Generalized MRI reconstruction including elastic physiological motion and coil sensitivity encoding

Odille, Freddy; Ĉındea, Nicolae; Mandry, Damien; Pasquier, Claude; Vuissoz, Pierre‐André; Felblinger, Jacques

doi:10.1002/mrm.21520

Cited by 48 publications

(69 citation statements)

References 23 publications

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“…NMI is a well-known concept that is often used to image coregistration for both intramodality and intermodality images [8][9][10]. Recently, Jiang and colleagues [11,12] introduced the use of NMI as a reference image with which to evaluate image quality. We assumed that the NMI-based technique would work successfully for three-dimensional (3D) volume images.…”

Section: Semiconductor Detectors Have In Recent Times Emerged As a Nementioning

confidence: 99%

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Evaluation of delineation of image details in semiconductor PET utilizing the normalized mutual information technique

Kubo

Hirata

Matsuzaki

et al. 2014

Nuclear Medicine Communications

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Delineation of image details in semiconductor PET Kubo et al. 2 Objective PET using semiconductor detectors provides high-quality images of the human brain because of its high spatial resolution. To quantitatively evaluate the delineation of image details in clinical PET images, we used normalized mutual information (NMI) to quantify the similarity with images obtained through MRI. NMI is used to evaluate image quality by determining similarity with a reference image. The aim of this study was to evaluate quantitatively the delineation of image details provided by semiconductor PET. Materials and methodsTo quantitatively evaluate anatomical delineation in clinical PET images, MRI scans of patients were used as T1-weighted images. ResultsNMIsemic ranged from 1.22 to 1.29, whereas NMIconve ranged from 1.13 to 1.18 (P<0.05). Furthermore, all the NMI values of the semiconductor PET were higher than those of the conventional scintillator PET. ConclusionUtilizing NMI, we quantitatively evaluated the delineation of image details in clinical PET images. The results reveal that semiconductor PET has superior anatomical delineation 3 and physical performance compared with conventional scintillator PET. This improved delineation of image details makes semiconductor PET promising for clinical applications.

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Section: Semiconductor Detectors Have In Recent Times Emerged As a Nementioning

confidence: 99%

“…In addition, it was already demonstrated that NMI values calculated between the reference image and acquired images can be used to evaluate image quality [11,12,20].…”

Section: Use Of Normalized Mutual Informationmentioning

confidence: 99%

Evaluation of delineation of image details in semiconductor PET utilizing the normalized mutual information technique

Kubo

Hirata

Matsuzaki

et al. 2014

Nuclear Medicine Communications

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“…This work can be extended to multiple coil acquisition (8), by combination with the general parallel imaging method proposed in (9). The resulting framework involves modeling the acquisition pipeline as shown in Fig.…”

Section: Generalized Reconstruction Framework For Arbitrary Motion Comentioning

confidence: 99%

“…This article starts by presenting a reconstruction framework also descibed in (8), generalizing methods in (7) and (9), in order to correct for artifacts caused by elastic motion (nonrigid or affine) in the context of multiple coil acquisition. Practical implementation requires knowledge of complete displacement fields at each acquisition time.…”

Section: Introductionmentioning

confidence: 99%

Generalized Reconstruction by Inversion of Coupled Systems (GRICS) applied to free‐breathing MRI

Odille

Vuissoz

Marie

et al. 2008

Magnetic Resonance in Med

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“…Then in (19), elastic spatial transformation operator T ti was incorporated in the equation of generalized SENSE:…”

Section: Gricsmentioning

confidence: 99%

Motion compensated generalized reconstruction for free‐breathing dynamic contrast‐enhanced MRI

Filipovic

Vuissoz

Codreanu

et al. 2010

Magnetic Resonance in Med

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The analysis of abdominal and thoracic dynamic contrastenhanced MRI is often impaired by artifacts and misregistration caused by physiological motion. Breath-hold is too short to cover long acquisitions. A novel multipurpose reconstruction technique, entitled dynamic contrast-enhanced generalized reconstruction by inversion of coupled systems, is presented. It performs respiratory motion compensation in terms of both motion artefact correction and registration. It comprises motion modeling and contrast-change modeling. The method feeds on physiological signals and x-f space properties of dynamic series to invert a coupled system of linear equations. The unknowns solved for represent the parameters for a linear nonrigid motion model and the parameters for a linear contrast-change model based on B-splines. Performance is demonstrated on myocardial perfusion imaging, on six simulated data sets and six clinical exams. The main purpose consists in removing motion-induced errors from time-intensity curves, thus improving curve analysis and postprocessing in general. This method alleviates postprocessing difficulties in dynamic contrast-enhanced MRI and opens new possibilities for dynamic contrast-enhanced MRI analysis. Magn Reson Med 65:812-822,

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Generalized MRI reconstruction including elastic physiological motion and coil sensitivity encoding

Cited by 48 publications

References 23 publications

Evaluation of delineation of image details in semiconductor PET utilizing the normalized mutual information technique

Evaluation of delineation of image details in semiconductor PET utilizing the normalized mutual information technique

Generalized Reconstruction by Inversion of Coupled Systems (GRICS) applied to free‐breathing MRI

Motion compensated generalized reconstruction for free‐breathing dynamic contrast‐enhanced MRI

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