TY - JOUR
T1 - Quantitative theory for the longitudinal relaxation time of blood water
AU - Li, Wenbo
AU - Grgac, Ksenija
AU - Huang, Alan
AU - Yadav, Nirbhay
AU - Qin, Qin
AU - van Zijl, Peter C.M.
N1 - Publisher Copyright:
© 2015 Wiley Periodicals, Inc.
PY - 2016/7/1
Y1 - 2016/7/1
N2 - Purpose: To propose and evaluate a model for the blood water T1 that takes into account the effects of hematocrit fraction, oxygenation fraction, erythrocyte hemoglobin concentration, methemoglobin fraction, and plasma albumin concentration. Methods: Whole blood and lysed blood T1 data were acquired at magnetic fields of 3 Tesla (T), 7T, 9.4T, and 11.7T using inversion-recovery measurements and a home-built blood circulation system for maintaining physiological conditions. A quantitative model was derived based on multivariable fitting of this data. Results: Fitting of the model to the data allowed determination of the different parameters describing the blood water T1 such as those for the diamagnetic and paramagnetic effects of albumin and hemoglobin, and the contribution of methemoglobin. The model correctly predicts blood T1 at multiple fields, as verified by comparison with existing literature. Conclusion: The model provides physical and physiological parameters describing the effects of hematocrit fraction, oxygenation, hemoglobin concentration, methemoglobin fraction, and albumin concentration on blood water T1. It can be used to predict blood T1 at multiple fields. Magn Reson Med 76:270–281, 2016.
AB - Purpose: To propose and evaluate a model for the blood water T1 that takes into account the effects of hematocrit fraction, oxygenation fraction, erythrocyte hemoglobin concentration, methemoglobin fraction, and plasma albumin concentration. Methods: Whole blood and lysed blood T1 data were acquired at magnetic fields of 3 Tesla (T), 7T, 9.4T, and 11.7T using inversion-recovery measurements and a home-built blood circulation system for maintaining physiological conditions. A quantitative model was derived based on multivariable fitting of this data. Results: Fitting of the model to the data allowed determination of the different parameters describing the blood water T1 such as those for the diamagnetic and paramagnetic effects of albumin and hemoglobin, and the contribution of methemoglobin. The model correctly predicts blood T1 at multiple fields, as verified by comparison with existing literature. Conclusion: The model provides physical and physiological parameters describing the effects of hematocrit fraction, oxygenation, hemoglobin concentration, methemoglobin fraction, and albumin concentration on blood water T1. It can be used to predict blood T1 at multiple fields. Magn Reson Med 76:270–281, 2016.
KW - Hct
KW - T model
KW - albumin
KW - hematocrit fraction
KW - hemoglobin concentration
KW - in vitro blood
KW - longitudinal relaxation
KW - methemoglobin fraction
KW - oxygenation
KW - relaxivity
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U2 - 10.1002/mrm.25875
DO - 10.1002/mrm.25875
M3 - Article
C2 - 26285144
AN - SCOPUS:84974856161
SN - 0740-3194
VL - 76
SP - 270
EP - 281
JO - Magnetic resonance in medicine
JF - Magnetic resonance in medicine
IS - 1
ER -