<sup>1</sup>H‐guided reconstruction of <sup>19</sup>F gas MRI in COPD patients

Obert, Arnd; Gutberlet, Marcel; Kern, A.; Kaireit, Till F.; Grimm, Robert; Wacker, Frank; Vogel‐Claussen, Jens

doi:10.1002/mrm.28209

Cited by 18 publications

(18 citation statements)

References 41 publications

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“…It has been shown that the extent of VDP (and the reproducibility of measurements as well) with hyperpolarized gas depends on the chosen gas, the inflation state (ie, chosen breathing maneuver and applied gas volume 36 ) and the latency between inhalation and scan allowing gas uptake in delayed‐filling lung regions; for example, via collateral ventilation 37 . Kirby et al observed visually and quantitatively higher VDP obtained with 129 Xe MR imaging in comparison to 3 He MR imaging in patients with COPD but not in healthy subjects, 38 and Obert et al measured higher VDP using 19 F in comparison to 129 Xe 39 . These differences are likely attributed to differences in gas density and viscosity—the use of a gas/ gas mixture with a lower density and viscosity results in a higher VDP.…”

Section: Discussionmentioning

confidence: 99%

Flow Volume Loop and Regional Ventilation Assessment Using Phase‐Resolved Functional Lung (PREFUL) MRI: Comparison With ¹²⁹Xenon Ventilation MRI and Lung Function Testing

Kaireit

Kern

Voskrebenzev

et al. 2020

Magnetic Resonance Imaging

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Background Regional flow volume loop ventilation‐weighted noncontrast‐enhanced proton lung MRI in free breathing has emerged as a novel technique for assessment of regional lung ventilation, but has yet not been validated with 129Xenon MRI (129Xe‐MRI), a direct visualization of ventilation in healthy volunteers, cystic fibrosis (CF), and chronic obstructive pulmonary disease (COPD) patients. Purpose To compare regional ventilation and regional flow volume loops measured by noncontrast‐enhanced ventilation‐weighted phase‐resolved functional lung MRI (PREFUL‐MRI) with 129Xe‐MRI ventilation imaging and with lung function test parameters. Study Type Retrospective study. Population Twenty patients with COPD, eight patients with CF, and six healthy volunteers. Field Strength/Sequence PREFUL and 129Xe‐MRI gradient echo sequences were acquired at 1.5T. Assessment Coronal slices of PREFUL‐MRI (free breathing) and 129Xe‐MRI (single breath‐hold) were acquired on the same day, matched by their ventrodorsal position and coregistered for evaluation. Ventilation defect percentage (VDP) was calculated based on regional ventilation (RV), regional flow volume loops (RFVL), or 129Xe‐MRI with two different threshold methods. A combined VDP was calculated for RV and RFVL. Additionally, lung function testing was performed (such as the forced expiratory volume in 1 second [FEV1]) was used. Statistical Tests The obtained parameters were compared using Wilcoxon tests, correlated using Spearman's correlation coefficient (r), and agreement between PREFUL and 129Xe‐MRI parameters was assessed using Bland–Altman analysis and Dice coefficients. Results VDP measured by PREFUL and 129Xe were significantly correlated with both thresholding techniques (r = 0.62–0.69, P < 0.05 for all) and with lung function test parameters. Combined RV and RFVL PREFUL defect maps correlated with lung function testing (eg, with FEV1 r = –0.87 P < 0.05), and showed better regional agreement to 129Xe‐MRI ventilation defects (Dice coefficient defect 0.413) with significantly higher VDP values (10.2 ± 27.3, P = 0.04) than either PREFUL defect map alone. Data Conclusion Combined RV and RFVL PREFUL defect maps likely increase sensitivity to mild airway obstruction with increased VDP values compared to 129Xe‐MRI, and correlate strongly with lung function test parameters. Level of Evidence 3 Technical Efficacy Stage 2

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Section: Discussionmentioning

confidence: 99%

Flow Volume Loop and Regional Ventilation Assessment Using Phase‐Resolved Functional Lung (PREFUL) MRI: Comparison With ¹²⁹Xenon Ventilation MRI and Lung Function Testing

Kaireit

Kern

Voskrebenzev

et al. 2020

Magnetic Resonance Imaging

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“… 124‐126 The gas wash‐out time constant has been shown to distinguish between healthy volunteers and patients with CF who have normal spirometry (FEV 1 > 80%), pointing toward its potential utility for early/mild disease 124 . Recent work has focused on optimization of the imaging technique, for example by employing steady‐state 127 and accelerated imaging using compressed sensing, 128 and utilizing anatomical proton MRI during reconstruction to improve the quality of 19 F MR images 129 . It should be stressed that ventilation defects identified by HP 3 He or 129 Xe are not identical to those identified by PFP; for example, a slow filling area might be identified as a ventilation defect on 129 Xe imaging but not 19 F MRI imaging.…”

Section: Fluorinated Gas Mrimentioning

confidence: 99%

Novel imaging techniques for cystic fibrosis lung disease

Goralski

Stewart

Woods

2021

Pediatric Pulmonology

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With an increasing number of patients with cystic fibrosis (CF) receiving highly effective CFTR (cystic fibrosis transmembrane regulator protein) modulator therapy, particularly at a young age, there is an increasing need to identify imaging tools that can detect and regionally visualize mild CF lung disease and subtle changes in disease state. In this review, we discuss the latest developments in imaging modalities for both structural and functional imaging of the lung available to CF clinicians and researchers, from the widely available, clinically utilized imaging methods for assessing CF lung disease—chest radiography and computed tomography—to newer techniques poised to become the next phase of clinical tools—structural/functional proton and hyperpolarized gas magnetic resonance imaging (MRI). Finally, we provide a brief discussion of several newer lung imaging techniques that are currently available only in selected research settings, including chest tomosynthesis, and fluorinated gas MRI. We provide an update on the clinical and/or research status of each technique, with a focus on sensitivity, early disease detection, and possibilities for monitoring treatment efficacy.

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“…This attribute results from the natural Boltzmann distribution of the spins in the Zeeman energy states for fluorinated gases, as opposed to hyperpolarized gases. Multiple studies have researched ways of improving the quality of ventilation images acquired with fluorinated gases 2,12,14‐16 . The main factors that affect SNR are the number of equivalent 19 F atoms and the relaxation time of the fluorinated gas.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of fluorine‐19 magnetic resonance imaging of the lungs using octafluorocyclobutane in a rat model

Shepelytskyi

Grynko

et al. 2020

Magnetic Resonance in Med

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Purpose To test octafluorocyclobutane (OFCB) as an inhalation contrast agent for fluorine‐19 MRI of the lung, and to compare the image quality of OFCB scans with perfluoropropane (PFP) scans Theory and Methods After normalizing for the number of signal averages, a theoretical comparison between the OFCB signal‐to‐noise ratio (SNR) and PFP SNR predicted the average SNR advantage of 90% using OFCB during gradient echo imaging. The OFCB relaxometry was conducted using single‐voxel spectroscopy and spin‐echo imaging. A comparison of OFCB and PFP SNRs was performed in vitro and in vivo. Five healthy Sprague‐Dawley rats were imaged during single breath‐hold and continuous breathing using a Philips Achieva 3.0T MRI scanner (Philips, Andover, MA). The scan time was constant for both gases. Statistical comparison between PFP and OFCB scans was conducted using a paired t test and by calculating the Bayes factor. Results Spin‐lattice (T1) and effective spin‐spin (T2∗) relaxation time constants of the pure OFCB gas were determined as 28.5 ± 1.2 ms and 10.5 ± 1.8 ms, respectively. Mixing with 21% of oxygen decreased T1 by 30% and T2∗ by 20%. The OFCB in vivo images showed 73% higher normalized SNR on average compared with images acquired using PFP. The statistical significance was shown by both paired t test and calculated Bayes factors. The experimental results agree with theoretical calculations within the error of the relaxation parameter measurements. Conclusion The quality of the lung images acquired using OFCB was significantly better compared with PFP scans. The OFCB images had higher a SNR and were artifact‐free.

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¹H‐guided reconstruction of ¹⁹F gas MRI in COPD patients

Cited by 18 publications

References 41 publications

Flow Volume Loop and Regional Ventilation Assessment Using Phase‐Resolved Functional Lung (PREFUL) MRI: Comparison With ¹²⁹Xenon Ventilation MRI and Lung Function Testing

Flow Volume Loop and Regional Ventilation Assessment Using Phase‐Resolved Functional Lung (PREFUL) MRI: Comparison With ¹²⁹Xenon Ventilation MRI and Lung Function Testing

Novel imaging techniques for cystic fibrosis lung disease

Evaluation of fluorine‐19 magnetic resonance imaging of the lungs using octafluorocyclobutane in a rat model

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1H‐guided reconstruction of 19F gas MRI in COPD patients

Cited by 18 publications

References 41 publications

Flow Volume Loop and Regional Ventilation Assessment Using Phase‐Resolved Functional Lung (PREFUL) MRI: Comparison With 129Xenon Ventilation MRI and Lung Function Testing

Flow Volume Loop and Regional Ventilation Assessment Using Phase‐Resolved Functional Lung (PREFUL) MRI: Comparison With 129Xenon Ventilation MRI and Lung Function Testing

Novel imaging techniques for cystic fibrosis lung disease

Evaluation of fluorine‐19 magnetic resonance imaging of the lungs using octafluorocyclobutane in a rat model

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¹H‐guided reconstruction of ¹⁹F gas MRI in COPD patients

Flow Volume Loop and Regional Ventilation Assessment Using Phase‐Resolved Functional Lung (PREFUL) MRI: Comparison With ¹²⁹Xenon Ventilation MRI and Lung Function Testing

Flow Volume Loop and Regional Ventilation Assessment Using Phase‐Resolved Functional Lung (PREFUL) MRI: Comparison With ¹²⁹Xenon Ventilation MRI and Lung Function Testing