Analysis of different image-registration algorithms for Fourier decomposition MRI in functional lung imaging

Ljimani, Alexandra; Hojdis, Malte; Stabinska, Julia; Valentin, Birte; Frenken, Miriam; Appel, Elisabeth; Antoch, Gerald; Wittsack, Hans‐Jörg

doi:10.1177/0284185120944902

Cited by 7 publications

(14 citation statements)

References 30 publications

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“…For this reason, the phase‐cycled FD method suffers from a lower scan efficiency compared with the conventional FD method. Please note that for successful applications of FD MRI, multiple respiratory and cardiac cycles are needed to be captured with sufficient temporal resolution, 52 and commonly, images in the order of hundreds are acquired for FD‐MRI applications 1,39 . Here, the total number of acquisitions prescribed was within the range of values previously used for conventional acquisition studies, 53 and no additional time was required to accommodate additional phase cycle increments.…”

Section: Discussionmentioning

confidence: 99%

“…In conventional FD MRI, 2D bSSFP sequence with single RF phase increment (hereafter referred to as single‐phase acquisition) constitutes the basis of the time‐resolved acquisitions to assess the signal variations arising from respiratory and cardiac cycles 5 . Conventionally, a total of

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images are acquired with a frame rate of 3–4 images per second during free breathing, 14 and registered using a nonrigid registration software 39 to align lung structures, thus enabling the observation of regional parenchymal density changes. Thereafter, temporal Fourier transform is used to spectrally analyze and obtain the signal changes corresponding to respiratory and cardiac frequencies, resulting in ventilation‐weighted and perfusion‐weighted maps.…”

Section: Methodsmentioning

confidence: 99%

“…Please note that for successful applications of FD MRI, multiple respiratory and cardiac cycles are needed to be captured with sufficient temporal resolution, 52 and commonly, images in the order of hundreds are acquired for FD-MRI applications. 1,39 Here, the total number of acquisitions prescribed was within the range of values previously used for conventional acquisition studies, 53 and no additional time was required to accommodate additional phase cycle increments. Another limitation of the current implementation originates from the phase cycle increments used in this study.…”

Section: T a B L Ementioning

confidence: 99%

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Phase‐cycled balanced SSFP imaging for non‐contrast‐enhanced functional lung imaging

Ilicak

Ozdemir

Schad

et al. 2022

Magnetic Resonance in Med

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Purpose To introduce phase‐cycled balanced SSFP (bSSFP) acquisition as an alternative in Fourier decomposition MRI for improved robustness against field inhomogeneities. Methods Series 2D dynamic lung images were acquired in 5 healthy volunteers at 1.5 T and 3 T using bSSFP sequence with multiple RF phase increments and compared with conventional single RF phase increment acquisitions. The approach was evaluated based on functional map homogeneity analysis, while ensuring image and functional map quality by means of SNR and contrast‐to‐noise ratio analyses. Results At both field strengths, functional maps obtained with phase‐cycled acquisitions displayed improved robustness against local signal losses compared with single‐phase acquisitions. The coefficient of variation (mean ± SD, across volunteers) measured in the ventilation maps resulted in 29.7 ± 2.6 at 1.5 T and 37.5 ± 3.1 at 3 T for phase‐cycled acquisitions, compared with 39.9 ± 5.2 at 1.5 T and 49.5 ± 3.7 at 3 T for single‐phase acquisitions, indicating a significant improvement (p<0.05$$ p<0.05 $$) in ventilation map homogeneity. Conclusions Phase‐cycled bSSFP acquisitions improve robustness against field inhomogeneity artifacts and significantly improve ventilation map homogeneity at both field strengths. As such, phase‐cycled bSSFP may serve as a robust alternative in lung function assessments.

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Section: Discussionmentioning

confidence: 99%

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Section: Methodsmentioning

confidence: 99%

Section: T a B L Ementioning

confidence: 99%

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Phase‐cycled balanced SSFP imaging for non‐contrast‐enhanced functional lung imaging

Ilicak

Ozdemir

Schad

et al. 2022

Magnetic Resonance in Med

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“…Likewise, different approaches have been proposed based on traditional functional optimization that shows stable quality results. 35 Deep learning registration offers an alternative with low computational cost during the inference stage once the registration model is trained. 36,37 Deep learning in MRI also has been attempted to estimate quantitative tissue parameters using quantitative susceptibility mapping (QMS) and MRI fingerprinting to achieve more standardized biomarkers.…”

Section: Ai In Functional Image Reconstructionmentioning

confidence: 99%

Artificial intelligence in functional imaging of the lung

Estépar

2021

The British Journal of Radiology

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Artificial intelligence (AI) is transforming the way we perform advanced imaging. From high-resolution image reconstruction to predicting functional response from clinically acquired data, AI is promising to revolutionize clinical evaluation of lung performance, pushing the boundary in pulmonary functional imaging for patients suffering from respiratory conditions. In this review, we overview the current developments and expound on some of the encouraging new frontiers. We focus on the recent advances in machine learning and deep learning that enable reconstructing images, quantitating, and predicting functional responses of the lung. Finally, we shed light on the potential opportunities and challenges ahead in adopting AI for functional lung imaging in clinical settings.

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“…Image registration demands up to several hours to enable pixel-wise analysis of acquired images from a single subject, even for 2D techniques. 11 The current state-of-the-art registration algorithms are implemented in Advanced Normalization Tools (ANTs) open-source software library. 12 To date, ANTs development does not permit taking advantage of a graphics processing unit (GPU), which hinders the use of new free-breathing proton MR techniques in the clinical setting.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of image registration algorithms for 3D phase‐resolved functional lung ventilation magnetic resonance imaging in healthy volunteers and chronic obstructive pulmonary disease patients

et al. 2022

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The purpose of the current study was to assess the influence of the registration algorithms on the repeatability of three‐dimensional (3D) phase‐resolved functional lung (PREFUL) ventilation magnetic resonance imaging (MRI). Twenty‐three healthy volunteers and 10 patients with chronic obstructive pulmonary disease (COPD) underwent 3D PREFUL MRI during tidal breathing. The registration of dynamically acquired data to a fixed image was executed using single‐step, stepwise, and group‐oriented registration (GOREG) approaches. Advanced Normalization Tools (ANTs) and the Forsberg image‐registration package were used for the registration. Image registration algorithms were tested for differences and evaluated by the repeatability analysis of ventilation parameters using coefficient of variation (CoV), intraclass‐correlation coefficient, Bland–Altman plots, and correlation to spirometry. Also, the registration time and image quality were computed for all registration approaches. Very strong to strong correlations (r range: 0.917–0.999) were observed between ventilation parameters derived using various registration approaches. Median CoV values of the cross‐correlation (CC) parameter were significantly lower (all p ≤ 0.0054) for ANTs GOREG compared with single‐step and stepwise ANTs registration. The majority of comparisons between COPD patients and age‐matched healthy volunteers showed agreement among the registration approaches. The repeatability of regional ventilation (RVent)‐based ventilation defect percentage (VDPRVent) and VDPCC was significantly higher (both p ≤ 0.0054) for Forsberg GOREG compared with ANTs GOREG. All 3D PREFUL‐derived ventilation parameters correlated with forced expiratory volume in 1 s (FEV1) and the FEV1/ forced vital capacity (FVC) ratio (all |r| > 0.40, all p < 0.03). The image sharpness of RVent maps was statistically elevated (all p < 0.001) using GOREG compared with single‐step and stepwise registration approaches using ANTs. The best computational performance was achieved with Forsberg GOREG. The GOREG scheme improves the repeatability and image quality of dynamic 3D PREFUL ventilation parameters. Registration time can be ~10‐fold reduced to 9 min using the Forsberg method with equal or even improved repeatability and comparable PREFUL ventilation results compared with the ANTs method.

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Analysis of different image-registration algorithms for Fourier decomposition MRI in functional lung imaging

Cited by 7 publications

References 30 publications

Phase‐cycled balanced SSFP imaging for non‐contrast‐enhanced functional lung imaging

Phase‐cycled balanced SSFP imaging for non‐contrast‐enhanced functional lung imaging

Artificial intelligence in functional imaging of the lung

Evaluation of image registration algorithms for 3D phase‐resolved functional lung ventilation magnetic resonance imaging in healthy volunteers and chronic obstructive pulmonary disease patients

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