In previous experiments by the authors, in which hyperpolarized Xe-129 was
dissolved in fresh blood samples, the T-1 was found to be strongly dependen
t on the oxygenation level, the values increasing with oxygenation: T-1 was
about 4 s in deoxygenated samples and about 13 s in oxygenated samples. C.
H. Tseng et al. (1997, J. Magn. Reson. 126, 79-86), on the other hand, rec
ently reported extremely long T-1 values using hyperpolarized Xe-129 to cre
ate a "blood foam" and found that oxygenation decreased T-1. In their exper
iments, the continual and rapid exchange of hyperpolarized Xe-129 between t
he gas phase (within blood-foam bubbles) and the dissolved phase tin the sk
in of the bubbles) necessitated a complicated analysis to extract the effec
tive blood T-1. In the present study, the complications of hyperpolarized X
e-129 exchange dynamics have been avoided by using thermally polarized Xe-1
29 dissolved in whole blood and in suspensions of lysed red blood cells (RB
C). During T-1 measurements in whole blood, the samples were gently and con
tinuously agitated, for the entire course of the experiment, to avert sedim
entation. Oxygenation was found to markedly increase the T-1 of Xe-129 in b
lood, as originally measured, and it shifts the RBC resonance to a higher f
requency. Carbon monoxide has a similar but somewhat stronger effect. (C) 1
999 Academic Press.