Magnetic Resonance Image Fusion Based on Three Dimensional Band Limited Shearlet Transform_Journal of Biomedical Engineering

Authors：

 DUANChang ^1,2 , WANGXuegang ¹ , WANGHong ¹ , WANGShuai ¹

1. School of Electronic Engineering, University of Electronic Technology and Science of China, Chengdu 611731, China;
2. School of Electrical Engineering and Information, Southwest Petroleum University, Chengdu 610500, China;

Corresponding author：

DUANChang, Email: pertinax@163.com

Keywords：

magnetic resonance image fusion; three dimensional shearlet transform; band limited shearlet transform; quantitative susceptibility mapping

DOI：

10.7507/1001-5515.20150033

Video：

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More and more medical devices can capture different features of human body and form three dimensional (3D) images. In clinical applications, usually it is required to fuse multiple source images containing different and crucial information into one for the purpose of assisting medical treatment. However, traditional image fusion methods are normally designed for two dimensional (2D) images and will lead to loss of the third dimensional information if directly applied to 3D data. Therefore, a novel 3D magnetic image fusion method was proposed based on the combination of newly invented beyond wavelet transform, called 3D band limited shearlet transformand (BLST), and four groups of traditional fusion rules. The proposed method was then compared with the 2D and 3D wavelet and dual-tree complex wavelet transform fusion methods through 4 groups of human brain T2^* and quantitative susceptibility mapping (QSM) images. The experiments indicated that the performance of the method based on 3D transform was generally superior to the existing methods based on 2D transform. Taking advantage of direction representation, shearlet transform could effectively improve the performance of conventional fusion method based on 3D transform. It is well concluded, therefore, that the proposed method is the best among the methods based on 2D and 3D transforms.

Citation： DUANChang, WANGXuegang, WANGHong, WANGShuai. Magnetic Resonance Image Fusion Based on Three Dimensional Band Limited Shearlet Transform. Journal of Biomedical Engineering, 2015, 32(1): 181-186, 196. doi: 10.7507/1001-5515.20150033 Copy

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7.	NEGI P S, LABATE D. 3-D discrete shearlet transform and video processing[J]. IEEE Trans Image Process, 2012, 21(6): 2944-2954.
8.	DEHGHANI M. Wavelet-based image fusion using "A trous" algorithm[C]//Proceeding of the Map India Conference. New Delhi: 2003: 28-31.
9.	KUTYNIOK G I, DEMETRIO L. Shearlets: multiscale analysis for multivariate data[M]. Boston: Springer, 2012: 15-35.
10.	LIM W Q. The discrete shearlet transform: a new directional transform and compactly supported shearlet frames[J]. IEEE Trans Image Process, 2010, 19(5): 1166-1180.
11.	SMITH S M. Fast robust automated brain extraction[J]. Hum Brain Mapp, 2002, 17(3): 143-155.
12.	ZHANG Q, CHEN Y, WANG L. Multisensor video fusion based on spatial-temporal salience detection[J]. Signal Processing, 2013, 93(9): 2485-2499.
13.	ZHANG Q, WANG L, MA Z, et al. A novel video fusion framework using surfacelet transform[J]. Opt Commun, 2012, 285(13): 3032-3041.
14.	PETROVI V, XYDEAS C. On the effects of sensor noise in pixel-level image fusion performance[C]//Proceedings of the Third International Conference on Information Fusion. Paris: 2000: WEC3/14-19.

1. HATT C R, JAIN A K, PARTHASARATHY V, et al. MRI-3D ultrasound-X-ray image fusion with electromagnetic tracking for transendocardial therapeutic injections: in-vitro validation and in-vivo feasibility[J]. Comput Med Imaging Graph, 2013, 37(2): 162-173.
2. CLEVERT D A, HELCK A, PAPROTTKA P M, et al. Ultrasound-guided image fusion with computed tomography and magnetic resonance imaging. Clinical utility for imaging and interventional diagnostics of hepatic lesions[J]. Radiologe, 2012, 52(1): 63-69.
3. WANG S, LIU T, CHEN W, et al. Noise effects in various quantitative susceptibility mapping methods[J/OL]. (2013-06-07) [2014-02-06]. http://www.ncbi.nlm.nih.gov/pubmed/23751950.
4. LU H, ZHANG L, SERIKAWA S. Maximum local energy: an effective approach for multisensor image fusion in beyond wavelet transform domain[J]. Computers & Mathematics with Applications, 2012, 64(5): 996-1003.
5. EASLEY G R, LABATE D, COLONNA F. Shearlet-based total variation diffusion for denoising[J]. IEEE Trans Image Process, 2009, 18(2): 260-268.
6. YI S, LABATE D, EASLEY G R, et al. A shearlet approach to edge analysis and detection[J]. IEEE Trans Image Process, 2009, 18(5): 929-941.
7. NEGI P S, LABATE D. 3-D discrete shearlet transform and video processing[J]. IEEE Trans Image Process, 2012, 21(6): 2944-2954.
8. DEHGHANI M. Wavelet-based image fusion using "A trous" algorithm[C]//Proceeding of the Map India Conference. New Delhi: 2003: 28-31.
9. KUTYNIOK G I, DEMETRIO L. Shearlets: multiscale analysis for multivariate data[M]. Boston: Springer, 2012: 15-35.
10. LIM W Q. The discrete shearlet transform: a new directional transform and compactly supported shearlet frames[J]. IEEE Trans Image Process, 2010, 19(5): 1166-1180.
11. SMITH S M. Fast robust automated brain extraction[J]. Hum Brain Mapp, 2002, 17(3): 143-155.
12. ZHANG Q, CHEN Y, WANG L. Multisensor video fusion based on spatial-temporal salience detection[J]. Signal Processing, 2013, 93(9): 2485-2499.
13. ZHANG Q, WANG L, MA Z, et al. A novel video fusion framework using surfacelet transform[J]. Opt Commun, 2012, 285(13): 3032-3041.
14. PETROVI V, XYDEAS C. On the effects of sensor noise in pixel-level image fusion performance[C]//Proceedings of the Third International Conference on Information Fusion. Paris: 2000: WEC3/14-19.

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