the level set method is a combination of region-based and edge-based energy. Initialization of LIB segmentation is first done in the longitudinal slice where the geometry of the carotid bifurcation is best visualized and then reconstructed in the cross sectional slice to guide the 3D initialization. Manual initialization of the contour is done only on the starting slice of the common carotid, bifurcation, and internal and external carotid arteries. Initialization of the other slices is done by eroding segmentation of previous slices. The user also initializes the boundary points for every slice. A combination of changes in the modified Hausdorff distance (MHD) between contours at successive iterations and a stopping boundary formed from initial boundary points is used as a stopping criterion to avoid over- or under-segmentation. The proposed algorithm is evaluated against manually segmented boundaries by calculating dice similarity coefficient (DSC), HD and MHD in the common carotid (C), carotid bulb (B) and internal carotid (I) regions to get a better understanding of accuracy?. Results from five subjects with <50% carotid stenosis showed good agreement with manual segmentation; between the semiautomatic algorithm and manuals: DSC (C: 86.49± 9.38, B: 82.21±8.49, I: 78.96±7.55), MHD (C: 3.79 ± 1.64, B: 4.09 ± 1.71, I: 4.12 ± 2.01), HD (C: 8.07±2.59, B: 10.09±3.95, I: 11.28±5.06); and inter observers: DSC (C: 88.31±5, B: 82.45±7.57, I: 82.03±8.83), MHD (C: 3.77±2.09, B: 4.32±1.88, I: 4.56±2.24), HD (C: 7.61±2.67, B: 10.22±4.30, I: 10.63±4.94). This method is a first step towards achieving full 3D characterization of plaque progression, and is currently being evaluated in a longitudinal study of asymptomatic carotid stenosis.

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