RATIONALE AND OBJECTIVES: Renal medullary hypoxia is frequently implicated in renal dysfunction, and urinary oxygen tension (PO(2)) in the renal pelvis can be used as a surrogate for the adjacent renal medullary oxygenation. We sought to assess the feasibility of magnetic resonance (MR) quantification of urinary PO(2) in humans. MATERIALS AND METHODS: The longitudinal relaxivity (R1) of fluids is linearly related to PO(2), allowing MR quantification of urinary PO(2). We imaged urine phantoms with a range of PO(2) using a real-time saturation recovery T2-prepped single-shot fast spin-echo sequence to calibrate urine R1 values to PO(2). Following institutional review board approval, we imaged the urinary bladders of seven healthy subjects while they were breathing room air and the renal pelvis of nine healthy subjects while they were breathing room air or 100% oxygen via facemask. The renal pelvic urine PO(2) was compared before, during, and after 100% oxygen breathing. RESULTS: Our phantom study confirmed that urine R1 is linearly related to PO(2): PO(2) (mm Hg) = (R1 - 0.2253 s(-1))/(2.61e(-4) s(-1)/mm Hg). The mean bladder urine PO(2) ranged from 23 to 45 mm Hg among the seven subjects. Successful MR measurements of renal pelvic urine PO(2) were obtained in seven of nine healthy subjects. Following 100% O(2) breathing, the renal pelvic urine PO(2) showed a significant mean increase of 29 mm Hg (P < .05). CONCLUSIONS: We show that MR quantification of urinary PO(2) is feasible. Noninvasive renal pelvic urine PO(2) determinations could serve as a valuable indirect measure for renal medullary oxygenation, allowing for clinical investigations of the role of renal medullary hypoxia in renal disease.
RATIONALE AND OBJECTIVES: Renal medullary hypoxia is frequently implicated in renal dysfunction, and urinary oxygen tension (PO(2)) in the renal pelvis can be used as a surrogate for the adjacent renal medullary oxygenation. We sought to assess the feasibility of magnetic resonance (MR) quantification of urinary PO(2) in humans. MATERIALS AND METHODS: The longitudinal relaxivity (R1) of fluids is linearly related to PO(2), allowing MR quantification of urinary PO(2). We imaged urine phantoms with a range of PO(2) using a real-time saturation recovery T2-prepped single-shot fast spin-echo sequence to calibrate urine R1 values to PO(2). Following institutional review board approval, we imaged the urinary bladders of seven healthy subjects while they were breathing room air and the renal pelvis of nine healthy subjects while they were breathing room air or 100% oxygen via facemask. The renal pelvic urine PO(2) was compared before, during, and after 100% oxygen breathing. RESULTS: Our phantom study confirmed that urine R1 is linearly related to PO(2): PO(2) (mm Hg) = (R1 - 0.2253 s(-1))/(2.61e(-4) s(-1)/mm Hg). The mean bladder urine PO(2) ranged from 23 to 45 mm Hg among the seven subjects. Successful MR measurements of renal pelvic urine PO(2) were obtained in seven of nine healthy subjects. Following 100% O(2) breathing, the renal pelvic urine PO(2) showed a significant mean increase of 29 mm Hg (P < .05). CONCLUSIONS: We show that MR quantification of urinary PO(2) is feasible. Noninvasive renal pelvic urine PO(2) determinations could serve as a valuable indirect measure for renal medullary oxygenation, allowing for clinical investigations of the role of renal medullary hypoxia in renal disease.
Authors: Greg Zaharchuk; Reed F Busse; Guy Rosenthal; Geoffery T Manley; Orit A Glenn; William P Dillon Journal: Acad Radiol Date: 2006-08 Impact factor: 3.173
Authors: Andrea Morelli; Monica Rocco; Giorgio Conti; Alessandra Orecchioni; Roberto Alberto De Blasi; Flaminia Coluzzi; Paolo Pietropaoli Journal: Anesth Analg Date: 2003-12 Impact factor: 5.108
Authors: Kyle A Floyd; Courtney A Mitchell; Allison R Eberly; Spencer J Colling; Ellisa W Zhang; William DePas; Matthew R Chapman; Matthew Conover; Bridget R Rogers; Scott J Hultgren; Maria Hadjifrangiskou Journal: J Bacteriol Date: 2016-09-09 Impact factor: 3.490
Authors: Mark D Okusa; Bertrand L Jaber; Peter Doran; Jacques Duranteau; Li Yang; Patrick T Murray; Ravindra L Mehta; Can Ince Journal: Contrib Nephrol Date: 2013-05-13 Impact factor: 1.580
Authors: Connor J Beebout; Allison R Eberly; Sabrina H Werby; Seth A Reasoner; John R Brannon; Shuvro De; Madison J Fitzgerald; Marissa M Huggins; Douglass B Clayton; Lynette Cegelski; Maria Hadjifrangiskou Journal: mBio Date: 2019-04-02 Impact factor: 7.867
Authors: Emma Bluemke; Liam A J Young; Joshua Owen; Sean Smart; Paul Kinchesh; Daniel P Bulte; Eleanor Stride Journal: MAGMA Date: 2022-04-13 Impact factor: 2.533
Authors: Allison R Eberly; Kyle A Floyd; Connor J Beebout; Spencer J Colling; Madison J Fitzgerald; Charles W Stratton; Jonathan E Schmitz; Maria Hadjifrangiskou Journal: Int J Mol Sci Date: 2017-09-30 Impact factor: 5.923