ORIGINAL PAPER
Noninvasive evaluation of renal tissue oxygenation with blood oxygen level-dependent magnetic resonance imaging early after transplantation has a limited predictive value for the delayed graft function
Submission date: 2018-07-03
Acceptance date: 2018-07-05
Publication date: 2018-08-05
Pol J Radiol, 2018; 83: 389-393
KEYWORDS
renal graft oxygenationBOLD MRIblood oxygen level dependent (BOLD) magnetic resonancekidney transplantation
TOPICS
ABSTRACT
Purpose:
The aim of this study was to evaluate the feasibility of renal oxygenation assessment using blood oxygen level-dependent (BOLD) magnetic resonance imaging (MRI) in the early period after kidney transplantation and to estimate its prognostic value for delayed graft function.
Material and methods:
Examinations were performed in 50 subjects: 40 patients within a week after the kidney transplantation and 10 healthy controls, using T2*-weighted sequence. Measurements in transplant patients were correlated to basic laboratory parameters in the early period after transplantation and at follow-up.
Results:
Examinations of seven patients (18%) were rejected due to their poor technical quality. Mean R2* values in transplant recipients were lower than in controls (11.6 vs. 15.9 Hz; p = 0.0001). An R2* value of 0.28 Hz was calculated as the minimal detectable change. There was no relation between R2* values and laboratory parameters. However, patients eGFR ≥ 40 ml/min/1.73 m2 presented higher R2* values than recipients eGFR < 40 ml/min/1.73 m2 (12.0 vs. 11.1 Hz; p = 0.0189). In ROC analysis R2* of ≤ 11.7 predicted an early reduced graft function with 0.82 sensitivity and 56% specificity (AUC = 0.708; p = 0.024) but was not useful for delayed graft function prediction (p > 0.7).
Conclusions:
Evaluation of renal graft oxygenation using BOLD MRI is technically challenging in the early period after transplantation. An R2* value of 0.28 Hz may in practice be considered as the minimal detectable change. The delayed graft function seems not to be dependent on early oxygenation values. Further, large-scale studies are necessary to confirm the latter observation.
The aim of this study was to evaluate the feasibility of renal oxygenation assessment using blood oxygen level-dependent (BOLD) magnetic resonance imaging (MRI) in the early period after kidney transplantation and to estimate its prognostic value for delayed graft function.
Material and methods:
Examinations were performed in 50 subjects: 40 patients within a week after the kidney transplantation and 10 healthy controls, using T2*-weighted sequence. Measurements in transplant patients were correlated to basic laboratory parameters in the early period after transplantation and at follow-up.
Results:
Examinations of seven patients (18%) were rejected due to their poor technical quality. Mean R2* values in transplant recipients were lower than in controls (11.6 vs. 15.9 Hz; p = 0.0001). An R2* value of 0.28 Hz was calculated as the minimal detectable change. There was no relation between R2* values and laboratory parameters. However, patients eGFR ≥ 40 ml/min/1.73 m2 presented higher R2* values than recipients eGFR < 40 ml/min/1.73 m2 (12.0 vs. 11.1 Hz; p = 0.0189). In ROC analysis R2* of ≤ 11.7 predicted an early reduced graft function with 0.82 sensitivity and 56% specificity (AUC = 0.708; p = 0.024) but was not useful for delayed graft function prediction (p > 0.7).
Conclusions:
Evaluation of renal graft oxygenation using BOLD MRI is technically challenging in the early period after transplantation. An R2* value of 0.28 Hz may in practice be considered as the minimal detectable change. The delayed graft function seems not to be dependent on early oxygenation values. Further, large-scale studies are necessary to confirm the latter observation.
REFERENCES (24)
1.
Sharfuddin A. Renal relevant radiology: Imaging in kidney transplantation. Clin J Am Soc Nephrol 2014; 9: 416-429.
2.
Thölking G, Schuette-Nuetgen K, Kentrup D, et al. Imaging-based diagnosis of acute renal allograft rejection. World J Transplant 2016; 6: 174-182.
3.
Baker R, Jardine A, Andrews P. Clinical Practice Guidelines: Post-operative care of the kidney transplant recipient, UK Renal Association. 5th ed. Final version (10th December 2010).
4.
Mahmoud H, Buchanan C, Francis ST, Selby NM. Imaging the kidney using magnetic resonance techniques: structure to function. Curr Opin Nephrol Hypertens 2016; 25: 487-493.
5.
Gaddikeri S, Mitsumori L, Vaidya S, et al. Comparing the diagnostic accuracy of contrast-enhanced computed tomographic angiography and gadolinium-enhanced magnetic resonance angiography for the assessment of hemodynamically significant transplant renal artery stenosis. Curr Probl Diagn Radiol 2014; 43: 162-168.
6.
Wang YT, Li YC, Yin LL, et al. Functional assessment of transplanted kidneys with magnetic resonance imaging. World J Radiol 2015; 7: 343-349.
7.
Wypych-Klunder K, Adamowicz A, Lemanowicz A, et al. Diffusion-weighted MR imaging of transplanted kidneys: Preliminary report. Pol J Radiol 2014; 79: 94-98.
8.
Robson PM, Madhuranthakam AJ, Smith MP, et al. Volumetric arterial spin-labeled perfusion imaging of the kidneys with a three-dimensional fast spin echo acquisition. Acad Radiol 2016; 23: 144-154.
9.
Notohamiprodjoa M, Reiser MF, Sourbron SP. Diffusion and perfusion of the kidney. Eur J Radiol 2010; 76: 337-347.
10.
Prasad PV, Edelman RR, Epstein FH. Noninvasive evaluation of intrarenal oxygenation with BOLD MRI. Circulation 1996; 94: 3271-3275.
11.
Milani B, Ansaloni A, Sousa-Guimaraes S, et al. Reduction of cortical oxygenation in chronic kidney disease: evidence obtained with a new analysis method of blood oxygenation level-dependent magnetic resonance imaging. Nephrol Dial Transplant 2016; pii: gfw362.
12.
Sadowski EA, Fain SB, Alford SK, et al. Assessment of acute renal transplant rejection with blood oxygen level-dependent MR imaging: initial experience. Radiology 2005; 236: 911-919.
13.
Djamali A, Sadowski EA, Samaniego-Picota M, et al. Noninvasive assessment of early kidney allograft dysfunction by blood oxygen level-dependent magnetic resonance imaging. Transplantation 2006; 82: 621-628.
15.
dependent and perfusion magnetic resonance imaging: detecting differences in oxygen bioavailability and blood flow in transplanted kidneys. Magn Reson Imaging 2010; 28: 56-64.
16.
Park SY, Kim CK, Park BK, et al. Assessment of early renal allograft dysfunction with blood oxygenation level-dependent MRI and diffusion-weighted imaging. Eur J Radiol 2014; 83: 2114-2121.
17.
Liu G, Han F, Xiao W, et al. Detection of renal allograft rejection using blood oxygen level-dependent and diffusion weighted magnetic resonance imaging: a retrospective study. BMC Nephrol 2014; 15: 158.
18.
Vermathen P, Binser T, Boesch C, et al. Three-year follow-up of human transplanted kidneys by diffusion-weighted MRI and blood oxygenation level-dependent imaging. J Magn Reson Imaging 2012; 35: 1133-1138.
19.
Haley SM, Fragala-Pinkham MA. Interpreting change scores of tests and measures used in physical therapy Phys Ther 2006; 86: 735-743.
20.
Niles DJ, Artz NS, Djamali A, et al. Longitudinal assessment of renal perfusion and oxygenation in transplant donor-recipient pairs using arterial spin labeling and blood oxygen level-dependent magnetic resonance imaging. Invest Radiol 2016; 51: 113-120.
21.
Park SY, Kim CK, Park BK, et al. Evaluation of transplanted kidneys using blood oxygenation level-dependent MRI at 3 T: a preliminary study. AJR Am J Roentgenol 2012; 198: 1108-1114.
22.
Xiao W, Xu J, Wang Q, et al. Functional evaluation of transplanted kidneys in normal function and acute rejection using BOLD MR imaging. Eur J Radiol 2012; 81: 838-845.
23.
Thoeny HC, Zumstein D, Simon-Zoula S, et al. Functional evaluation of transplanted kidneys with diffusion-weighted and BOLD MR imaging: initial experience. Radiology 2006; 241: 812-821.
24.
Seif M, Eisenberger U, Binser T, et al. Renal blood oxygenation level-dependent imaging in longitudinal follow-up of donated and remaining kidneys. Radiology 2016; 279: 795-804.
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