21.7.4.1 Medical Applications, Trabecular Bone, Spongy Bone

Chapter Contents (Back)
Trabecular Bone. Bones.

Korstjens, C.M., Spruijt, R.J., Geraets, W.G.M., Mosekilde, L., van der Stelt, P.F.,
Reliability of an image analysis system for quantifying the radiographic trabecular pattern,
MedImg(16), No. 2, April 1997, pp. 230-234.
IEEE Top Reference. 0205
BibRef

Gomberg, B.R., Saha, P.K., Song, H.K.[Hee Kwon], Hwang, S.N., Wehrli, F.W.,
Topological analysis of trabecular bone MR images,
MedImg(19), No. 3, March 2000, pp. 166-174.
IEEE Top Reference. 0110
BibRef

Saha, P.K.[Punam K.], Gomberg, B.R.[Bryon R.], Wehrli, F.W.[Felix W.],
Three-dimensional digital topological characterization of cancellous bone architecture,
IJIST(11), No. 1, 2000, pp. 81-90. 0005
BibRef

Saha, P.K.[Punam Kumar], Wehrli, F.W.[Felix W.],
A robust method for measuring trabecular bone orientation anisotropy at in vivo resolution using tensor scale,
PR(37), No. 9, September 2004, pp. 1935-1944.
Elsevier DOI 0407
BibRef

Saha, P.K., Wehrli, F.W.,
Measurement of Trabecular Bone Thickness in the Limited Resolution Regime of In Vivo MRI by Fuzzy Distance Transform,
MedImg(23), No. 1, January 2004, pp. 53-62.
IEEE Abstract. 0403
BibRef

Saha, P.K., Xu, Y., Duan, H., Heiner, A., Liang, G.,
Volumetric Topological Analysis: A Novel Approach for Trabecular Bone Classification on the Continuum Between Plates and Rods,
MedImg(29), No. 11, November 2010, pp. 1821-1838.
IEEE DOI 1011
BibRef

Hwang, S.N.[Scott N.], Wehrli, F.W.[Felix W.],
Estimating voxel volume fractions of trabecular bone on the basis of magnetic resonance images acquired in vivo,
IJIST(10), No. 2, 1999, pp. 186-198. BibRef 9900

Veenland, J.F., Grashuis, J.L., Weinans, H., Ding, M., Vrooman, H.A.,
Suitability of texture features to assess changes in trabecular bone architecture,
PRL(23), No. 4, February 2002, pp. 395-403.
Elsevier DOI 0202
BibRef

Elmoutaouakkil, A., Peyrin, F., Elkafi, J., Laval-Jeantet, A.M.,
Segmentation of cancellous bone from high-resolution computed tomography images: influence on trabecular bone measurements,
MedImg(21), No. 4, April 2002, pp. 354-362.
IEEE Top Reference. 0206
BibRef

Vasilic, B., Wehrli, F.W.,
A novel local thresholding algorithm for trabecular bone volume fraction mapping in the limited spatial resolution regime of in vivo MRI,
MedImg(24), No. 12, December 2005, pp. 1574-1585.
IEEE DOI 0601
BibRef

Fritscher, K., Grunerbl, A., Hanni, M., Suhm, N., Hengg, C., Schubert, R.,
Trabecular Bone Analysis in CT and X-Ray Images of the Proximal Femur for the Assessment of Local Bone Quality,
MedImg(28), No. 10, October 2009, pp. 1560-1575.
IEEE DOI 0910
BibRef

Zhou, B.[Bin], Zhang, Z.D.[Zhen-Dong], Wang, J.[Ji], Yu, Y.E.[Y. Eric], Liu, X.S.[X. Sherry], Nishiyama, K.K.[Kyle K.], Rubin, M.R.[Mishaela R.], Shane, E.[Elizabeth], Bilezikian, J.P.[John P.], Guo, X.E.[X. Edward],
In vivo precision of digital topological skeletonization based individual trabecula segmentation (ITS) analysis of trabecular microstructure at the distal radius and tibia by HR-pQCT,
PRL(76), No. 1, 2016, pp. 83-89.
Elsevier DOI 1605
Individual trabecula segmentation (ITS) BibRef

Humbert, L., Martelli, Y., Fonollŕ, R., Steghöfer, M., di Gregorio, S., Malouf, J., Romera, J., Barquero, L.M.D.R.,
3D-DXA: Assessing the Femoral Shape, the Trabecular Macrostructure and the Cortex in 3D from DXA images,
MedImg(36), No. 1, January 2017, pp. 27-39.
IEEE DOI 1701
Bones BibRef

Oulhaj, H., Rziza, M., Amine, A., Toumi, H., Lespessailles, E., El Hassouni, M., Jennane, R.,
Anisotropic Discrete Dual-Tree Wavelet Transform for Improved Classification of Trabecular Bone,
MedImg(36), No. 10, October 2017, pp. 2077-2086.
IEEE DOI 1710
Brownian motion, Gaussian distribution, bone, computerised tomography, discrete wavelet transforms, diseases, BibRef

López Picazo, M., Magallón Baro, A., del Río Barquero, L.M., di Gregorio, S., Martelli, Y., Romera, J., Steghöfer, M., González Ballester, M.A., Humbert, L.,
3-D Subject-Specific Shape and Density Estimation of the Lumbar Spine From a Single Anteroposterior DXA Image Including Assessment of Cortical and Trabecular Bone,
MedImg(37), No. 12, December 2018, pp. 2651-2662.
IEEE DOI 1812
Bones, Shape, Spine, Osteoporosis, Solid modeling, Training, Bone mineral density, cortical thickness, statistical model BibRef

Li, Y., Sixou, B., Peyrin, F.,
Nonconvex Mixed TV/Cahn-Hilliard Functional for Super-Resolution/Segmentation of 3D Trabecular Bone Images,
JMIV(61), No. 4, May 2019, pp. 504-514.
Springer DOI 1904
BibRef


Comin, C.H., Viana, M.P., Henning, B., dos Reis, S.F., dos Santos, T.M.P., Lopes, R.T., da Fontoura Costa, L.[Luciano],
Characterizing the Trabecular Bone Tissue of the Toco Toucan Bill,
ICIP18(1228-1232)
IEEE DOI 1809
Bones, Bone tissue, Shape, Image segmentation, Surface morphology, Pipelines, Toco toucan, bill coordinates, trabecular bone density BibRef

Chowdhury, M.[Manish], Klintström, B.[Benjamin], Klintström, E.[Eva], Smedby, Ö.[Örjan], Moreno, R.[Rodrigo],
Granulometry-Based Trabecular Bone Segmentation,
SCIA17(II: 100-108).
Springer DOI 1706
BibRef

Klintström, B.[Benjamin], Klintström, E.[Eva], Smedby, Ö.[Örjan], Moreno, R.[Rodrigo],
Feature Space Clustering for Trabecular Bone Segmentation,
SCIA17(II: 65-75).
Springer DOI 1706
BibRef

Chen, C.[Cheng], Jin, D.[Dakai], Zhang, X.L.[Xiao-Liu], Levy, S.M.[Steven M.], Saha, P.K.[Punam K.],
Segmentation of Trabecular Bone for In Vivo CT Imaging Using a Novel Approach of Computing Spatial Variation in Bone and Marrow Intensities,
MCBMIIA16(III: 3-15).
Springer DOI 1704
BibRef

Slim, I., Akkari, H., Abdallah, A.B., Bhouri, I., Lespessailles, E., Jennane, R., Bedoui, M.H.,
Trabecular Bone Radiograph Characterization Using Lacunarity Measurement,
CGiV16(196-199)
IEEE DOI 1608
bone BibRef

Martin, B.L., Bottema, M.J.,
Textons for 3D Binary Data with Applications to Classifying Cancellous Bone,
DICTA15(1-6)
IEEE DOI 1603
bone BibRef

Darabi, A., Baroud, G.,
Assessment of trabecular bone structure using fuzzy distance transform based on Min-Max operations,
IPRIA15(1-6)
IEEE DOI 1603
biomedical MRI BibRef

Chen, C.[Cheng], Jin, D.[Dakai], Saha, P.K.[Punam K.],
Fuzzy Skeletonization Improves the Performance of Characterizing Trabecular Bone Micro-architecture,
ISVC15(I: 14-24).
Springer DOI 1601
BibRef

Chen, C.[Cheng], Jin, D.[Dakai], Liu, Y.[Yinxiao], Wehrli, F.W.[Felix W.], Chang, G.[Gregory], Snyder, P.J.[Peter J.], Regatte, R.R.[Ravinder R.], Saha, P.K.[Punam K.],
Volumetric Topological Analysis on In Vivo Trabecular Bone Magnetic Resonance Imaging,
ISVC14(I: 501-510).
Springer DOI 1501
BibRef

El Hassani, A.S.E.[Ahmed Salmi El_Boumnini], El Hassouni, M.[Mohammed], Jennane, R.[Rachid], Rziza, M.[Mohammed], Lespessailles, E.[Eric],
Texture Analysis for Trabecular Bone X-Ray Images Using Anisotropic Morlet Wavelet and Rényi Entropy,
ICISP12(290-297).
Springer DOI 1208
BibRef

Houam, L.[Lotfi], Hafiane, A.[Adel], Boukrouche, A.[Abdelhani], Lespessailles, E.[Eric], Jennane, R.[Rachid],
Texture characterization using local binary pattern and wavelets. Application to bone radiographs,
IPTA12(371-376)
IEEE DOI 1503
BibRef
Earlier: A1, A2, A5, A3, A4:
Trabecular Bone Anisotropy Characterization Using 1D Local Binary Patterns,
ACIVS10(I: 105-113).
Springer DOI 1012
bone BibRef

Dias, J.[Jerome], Valette, S.[Sebastien], Dardenne, J.[Julien], Prost, R.[Remy], Peyrin, F.[Francoise],
Graph-based multi-scale analysis of plates and rods in human trabecular bone,
ICIP10(2289-2292).
IEEE DOI 1009
BibRef

Yap, D.W.H.[Dennis Wen-Hsiang], Chen, Y.[Ying], Leow, W.K.[Wee Kheng], Howe, T.S.[Tet Sen], Png, M.A.[Meng Ai],
Detecting femur fractures by texture analysis of trabeculae,
ICPR04(III: 730-733).
IEEE DOI 0409
BibRef

Accardo, A., Candido, G., Toffanin, R., Vittur, F., Jellus, V.,
Quantification of Trabecular Bone Structure from Three-dimensional MR Images,
ICIP01(II: 304-306).
IEEE DOI 0108
BibRef

Bezy-Wendling, J., Bruno, A., Reuze, P.,
MRI Texture Analysis Applied to Trabecular Bone: An Experimental Study,
CVRMed95(XX-YY) BibRef 9500

Chapter on Medical Applications, CAT, MRI, Ultrasound, Heart Models, Brain Models continues in
Medical Applications, Femur Analysis, Bone .


Last update:Mar 16, 2024 at 20:36:19