Fast pseudo-CT synthesis from MRI T1-weighted images using a patch-based approach

MRI-based bone segmentation is a challenging task because bone tissue and air both present low signal intensity on MR images, making it difficult to accurately delimit the bone boundaries. However, estimating bone from MRI images may allow decreasing patient ionization by removing the need of patient-specific CT acquisition in several applications. In this work, we propose a fast GPU-based pseudo-CT generation from a patient-specific MRI T1-weighted image using a group-wise patch-based approach and a limited MRI and CT atlas dictionary. For every voxel in the input MR image, we compute the similarity of the patch containing that voxel with the patches of all MR images in the database, which lie in a certain anatomical neighborhood. The pseudo-CT is obtained as a local weighted linear combination of the CT values of the corresponding patches. The algorithm was implemented in a GPU. The use of patch-based techniques allows a fast and accurate estimation of the pseudo-CT from MR T1-weighted images, with a similar accuracy as the patient-specific CT. The experimental normalized cross correlation reaches 0.9324±0.0048 for an atlas with 10 datasets. The high NCC values indicate how our method can accurately approximate the patient-specific CT. The GPU implementation led to a substantial decrease in computational time making the approach suitable for real applications.

[1]  Raúl San José Estépar,et al.  Multi‐atlas and label fusion approach for patient‐specific MRI based skull estimation , 2014, Magnetic resonance in medicine.

[2]  M. Robson,et al.  Clinical ultrashort echo time imaging of bone and other connective tissues , 2006, NMR in biomedicine.

[3]  Daniel Rueckert,et al.  A Probabilistic Patch-Based Label Fusion Model for Multi-Atlas Segmentation With Registration Refinement: Application to Cardiac MR Images , 2013, IEEE Transactions on Medical Imaging.

[4]  Olaf Dössel,et al.  Local SAR management by RF Shimming: a simulation study with multiple human body models , 2012, Magnetic Resonance Materials in Physics, Biology and Medicine.

[5]  Ben Glocker,et al.  Modality Propagation: Coherent Synthesis of Subject-Specific Scans with Data-Driven Regularization , 2013, MICCAI.

[6]  Colin Studholme,et al.  A Supervised Patch-Based Approach for Human Brain Labeling , 2011, IEEE Transactions on Medical Imaging.

[7]  Nassir Navab,et al.  Tissue Classification as a Potential Approach for Attenuation Correction in Whole-Body PET/MRI: Evaluation with PET/CT Data , 2009, Journal of Nuclear Medicine.

[8]  Jaakko Astola,et al.  From Local Kernel to Nonlocal Multiple-Model Image Denoising , 2009, International Journal of Computer Vision.

[9]  D. Louis Collins,et al.  Patch-based segmentation using expert priors: Application to hippocampus and ventricle segmentation , 2011, NeuroImage.

[10]  Isabelle Bloch,et al.  Segmentation of the skull in MRI volumes using deformable model and taking the partial volume effect into account , 2000, Medical Image Anal..

[11]  Gudrun Wagenknecht,et al.  MRI for attenuation correction in PET: methods and challenges , 2012, Magnetic Resonance Materials in Physics, Biology and Medicine.

[12]  Lin Shi,et al.  Segmentation of human skull in MRI using statistical shape information from CT data , 2009, Journal of magnetic resonance imaging : JMRI.

[13]  S. Vandenberghe,et al.  MRI-Based Attenuation Correction for PET/MRI Using Ultrashort Echo Time Sequences , 2010, Journal of Nuclear Medicine.

[14]  Jean-Michel Morel,et al.  A Review of Image Denoising Algorithms, with a New One , 2005, Multiscale Model. Simul..

[15]  P. Andreo Monte Carlo techniques in medical radiation physics. , 1991, Physics in medicine and biology.