Urinary Biomarkers for Diagnosis and Prediction of Acute Kidney Allograft Rejection: A Systematic Review
Abstract
:1. Introduction
2. Results
2.1. Included Studies
2.2. Study Characteristics
2.3. Biomarkers
2.4. Quality Assessment
2.5. Summary of the Results
2.5.1. Acute Rejection Diagnosis
2.5.2. T-Cell-Mediated Rejection Diagnosis
2.5.3. Antibody-Mediated Rejection Diagnosis
2.5.4. Acute Rejection, TCMR, and ABMR Prediction
3. Discussion
4. Materials and Methods
4.1. Literature Search
4.2. Selection Process
4.3. Data Collection and Analysis
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
ABMR | Antibody-mediated rejection |
AKI | Acute kidney injury |
AR | Acute rejection |
ATN | Acute tubular necrosis |
AUC | Area under the ROC curve |
BKVN | BK virus nephropathy |
CAN | Chronic allograft nephropathy |
CCL2 | Chemokine ligand 2 |
cfDNA | Cell free DNA |
CKD | Chronic kidney disease |
CTOT | Clinical trials in organ transplantation |
CXCL | C-X-C motif chemokine ligands |
DGF | Delayed graft function |
DSA | Donor-specific antibodies |
DTA | Diagnostic test accuracy |
EPCAM | Epithelial cell adhesion molecule |
FOXP3 | Forkhead box P3 |
GABA | Gamma-aminobutyric acid |
HE4 | Human epididymis protein 4 |
HPX | Hemopexin |
IFNγ | Interferon gamma |
IFTA | Interstitial fibrosis and tubular atrophy |
iKEA | Integrated kidney exosome analysis |
IL | Interleukin |
LC3 | Microtubule-associated protein 1A/1B-light chain 3 |
LFABP | Liver-type fatty acid-binding protein |
MMP7 | Matrix metalloproteinase 7 |
MNA | 1-methylnicotinamide |
NAD | Nicotinamide adenine dinucleotide |
NADP | Nicotinamide adenine dinucleotide phosphate |
NGAL | Neutrophil gelatinase-associated lipocalin |
NPV | Negative predictive value |
PB | Publication bias |
PD1 | Programmed cell death protein 1 |
PDX | Podocalyxin |
PPV | Positive predictive value |
PRISMA | Preferred reporting items for systematic reviews and meta-analysis |
QUADAS | Quality assessment tool for diagnostic accuracy studies |
Sens | Sensitivity |
Spec | Specificity |
sTIM3 | Soluble T cell immunoglobulin mucin domain 3 |
TCMR | T-cell mediated rejection |
TEC | Tubular epithelial cells |
TNFα | Tumor necrosis factor alpha |
TSPAN1 | Tetraspanin 1 |
uCRM | Urinary common rejection module |
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Ref | Study Design | Single/Multicenter | Patients (n) | Enrolment (years) | Urinary Biomarker(s) | Ref. Standard | Outcome |
---|---|---|---|---|---|---|---|
Tinel [16] | Cross-sectional | Single center | 329 | 2011–2016 | CXCL9, CXCL10 | Banff ‘15 | TCMR, ABMR |
Yang [17] | Cross-sectional | Multicenter | 364 | 2010–2018 | Q score | Banff ‘17 | TCMR, ABMR |
Kalantari [18] | Case-control | Single center | 22 | 2016–2018 | Unbiased metabolomics 1 | Banff ‘97 | TCMR |
Verma [19] | Case-control | Single center | 53 | N/R | RNA-Seq signature | Banff ‘17 | TCMR |
Goerlich [20] | Case-control | Single center | 39 | 2016–2017 | T cells, TEC, PDX | Banff ‘13 | TCMR, ABMR |
Banas [21] | Cross-sectional | Single center | 109 | 2011–2012 | Unbiased metabolomics 2 | Banff ‘09 | TCMR, ABMR |
Tajima [22] | Cross-sectional | Single center | 80 | 2014–2016 | LC3, CCL2, LFABP, NGAL, HE4 | Banff ‘09 | TCMR, ABMR |
Kolling [23] | Case-control | Single center | 93 | N/R | Circular RNAs | Banff ‘09 | TCMR |
Sigdel [24] | Cross-sectional | Multicenter | 150 | 2000–2016 | uCRM score | Banff ‘09 | TCMR, ABMR |
Kim [25] | Case-control | Multicenter | 23 | N/R | Unbiased metabolomics 3 | Banff ‘07 | TCMR |
Ciftci [26] * | Prospective | Single center | 85 | 2014–2017 | CXCL9, CXCL10 | Banff ‘13 | TCMR, ABMR |
Banas [27] | Case-control | Single center | 358 | 2008–2010; 2015–2016 | Unbiased metabolomics 2 | Banff ‘97 | TCMR |
Lim [28] | Case-control | Multicenter | 47 | 2013–2015 | Exosome proteins | Banff ‘07 | TCMR |
Chen [29] | Case-control | Single center | 49 | 2006–2009 | CXCL13 | Banff ‘97 | TCMR, ABMR |
Barabadi [30] § | Cross-sectional | Single center | 91 | 2013–2015 | FOXP3 | Banff ‘13 | AR |
Mockler [31] *§ | Prospective | Single center | 38 | N/R | CCL2 | Banff ‘13 | TCMR |
Ciftci [32] * | Prospective | Single center | 65 | 2013–2015 | TNFα | Banff ‘97 | AR |
Park [33] | Case-control | Single center | 44 | N/R | Exosome proteins | Banff (N/R) | TCMR |
Millan [34] * | Prospective | Multicenter | 80 | N/R | miR-155-5p, CXCL10 | Banff ‘97 | TCMR |
Seo [35] | Case-control | Multicenter | 88 | 2013–2015 | CTOT4 formula | Banff (N/R) | TCMR, ABMR |
Gandolfini [36] § | Case-control | Multicenter | 56 | N/R | CXCL9 | Banff ‘13 | TCMR |
Chen [37] | Case-control | Single center | 156 | 2006–2009 | sTim3 | Banff ‘97 | TCMR, ABMR |
Domenico [38] § | Case-control | Single center | 49 | N/R | miRNA-142-3p | Banff ‘07 | AR |
Lee [39] § | Case-control | Single center | 34 | N/R | Donor-derived cfDNA | unclear | AR |
Seeman [40] § | Case-control | Single center | 15 | 2013–2014 | NGAL | Banff ‘09 | TCMR, ABMR |
Blydt-H. [41] | Cross-sectional | Multicenter | 59 | 2002–N/R | ABMR score | Banff ‘13 | ABMR |
Belmar V. [42] * | Retrospective | Single center | 86 | 2012–2015 | Albumin | Banff (N/R) | ABMR |
Raza [43] | Cross-sectional | Single center | 300 | 2009–2014 | CCL2 | Banff ‘97 | TCMR |
Galichon [44] | Cross-sectional | Multicenter | 108 | N/R | CTOT4 formula | Banff ‘09 | TCMR, ABMR |
Sigdel [45] | Cross-sectional | Single center | 396 | 2000–2011 | Unbiased proteomics | Banff ‘07 | TCMR, ABMR |
Garcìa-C. [46] § | Cross-sectional | Single center | 50 | N/R | IL10, IFNγ | Banff ‘09 | TCMR, ABMR |
Ho [47] § | Cross-sectional | Single center | 133 | N/R | MMP7, CXCL10 | Banff ‘07 | TCMR |
A. Elaziz [48] | Cross-sectional | Single center | 54 | 2011–2014 | PD1, FOXP3 | Banff ‘07 | TCMR |
Lorenzen [49] | Cross-sectional | Single center | 93 | N/R | LncRNAs | Banff ‘09 | TCMR |
Rabant [50] * | Prospective | Single center | 300 | 2010–2012 | CXCL9, CXCL10 | Banff ‘07 | TCMR, ABMR |
Rabant [51] | Cross-sectional | Single center | 244 | 2011–2013 | CXCL9, CXCL10 | Banff ‘07 | TCMR, ABMR |
Blydt-H. [52] | Cross-sectional | Single center | 51 | 2002–N/R | CXCL10 | Banff ‘07 | TCMR |
Sigdel [53] § | Case-control | Single center | 30 | 2000–2009 | Exosome proteins | Banff ‘07 | AR |
Category | Biomarkers |
---|---|
Cytokines | |
Chemokines Other | CCL2, CXCL9, CXCL10, CXCL13 IFNγ, IL10, TNFα |
Metabolites | |
Nucleotides Amino acids and Organic acids Other small molecules | NAD, NADP Alanine, Citrate, GABA, 4-Guanidinobutyric Acid, Guanidoacetic Acid, Homocysteine, Lactate, Methylimidazoleacetic Acid, Nicotinic Acid, l-Tryptophan Cholesterol Sulfate, Dopamine, MNA, Urea |
Proteins | Albumin, LFAPB, HE4, LC3, MMP7, NGAL, sTIM3, Urinary extracellular vesicle (exosome) proteins (HPX, TSPAN1) |
RNAs micro RNAs | Circular RNAs, FOXP3 mRNA, LncRNAs, PD1 mRNA, RNA-seq miR-142-3p, miR-155-5p |
Urinary Cells | CD4+/CD8+ T cells, CD10+/EPCAM+ cells, PDX+ cells, TEC |
Scores and Formulas | |
ABMR score [41] CTOT-4 formula [54] Q score [17] uCRM score [24] | Signature of 133 unique metabolites CD3ε mRNA + CXCL10 mRNA + 18S rRNA Cell-free DNA + Clusterin + Creatinine + CXCL10 + Methylated Cell-free DNA + Total Urinary Protein 11 genes expression score on urinary cell pellet (including CXCL9 and CXCL10) |
Ref | Risk of Bias | Applicability Concerns | |||||
---|---|---|---|---|---|---|---|
Patient Selection | Index Test | Reference Standard | Flow and Timing | Patient Selection | Index Test | Reference Standard | |
Tinel [16] | ☺ | ☺ | ☺ | ☺ | ☺ | ☺ | ☺ |
Yang [17] | ☺ | ☺ | ☺ | ☺ | ☺ | ☺ | ☺ |
Kalantari [18] | ☹ | ☹ | ☺ | ? | ☹ | ☹ | ☺ |
Verma [19] | ☹ | ☹ | ☺ | ☺ | ☹ | ☺ | ☺ |
Goerlich [20] | ☹ | ☹ | ☺ | ☺ | ☹ | ☺ | ☺ |
Banas [21] | ☺ | ☺ | ☺ | ? | ☺ | ☺ | ☺ |
Tajima [22] | ☺ | ☹ | ☺ | ☺ | ☹ | ☺ | ☺ |
Kolling [23] | ☹ | ☹ | ☺ | ☺ | ☹ | ☺ | ☺ |
Sigdel [24] | ☺ | ☹ | ☺ | ☺ | ☺ | ☺ | ☺ |
Kim [25] | ☹ | ☹ | ☺ | ☺ | ☹ | ☺ | ☺ |
Ciftci [26] * | ☹ | ☹ | ☺ | ? | ☹ | ☺ | ☺ |
Banas [27] | ☹ | ☹ | ☺ | ☺ | ☹ | ☺ | ☺ |
Lim [28] | ☹ | ☹ | ☺ | ☺ | ☹ | ☺ | ☺ |
Chen [29] | ☹ | ☹ | ? | ☺ | ☹ | ☺ | ☺ |
Ciftci [31] * | ☹ | ☹ | ? | ? | ☹ | ☺ | ☺ |
Park [33] | ☹ | ☺ | ☺ | ☺ | ☹ | ☺ | ☺ |
Millan [34] * | ? | ☹ | ☺ | ? | ☺ | ☺ | ☺ |
Seo [35] | ☹ | ☹ | ☺ | ☹ | ☹ | ☺ | ☺ |
Chen [37] | ☹ | ☹ | ? | ☺ | ☹ | ☺ | ☺ |
Blydt-H. [41] | ☺ | ☺ | ☺ | ☺ | ☺ | ☺ | ☺ |
Belm.V. [42] * | ☹ | ☹ | ? | ☺ | ☹ | ☺ | ☺ |
Raza [43] | ☺ | ☹ | ☺ | ☹ | ☹ | ☺ | ☺ |
Galichon [44] | ☺ | ☹ | ? | ☺ | ☺ | ☺ | ☺ |
Sigdel [45] | ☺ | ☺ | ☺ | ☺ | ☺ | ☺ | ☺ |
A. Elaziz [48] | ? | ☹ | ☺ | ☺ | ☺ | ☺ | ☺ |
Lorenzen [49] | ☺ | ☹ | ☺ | ☺ | ☺ | ☺ | ☺ |
Rabant [50] * | ☺ | ☹ | ☺ | ☺ | ☺ | ☺ | ☺ |
Rabant [51] | ☺ | ☹ | ☺ | ☺ | ☺ | ☺ | ☺ |
Blydt-H. [52] | ☺ | ☹ | ☺ | ☹ | ☺ | ☺ | ☺ |
Ref. | Outcome (n) | Control Group (n) | Test Design, Biomarkers, Thresholds | Diagnostic Test Accuracy (95%CI) | ||||
---|---|---|---|---|---|---|---|---|
Sens. | Spec. | PPV | NPV | AUC–Accuracy(%) | ||||
Tinel [16] | TCMR (17), ABMR (64), mixed (14) | ALL-B (normal, 21; IFTA, 154; BKVN, 23; ATN, 11; recurrent disease, 9; other, 78) | CXCL9 + CXCL10 for AR | 62% | 72% | 41% | 86% | 0.70 (0.64–0.76) |
CXCL9 + CXCL10 for TCMR | 79% | 74% | 21% | 98% | 0.81 (0.73–0.89) | |||
CXCL9 + CXCL10 for ABMR | 72% | 54% | 28% | 88% | 0.67 (0.61–0.74) | |||
Yang [17] | TCMR + ABMR (103) | ALL-B (normal, 170; bAR, 50; | Training: AR vs normal (Q score ≥ 32) | 95% | 100% | - | - | 0.99 (0.99–1.00) |
BKVN, 9) | Validation 1: AR vs normal | 91% | 92% | - | - | 0.98 (0.96–1.00) | ||
Validation 2: AR vs normal | 100% | 96% | - | - | 1.00 (1.00–1.00) | |||
All AR vs All normal | 95% | 96% | 87% | 98% | 0.99(0.98–0.99) | |||
All AR vs ALL-B | - | - | - | - | 0.96 (0.94–0.98) | |||
Kalantari [18] | TCMR (7) | DYS-B (normal, 15) | Unbiased metab.1 | 67–71% | 40–100% | - | - | 0.51–0.71 |
Verma [19] | TCMR (22) | ALL-B (normal, 28) | 13-gene urinary cell signature | - | - | - | - | 0.92 (0.85–0.99) |
Goerlich [20] | TCMR (14) + ABMR (7) | DYS-B (normal, 18) | T cells + total TEC | - | - | - | - | 0.90 |
T cells + CD10+ TEC | - | - | - | - | 0.89 | |||
T cells + ECPAM+ TEC | - | - | - | - | 0.91 | |||
T cells + PDX+ cells | - | - | - | - | 0.89 | |||
Banas [21] | TCMR + ABMR + mixed | ALL-B (normal) + STA | Unbiased metab.2 | - | - | - | - | 0.75 (0.68–0.83) |
Score = 3.0 | 91% (79–98) | 34% (30–38) | - | - | - | |||
Score = 13.0 | 48% (33–63) | 89% (86–91) | - | - | - | |||
+ bAR | + (IFTA + other) | - | - | - | - | 0.71 (0.64–0.79) | ||
Tajima [22] | TCMR + ABMR (subclinical, 11) | STA-B (normal or borderline AR, 69) | LC3 (517.9 pg/mg) | 64% (31–89) | 78% (67–87) | 32% | 93% | 0.73 (0.55–0.90) |
CCL2 (226.0 pg/mg) | 82% (48–98) | 57% (44–68) | 23% | 95% | 0.69 (0.54–0.84) | |||
L-FABP (7.6 ng/mg) | 9% (0–41) | 88% (78–94) | 15% | 100% | 0.61 (0.45–0.77) | |||
NGAL (12.8 ng/mg) | 100% (72–100) | 48% (36–60) | 23% | 100% | 0.72 (0.59–0.84) | |||
HE4 (789.1 ng/mg) | 100% (72–100) | 54% (41–66) | 26% | 100% | 0.81 (0.70–0.92) | |||
Kolling [23] | TCMR (11; subclinical, 51) | STA-B (normal, 31) | hsa_circ_0001334 (2.41) | 70% (59–80) | 92% (64–100) | 98% | 32% | 0.85 (p < 0.0001) |
Sigdel [24] | TCMR + ABMR (45) | ALL-B (normal, 43; bAR, 19; BKVN, 43) | AR vs normal (uCRM score = 3.63) | 95% | 98% | - | - | 0.99, p < 0.0001 |
AR vs normal + bAR | 87% | 98% | - | - | - | |||
AR vs normal + bAR + BKVN | 77% | 98% | - | - | 96.6% | |||
Kim [25] | TCMR (14) | STA-B (normal, 17) | Unbiased metab.3 | - | - | - | - | - |
Training: TCMR (10) vs STA-B (13) | 90% | 85% | - | - | 0.93 (0.72–1.00) - 87% | |||
Validation: TCMR (4) vs STA-B (4) | - | - | - | - | 62.5% | |||
Banas [27] | TCMR | ALL-B (normal) + STA (extended) | Unbiased metab.2, train (180) | - | - | - | - | 0.76 (0.69–0.82) |
Test (178) strict/extended cohort | - | - | - | - | 0.72 (0.58–0.86)/ 0.74 (0.62–0.86) | |||
Lim [28] | TCMR (25) | STA-B (normal, 22) | TSPAN1 + HPX | 64% | 73% | - | - | 0.74 |
Chen [29] | TCMR (37) + ABMR (12) | ALL-B (normal, 58; CAN, 29; ATN, 10) | CXCL13 for AR vs. normal | 84% | 79% | - | - | 0.82 (0.73–0.90) |
CXCL13 for AR vs. CAN + ATN | - | - | - | - | 0.63 (0.52–0.75) | |||
Park [33] | TCMR (22) | DYS-B (normal, 22) | iKEA | |||||
Training: TCMR (15) vs normal (15) | 93% | 88% | - | - | 0.91 ± 0.02 - 90% | |||
Validation: TCMR (7) vs normal (7) | 64% | 100% | - | - | 0.84 ± 0.11 - 71% | |||
Seo [35] | TCMR (27) + ABMR (13) | STA-B (normal, 17); STA (22) | CTOT4 formula | - | - | - | - | 0.72 (0.60–0.83) |
CXCL10 mRNA | - | - | - | - | 0.72 (0.60–0.83) | |||
CD3ε mRNA | - | - | - | - | 0.71 (0.60–0.83) | |||
18S rRNA | - | - | - | - | 0.47 (0.33–0.60) | |||
Chen [37] | TCMR (37) + ABMR (12) | STA-B (normal, 58) | sTim-3 (1.836 ng/mmol) | 90% | 83% | - | - | 0.88 (0.81–0.95) |
Blydt-H. [41] | ABMR (10) | ALL-B (normal, TCMR, transplant glomerulopathy, IFTA, other, 49) | ABMR score = 0.23 | 78% | 83% | 40% | 96% | 0.84 (0.77–0.91) |
ABMR score with top 10 metabolites | - | - | - | - | 0.80 (0.73–0.88) | |||
Validation | - | - | - | - | 0.76 (0.67–0.84) | |||
Raza [43] | TCMR (acute, 101; borderline, 47; vascular, 17) | DYS-B (normal, 47; IFTA, 46) + STA (42) | CCL2 (198 pg/mL) | 87% | 62% | - | - | 0.81 (0.76–0.86) |
Galichon [44] | TCMR (11) + bAR (3) + ABMR (28) + mixed (9) | ALL-B (56) | CTOT4 formula | - | - | - | - | 0.72 (0.61–0.82) |
CXCL10 mRNA | - | - | - | - | 0.76 (0.66–0.86) | |||
CD3ε mRNA | - | - | - | - | 0.67 (0.56–0.78) | |||
18S rRNA | - | - | - | - | 0.63 (0.53–0.74) | |||
Sigdel [45] | TCMR + ABMR (42) | ALL-B (normal, 47; CAN, 46; BKVN, 16) | Unbiased proteomics (11 peptides) | |||||
Validation: AR (20) vs normal (27), CAN (15), BKVN (16) | - | - | - | - | 0.94 (0.93–0.95) | |||
A. Elaziz [48] | TCMR (31) | STA-B (normal, 23) | PD1 mRNA (2.6) | 80% | 84% | - | - | 0.81 |
FOXP3 mRNA (1.5) | 83% | 90% | - | - | 0.91 | |||
PD1 + FOXP3 mRNA | 94% | 97% | - | - | 0.98 | |||
Lorenzen [49] | TCMR (11; subclinical 51) | STA-B (normal, 31) | RNA L328 (9.556) | 49% | 96% | 49% | 93% | 0.76 (p < 0.001) |
Rabant [51] | TCMR (10) + ABMR (37) + mixed (31) | DYS-B (203) | CXCL9 | 58% | 85% | 59% | 84% | 0.71 (0.64–0.78) |
CXCL10 | 59% | 83% | 58% | 84% | 0.74 (0.68–0.80) | |||
Blydt-H. [52] | TCMR (subclinical, 17; clinical, 9) | ALL-B (normal, 21; IFTA, 31) | CXCL10, subclinical (4.82 ng/mL) | 59% | 67% | - | - | 0.81 (0.70–0.92) |
Clinical (4.72 ng/mL) | 77% | 60% | - | - | 0.88 (0.73–1.0) |
Ref. | Outcome (n) | Control Group (n) | Biomarkers, Thresholds and Time Post-Transplant | Diagnostic Test Accuracy (95%CI) | ||||
---|---|---|---|---|---|---|---|---|
Sens. | Spec. | PPV | NPV | AUC | ||||
Ciftci [26] | TCMR (9) + ABMR (6) | STA (70) | CXCL9, 1 day - 3 months | 70–85% | 37–88% | 60–71% | 71–90% | 0.71–0.95 |
CXCL10, 1 day - 3 months | 78–82% | 58–85% | 59–73% | 74–87% | 0.75–0.97 | |||
Ciftci [32] | AR (9) | STA (56) | TNF-α (12.08 pg/mL), 1 day | 71% | 57% | - | - | 0.74 (0.51–0.97) |
TNF-α (11.03), 7 days | 100% | 84% | - | - | 0.95 (0.88–1.00) | |||
TNF-α (9.85), 1 month | 100% | 83% | - | - | 0.91 (0.81–1.00) | |||
TNF-α (9.13), 3 months | 100% | 71% | - | - | 0.83 (0.75–0.98) | |||
TNF-α (7.42), 6 months | 100% | 62% | - | - | 0.82 (0.69–0.95) | |||
Millan [34] | TCMR (8) | STA (72) | miR-155-5p (0.51), 1wk-6m | 85% | 86% | 88% | 100% | 0.88 (0.78–0.97) |
CXCL10 (84.73 pg/mL),1wk-6m | 84% | 80% | 90% | 85% | 0.87 (0.81–0.92) | |||
CXCL10:Cr (0.43), 1wk-6m | 72% | 73% | 90% | 96% | 0.75 (0.67–0.83) | |||
Belm.V. [42] | ABMR (subclinical) | ALL-B | Albuminuria (> 30 mg/g), 6m | - | - | - | - | 0.75 (0.55–0.95) |
Rabant [50] | AR (TCMR + ABMR + mixed, 76) | ALL-B | CXCL9:Cr (1.78 ng/mmoL),10d | 61% | 50% | 24% | 84% | 0.58 (0.47–0.68) |
CXCL9:Cr (0.96), 1 month | 81% | 35% | 23% | 89% | 0.50 (0.37–0.62) | |||
CXCL9:Cr (1.67), 3 months | 57% | 62% | 18% | 91% | 0.57 (0.39–0.75) | |||
CXCL10:Cr (4.80), 10 days | 57% | 52% | 23% | 83% | 0.54 (0.43–0.65) | |||
CXCL10:Cr (2.79), 1 month | 83% | 51% | 29% | 93% | 0.72 (0.61–0.80) | |||
CXCL10:Cr (5.32), 3 months | 54% | 77% | 25% | 92% | 0.68 (0.55–0.80) |
Ref. | Outcome (n) | Control Group (n) | Biomarkers, Thresholds and Main Results |
---|---|---|---|
Barabadi [30] | AR (27) | ALL-B (normal, 45; CAN, 19) | FOXP3 mRNA expression was significantly higher in AR (p < 0.001) |
Mockler [31] * | TCMR (5; borderline, 3) | STA-B | There was no significant association between 6 months post-transplant CCL2 and TCMR changes (p = 0.46) |
Gandolfini [36] | TCMR (22) | ALL-B (normal, 19) | CXCL9 > 200 pg/mL in TCMR, 100-200 in dysfunction graft, and < 100 pg/mL in stable graft (p < 0.01) |
Domenico [38] | AR (23) | ALL-B (ATN, 18; normal, 8) | mirRNA 142-3p was significantly higher in AR compared to stable graft (p < 0.001); not compared to ATN (p = 0.079) |
Lee [39] | AR (8) | STA (8); DYS-B (ATN, 8; other, 4) | Donor-derived cfDNA was not significantly different between groups (p = 0.95) |
Seeman [40] | TCMR (2) + ABMR (2) | DYS-B (11) | NGAL was not significantly different between groups (p = 0.48) |
Garcìa-C. [46] | AR (9) | ALL-B (fibrosis, 31; other, 10) | IL10 and IFNγ were not significantly different between groups (p = 0.95, p = 0.1) |
Ho [47] | TCMR (17; subclinical, 17) | ALL-B (normal, 22) | MMP7 and CXCL10 were significantly elevated in subclinical (p = 0.01, p < 0.0001) and clinical (p < 0.001) TCMR |
Sigdel [53] | AR (10) | DYS-B (IFTA, BKVN, 20) | Ten urinary exosomal proteins were significantly increased in AR (p < 0.05) |
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Guzzi, F.; Cirillo, L.; Buti, E.; Becherucci, F.; Errichiello, C.; Roperto, R.M.; Hunter, J.P.; Romagnani, P. Urinary Biomarkers for Diagnosis and Prediction of Acute Kidney Allograft Rejection: A Systematic Review. Int. J. Mol. Sci. 2020, 21, 6889. https://doi.org/10.3390/ijms21186889
Guzzi F, Cirillo L, Buti E, Becherucci F, Errichiello C, Roperto RM, Hunter JP, Romagnani P. Urinary Biomarkers for Diagnosis and Prediction of Acute Kidney Allograft Rejection: A Systematic Review. International Journal of Molecular Sciences. 2020; 21(18):6889. https://doi.org/10.3390/ijms21186889
Chicago/Turabian StyleGuzzi, Francesco, Luigi Cirillo, Elisa Buti, Francesca Becherucci, Carmela Errichiello, Rosa Maria Roperto, James P. Hunter, and Paola Romagnani. 2020. "Urinary Biomarkers for Diagnosis and Prediction of Acute Kidney Allograft Rejection: A Systematic Review" International Journal of Molecular Sciences 21, no. 18: 6889. https://doi.org/10.3390/ijms21186889
APA StyleGuzzi, F., Cirillo, L., Buti, E., Becherucci, F., Errichiello, C., Roperto, R. M., Hunter, J. P., & Romagnani, P. (2020). Urinary Biomarkers for Diagnosis and Prediction of Acute Kidney Allograft Rejection: A Systematic Review. International Journal of Molecular Sciences, 21(18), 6889. https://doi.org/10.3390/ijms21186889