Hyperpolarized Xenon‐129 gas‐exchange imaging of lung microstructure: First case studies in subjects with obstructive lung disease

Dregely, Isabel; Mugler, John P.; Ruset, Iulian C.; Altes, Talissa A.; Mata, Jaime F.; Miller, G. Wilson; Ketel, Jeffrey; Ketel, Stephen; Distelbrink, J.H.J.; Hersman, F. W.; Ruppert, K.

doi:10.1002/jmri.22533

Cited by 91 publications

(98 citation statements)

References 35 publications

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“…3,4 Unlike optical pumping techniques, 5,6 DNP is performed in the solid state, with 1000 times higher 129 Xe density and, potentially, higher production rates. 129 Xe DNP builds upon the earlier success of low-temperature DNP of 13 C-labelled biomolecules, where high 13 C polarization (15%−75%) 7 is retained at room temperature after a rapid dissolution.…”

Section: Recent Reportsmentioning

confidence: 99%

“…After a number of modifications to the DNP system with an aim of reducing sample overheating, our subsequent experiment showed a four-fold increase in 129 Xe polarization, from 5.3% to 21%. 4 He variable-temperature insert could be cooled down to below 1.3 K for about an hour (or kept indefinitely at 1.43 K and above) using an external pump while being monitored with an Oxford Instruments ITC-503 controller. A computer-controlled primary microwave source (7-8 GHz range and 18.3 dBm power, Hewlett-Packard 83623B or Giga-tronics SNY-0410-510-01) fed via a short coaxial cable into a probe-mounted ×18 frequency multiplier/narrow-band 140 GHz, 70 mW microwave amplifier (ELVA DCOIMA-06/140/70).…”

Section: Recent Reportsmentioning

confidence: 99%

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Cluster formation restricts dynamic nuclear polarization of xenon in solid mixtures

Kuzma

Pourfathi

Kara

et al. 2012

The Journal of Chemical Physics

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During dynamic nuclear polarization (DNP) at 1.5 K and 5 T, 129 Xe nuclear magnetic resonance (NMR) spectra of a homogeneous xenon/1-propanol/trityl-radical solid mixture exhibit a single peak, broadened by 1 H neighbors. A second peak appears upon annealing for several hours at 125 K. Its characteristic width and chemical shift indicate the presence of spontaneously formed pure Xe clusters. Microwave irradiation at the appropriate frequencies can bring both peaks to either positive or negative polarization. The peculiar time evolution of 129 Xe polarization in pure Xe clusters during DNP can be modelled as an interplay of spin diffusion and T 1 relaxation. Our simple spherical-cluster model offers a sensitive tool to evaluate major DNP parameters in situ, revealing a severe spindiffusion bottleneck at the cluster boundaries and a significant sample overheating due to microwave irradiation. Subsequent DNP system modifications designed to reduce the overheating resulted in four-fold increase of 129 Xe polarization, from 5.3% to 21%.

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Section: Recent Reportsmentioning

confidence: 99%

Section: Recent Reportsmentioning

confidence: 99%

Cluster formation restricts dynamic nuclear polarization of xenon in solid mixtures

Kuzma

Pourfathi

Kara

et al. 2012

The Journal of Chemical Physics

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“…(The recently developed "open source" polarizer is a notable exception [8].) A cold trap using liquid nitrogen (LN 2 ) is typically used both to separate xenon from the other gases in the mixture that are needed to optimize spin-exchange optical pumping (SEOP) and to provide a compact storage vessel with a polarization lifetime T 1 ≈ 2.5 h. A detailed understanding of 129 Xe longitudinal relaxation in solid xenon is thus important for its use in a wide variety of fundamental studies and applications [9][10][11], including magnetic resonance imaging of the lung [12][13][14][15]. More generally, noble-gas solids are excellent model systems for first-principles calculation of nuclear relaxation mechanisms and rates.…”

Section: Introductionmentioning

confidence: 99%

Robust solidXe129longitudinal relaxation times

Limes

Sorte

et al. 2016

Phys. Rev. B

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We find that if solid xenon is formed from liquid xenon, denoted "ice", there is a 10% increase of 129 Xe longitudinal relaxation T1 time (taken at 77 K and 2 Tesla) over a trickle-freeze formation, denoted "snow". Forming xenon ice also gives unprecedented reproducibility of 129 Xe T1 measurements across a range of 77-150 K. This temperature dependence roughly follows the theory of spin-rotation mediated by Raman scattering of harmonic phonons (SRRS), though it results in a smaller-than-predicted spin-rotation coupling strength cK0/h. Enriched ice 129 Xe T1 experiments show no isotopic dependence in bulk relaxation mechanisms at 77 K and at kilogauss fields.

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“…Recent hyperpolarization methods can create near-unity net spin polarizations [13], resulting in spectroscopic signals four to five orders of magnitude greater than nonhyperpolarized samples. Such improvements in image quality facilitate the use of HP noble gas MRI within the lungs as a diagnostic imaging tool for characterizing lung structure and function [14], and consequently may potentially enable earlier and more reliable diagnosis of various respiratory disorders, such as idiopathic pulmonary fibrosis (IPF) and chronic obstructive pulmonary disease (COPD) 7]. An example of a HP 129 Xe lung ventilation image can be seen in Figure 2.…”

Section: Hyperpolarized Lung Imagingmentioning

confidence: 99%

Using Raman Spectroscopy to Improve Hyperpolarized Noble Gas Production for Clinical Lung Imaging Techniques

Birchall¹,

Whiting²,

Skinner³

et al. 2017

Raman Spectroscopy and Applications

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Spin-exchange optical pumping (SEOP) can be used to "hyperpolarize" 129Xe for human lung MRI. SEOP involves transfer of angular momentum from light to an alkali metal (Rb) vapor, and then onto 129 Xe nuclear spins during collisions; collisions between excited Rb and N 2 ensure that incident optical energy is nonradiatively converted into heat. However, because variables that govern SEOP are temperature-dependent, the excess heat can complicate efforts to maximize spin polarization-particularly at high laser fluxes and xenon densities. Ultra-low frequency Raman spectroscopy may be used to perform in situ gas temperature measurements to investigate the interplay of energy thermalization and SEOP dynamics. Experimental configurations include an "orthogonal" pump-and-probe design and a newer "inline" design (with source and detector on the same axis) that has provided a >20-fold improvement in SNR. The relationship between 129 Xe polarization and the spatiotemporal distribution of N 2 rotational temperatures has been investigated as a function of incident laser flux, exterior cell temperature, and gas composition. Significantly elevated gas temperatures have been observed -hundreds of degrees hotter than exterior cell surfaces-and variances with position and time can indicate underlying energy transport, convection, and Rb mass-transport processes that, if not controlled, can negatively impact 129 Xe hyperpolarization.

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Hyperpolarized Xenon‐129 gas‐exchange imaging of lung microstructure: First case studies in subjects with obstructive lung disease

Cited by 91 publications

References 35 publications

Cluster formation restricts dynamic nuclear polarization of xenon in solid mixtures

Cluster formation restricts dynamic nuclear polarization of xenon in solid mixtures

Robust solidXe129longitudinal relaxation times

Using Raman Spectroscopy to Improve Hyperpolarized Noble Gas Production for Clinical Lung Imaging Techniques

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