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• W3022946382 endingPage "106739" @default.
• W3022946382 startingPage "106739" @default.
• W3022946382 abstract "We present studies of spin-exchange optical pumping (SEOP) using ternary xenon-nitrogen-helium gas mixtures at high xenon partial pressures (up to 1330 Torr partial pressure at loading, out of 2660 Torr total pressure) in a 500-mL volume SEOP cell, using two automated batch-mode clinical-scale 129Xe hyperpolarizers operating under continuous high-power (~170 W) pump laser irradiation. In this pilot study, we explore SEOP in gas mixtures with up to 45% 4He content under a wide range of experimental conditions. When an aluminum jacket cooling/heating design was employed (GEN-3 hyperpolarizer), 129Xe polarization (%PXe) of 55.9 ± 0.9% was observed with mono-exponential build-up rate γSEOP of 0.049 ± 0.001 min−1 for the 4He-rich mixture (1000 Torr Xe/900 Torr He, 100 Torr N2), compared to %PXe of 49.3 ± 3.3% at γSEOP of 0.035 ± 0.004 min−1 for the N2-rich gas mixture (1000 Torr Xe/100 Torr He, 900 Torr N2). When forced-air cooling/heating was used (GEN-2 hyperpolarizer), %PXe of 83.9 ± 2.7% was observed at γSEOP of 0.045 ± 0.005 min−1 for the 4He-rich mixture (1000 Torr Xe/900 Torr He, 100 Torr N2), compared to %PXe of 73.5 ± 1.3% at γSEOP of 0.028 ± 0.001 min−1 for the N2-rich gas mixture (1000 Torr Xe and 1000 Torr N2). Additionally, %PXe of 72.6 ± 1.4% was observed at a build-up rate γSEOP of 0.041 ± 0.003 min−1 for a super-high-density 4He-rich mixture (1330 Torr Xe/1200 Torr 4He/130 Torr N2), compared to %PXe = 56.6 ± 1.3% at a build-up rate of γSEOP of 0.034 ± 0.002 min−1 for an N2-rich mixture (1330 Torr Xe/1330 Torr N2) using forced air cooling/heating. The observed SEOP hyperpolarization performance under these conditions corresponds to %PXe improvement by a factor of 1.14 ± 0.04 at 1000 Torr Xe density and by up to a factor of 1.28 ± 0.04 at 1330 Torr Xe density at improved SEOP build-up rates by factors of 1.61 ± 0.18 and 1.21 ± 0.11 respectively. Record %PXe levels have been obtained here: 83.9 ± 2.7% at 1000 Torr Xe partial pressure and 72.6 ± 1.4% at 1330 Torr Xe partial pressure. In addition to improved thermal stability for SEOP, the use of 4He-rich gas mixtures also reduces the overall density of produced inhalable HP contrast agents; this property may be desirable for HP 129Xe inhalation by human subjects in clinical settings—especially in populations with heavily impaired lung function. The described approach should enjoy ready application in the production of inhalable 129Xe contrast agent with near-unity 129Xe nuclear spin polarization." @default.
• W3022946382 created "2020-05-13" @default.
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• W3022946382 date "2020-06-01" @default.
• W3022946382 modified "2023-09-30" @default.
• W3022946382 title "Helium-rich mixtures for improved batch-mode clinical-scale spin-exchange optical pumping of Xenon-129" @default.
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• W3022946382 cites W1554617611 @default.
• W3022946382 cites W1582435223 @default.
• W3022946382 cites W1912319529 @default.
• W3022946382 cites W1965125223 @default.
• W3022946382 cites W1968082075 @default.
• W3022946382 cites W1972517270 @default.
• W3022946382 cites W1973063132 @default.
• W3022946382 cites W1973137433 @default.
• W3022946382 cites W1975095763 @default.
• W3022946382 cites W1979854777 @default.
• W3022946382 cites W1986757721 @default.
• W3022946382 cites W1987030469 @default.
• W3022946382 cites W1992569871 @default.
• W3022946382 cites W1994733862 @default.
• W3022946382 cites W1997172214 @default.
• W3022946382 cites W2002656892 @default.
• W3022946382 cites W2005942375 @default.
• W3022946382 cites W2021462174 @default.
• W3022946382 cites W2022564389 @default.
• W3022946382 cites W2031436470 @default.
• W3022946382 cites W2032069080 @default.
• W3022946382 cites W2041130235 @default.
• W3022946382 cites W2041749371 @default.
• W3022946382 cites W2044052913 @default.
• W3022946382 cites W2045169599 @default.
• W3022946382 cites W2045490198 @default.
• W3022946382 cites W2048127703 @default.
• W3022946382 cites W2050028286 @default.
• W3022946382 cites W2057017828 @default.
• W3022946382 cites W2057733730 @default.
• W3022946382 cites W2058655897 @default.
• W3022946382 cites W2059700219 @default.
• W3022946382 cites W2059900570 @default.
• W3022946382 cites W2070916102 @default.
• W3022946382 cites W2079806014 @default.
• W3022946382 cites W2083505809 @default.
• W3022946382 cites W2083725740 @default.
• W3022946382 cites W2086205216 @default.
• W3022946382 cites W2091612649 @default.
• W3022946382 cites W2091723288 @default.
• W3022946382 cites W2095145345 @default.
• W3022946382 cites W2096330560 @default.
• W3022946382 cites W2110878068 @default.
• W3022946382 cites W2120913449 @default.
• W3022946382 cites W2121549143 @default.
• W3022946382 cites W2130348576 @default.
• W3022946382 cites W2141261085 @default.
• W3022946382 cites W2142022122 @default.
• W3022946382 cites W2142136953 @default.
• W3022946382 cites W2289904488 @default.
• W3022946382 cites W2505030495 @default.
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• W3022946382 doi "https://doi.org/10.1016/j.jmr.2020.106739" @default.
• W3022946382 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/32408239" @default.
• W3022946382 hasPublicationYear "2020" @default.
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