• OPEN ACCESS

Assessing Donor Liver Quality and Restoring Graft Function in the Era of Extended Criteria Donors

  • Yimou Lin1,
  • Haitao Huang1,
  • Lifeng Chen2,
  • Ruihan Chen1,
  • Jimin Liu3,
  • Shusen Zheng1,4 and
  • Qi Ling1,4,* 
 Author information
Journal of Clinical and Translational Hepatology 2023;11(1):219-230

DOI: 10.14218/JCTH.2022.00194

Abstract

Liver transplantation (LT) is the final treatment option for patients with end-stage liver disease. The increasing donor shortage results in the wide usage of grafts from extended criteria donors across the world. Using such grafts is associated with the elevated incidences of post-transplant complications including initial nonfunction and ischemic biliary tract diseases, which significantly reduce recipient survival. Although several clinical factors have been demonstrated to impact donor liver quality, accurate, comprehensive, and effective assessment systems to guide decision-making for organ usage, restoration or discard are lacking. In addition, the development of biochemical technologies and bioinformatic analysis in recent years helps us better understand graft injury during the perioperative period and find potential ways to restore graft function. Moreover, such advances reveal the molecular profiles of grafts or perfusate that are susceptible to poor graft function and provide insight into finding novel biomarkers for graft quality assessment. Focusing on donors and grafts, we updated potential biomarkers in donor blood, liver tissue, or perfusates that predict graft quality following LT, and summarized strategies for restoring graft function in the era of extended criteria donors. In this review, we also discuss the advantages and drawbacks of these potential biomarkers and offer suggestions for future research.

Keywords

Liver transplantation, Extended criteria donors, Graft quality, Assessment, Biomarkers, Restoration

Introduction

Liver transplantation (LT) is a life-saving treatment option for patients with end-stage liver disease. In recent decades, good short- and long-term outcomes after LT have been achieved because of improvements in surgical technologies and organ preservation.1 Graft quality is believed to play a dominant role in early graft function and thereby dramatically influences graft survival and mortality after LT.2–4 Over the last decade, the disparity between the need for LT and the organ shortage is widening, which leads to the expanded usage of grafts from the extended criteria donors (ECDs).1 Traditionally, ECDs are donors with underlying medical diseases such as diabetes, or hypertension, advanced age, high-degree liver steatosis, prolonged ischemia time, pathogenic infection, prolonged intensive care unit stay, hypernatremia, and donation after circulatory death (DCD).5–7 ECD graft quality is routinely considered inferior because of their increased rate of post-transplant complications, such as primary graft nonfunction (PNF),2 early allograft dysfunction (EAD),4 and ischemic-type biliary lesions (ITBLs)8,9

PNF is early graft loss after LT and requires emergency regrafting, which occurs following 2–10% of LTs.10–12 ECDs include DCD donors13 and those with severe steatosis,14 prolonged ischemia time,15–17 and high donor bilirubin level18 sharply increase the risk of PNF, thereby reducing patient and graft survival. Unlike PNF, EAD represents marginal, usually reversible, graft function during the first postoperative week, and results in a higher morbidity and mortality.4 Compared with 1–10% seen in donation after brain death (DBD) LT, the incidence of biliary complications after DCD LT is approximately 10–30%,19–22 in which the time from asystole to cross-clamp is considered as a major risk factor.23 Moreover, advanced donor age, prolonged ischemia time, microvascular thrombosis, bile salt toxicity and immune injury may be the underlying mechanisms of the development of biliary complications.24,25

Therefore, ECDs should be well defined and precisely allocated to appropriate recipients. More importantly, in the era of ECD, effective systems need to be established to assess donor liver quality and guide the decision for organ usage or discard. Based on clinical risk parameters (Fig. 1), models like donor risk index,2 Eurotransplant donor risk index,26 and discard risk index18 were constructed to evaluate the risk of graft failure or discard, serving as useful tools to make decisions for organ allocation.2,26 However, those scoring models mainly focus on donor characteristics and cannot assess the degree of liver injury.27 Furthermore, combining clinical parameters with advanced molecular profiles, imaging, or histopathology may contribute to the development of better systems. In recent years, with the rapid development of multi-omics, single cell technology, and bioinformatic analysis, significant achievements have been made in revealing the molecular profiles that are closely related to poor graft outcomes, and which can provide novel biomarkers for evaluation of graft viability.

Clinical factors that influence graft quality during the entire process of liver transplantation.
Fig. 1  Clinical factors that influence graft quality during the entire process of liver transplantation.

Herein, we provide a review of potentially useful biomarkers in donor blood, liver tissue, and graft perfusate, which have been associated with impaired graft quality or predictive for the occurrence of EAD, PNF, and biliary complications after LT. In this review, we mainly focus on studies using human liver grafts. Given that the available biomarkers were insufficient in the field of LT, we also include experimental studies that have been performed in animal models. Furthermore, we summarize potential therapies for graft repairment during LT. Finally, we describe the pros and cons of the potential biomarkers, accompanied with suggestions for future graft assessment and restoration.

Potential biomarkers in donor blood

Donor serum alanine transferase (ALT), aspartate transferase (AST), total bilirubin, gamma glutamyl transpeptidase, and sodium concentration may reveal the underlying liver dysfunction and ischemic injury prior to graft procurement. Over the past decades, numerous studies have demonstrated that such laboratory disorders in donor blood are independent risk factors for early graft dysfunction following LT.18,26,28 In recent years, novel biomarkers in donor blood have been found to useful for predicting graft outcomes. By analyzing data from over 10,000 nondiabetic donors, Ezekian et al.29 showed that elevated donor serum hemoglobin A1c (HbA1c) >6.5% was associated with increased rate of PNF and decreased graft and patient survival. HbA1c is known to be a useful biomarker representing the average plasma glucose concentration within the last 3 months, serving as an early warning of diabetes. The liver undergoes glycogen deposition and hepatic steatosis resulting from diabetes.30,31 Therefore, it is worth noting that HbA1c may be a valuable marker for further stratifying marginal graft quality. In a large prospective study of 815 participants, Piemonti et al.32 identified increased serum donor interleukin 6 (IL6) and C-X-C motif chemokine ligand 10 (CXCL10) concentration as predictors of poor early graft function, graft failure and inferior graft survival after DBD LT. IL6 is responsible for transforming naïve B cells into mature plasma cells, as well as activating the production of IL17 to inhibit regulatory T lymphocyte (Treg) function.32 Alternatively, CXCL10 is a useful chemoattractant for macrophages, natural killer (NK) cells and dendritic cells (DCs), thereby shaping initial immunity.32 More interestingly, Pollara et al.33 found that elevated circulating mitochondria-derived damage-associated molecular patterns (mtDAMPs) in donor plasma were associated with severe inflammation response and the development of EAD following DBD LT in a group of 55 recipients. The major source of mtDAMPs may be the mitochondria released from graft tissue or cell death during organ procurement, suggesting that mtDAMPs might quantitatively assess graft injury.

Potential biomarkers in donor grafts

The liver, a multifunctional organ in the body, is mainly engaged in metabolism, synthesis, storage, detoxification, and complex immune activities. After implantation, the donor graft becomes the new center of the recipient to perform those functions.34 Therefore, the graft features could significantly regulate hepatic homeostasis and influence outcomes after LT (Table 1).35–55 Donor grafts could be gained for histological assessment and quantification of liver injury during LT. Histopathology is the gold standard for the diagnosis of steatosis, fibrosis, necrosis, inflammation, and cellular infiltration in liver grafts. In our center, pretransplant, and post-reperfusion liver biopsies are routinely performed, offering valuable clues for graft quality assessment (Supplementary Table 1).56 In addition, bile duct biopsies could provide valuable information to evaluate bile duct injury and predict graft outcomes. Dries et al.57 proposed a scoring system (Supplementary Table 2), including biliary epithelium, mural stroma, peribiliary vascular plexus, thrombosis, intramural bleeding, peribiliary gland, and inflammation, to quantify bile duct injury.

Table 1

Biomarkers from donor livers potentially useful for the prediction of graft outcomes following transplantation

BiomarkerStudySampleModel(s)GroupKey point
Genetic variantHeme oxygenase-1 A/T-allele genotypeBuis et al. (2008)35Pretransplant biopsiesHuman LTA-allele genotype (n=245) vs. TT-genotype (n=61)Graft with TT-genotype had elevated serum transaminases after LT and a higher incidence of PNF
HLA-C2 alleleHanvesakul et al. (2008)36Pretransplant biopsiesHuman LT459 livers biopsiesDonor grafts with HLA-C2 allele were associated with less incidence of graft dysfunction
GcfDNALevitsky et al. (2021)37Recipient bloodHuman LTNormal function (n=94) vs. Acute dysfunction (n=68)Elevated GcfDNA represented early graft injury after LT
GcfDNASchutz et al. (2017)38Recipient bloodHuman LT/Elevated GcfDNA could predict early graft injury
RNANrf2 mRNAZaman et al. (2007)39Pretransplant biopsiesHuman LT14 donor liver biopsiesHigher Nrf2 mRNA expression before IRI were associated with lower liver injury
MICA mRNAResch et al. (2021)40Pretransplant biopsiesHuman LT88 liver biopsiesHigh expression of MICA mRNA could reduce graft injury
MiR-22Khorsandi et al. (2015)41Post-reperfusion biopsiesHuman DCD LTPNF (n=7) vs. non-PNF (n=7)Graft miR-22 was associated with PNF
MiR-146b-5pLi et al. (2017)421.5 hours after LTHuman LTEAD (n=22) vs. non-EAD (n=20)Graft miR-146b-5p was associated with EAD
MiR-103 and miR-181Ling et al. (2017)43Pretransplant biopsiesHuman LTNODM (n=15) vs. non-NODM (n=15)Graft miR-103 and miR-181 were significantly associated with the development of NODM
CircFOXN2 and circNEXTIN3Wang et al. (2021)44Pretransplant biopsiesHuman LTEAD (n=29) vs. non-EAD (n=86)Two circRNAs were associated with EAD
LncRNA LOC103692832Chen et al. (2019)4512 hours after LTRat DBD LT model/Graft lncRNA LOC103692832 was related to early graft injury
ProteinSirtuin 1Nakamura et al. (2017)462 hours after LTHuman LT51 liver biopsiesHigh graft Sirtuin 1 was associated with superior liver function
Heme oxygenase-1Nakamura et al. (2018)472 hours after LTHuman LT51 liver biopsiesEnhanced Sirtuin 1 expression and protected against IRI
YAPLiu et al. (2019)483 hours after LTHuman LT60 liver biopsiesImproved early liver function
FGF15Gulfo et al. (2020)49Post-reperfusion biopsiesRat DBD LT model/Low graft FGF15 was associated with more severe hepatic damage and inhibited regeneration
CEACAM1Nakamura et al. (2020)50Pretransplant biopsiesHuman LT60 liver biopsiesHepatic CEACAM1 could prevent early graft injury
Hepatic occult collagen depositionHirao et al. (2021)51Pretransplant biopsiesHuman LTLow level (n=140) vs. High level (n=54)Increased risks of severe IRI and EAD
MetaboliteLysophospholipids, bile acids, phospholipids, sphingomyelins, and histidine metabolism productsCortes et al. (2014)52Pretransplant biopsiesHuman LTEAD (n=48) vs. non-EAD (n=48)Predictors for EAD
Lactate and phosphocholineFaitot et al. (2018)53Pretransplant biopsiesHuman LTEAD (n=7) vs. non-EAD (n=35)Predictors for EAD
single cell RNA sequencingA pro-inflammatory phenotype of KCs and a subset of DCsYang et al. (2021)5424 hours after LTRat steatotic LT modelFatty graft (n=3) vs. Control graft (n=3)A pro-inflammatory phenotype of KCs that highly expressed colony-stimulating factor 3 and a subset of DCs with high expression of XCR1 were enriched in the steatotic grafts
A dynamic transcription profileWang et al. (2021)55Grafts gained from preprocurement, at the end of organ preservation and 2 h after reperfusionHuman DBD LTn=1Showed a dynamic transcription profile of intrahepatic cells during LT

Genetic variants

With the advent of genome-wide association studies and pretransplant genetic analysis, a series of genes and variants have been found to be susceptible to graft injury.58 Heme oxygenase-1 (HO-1), a regulator of immune response, is considered to be cytoprotective gene of ischemia-reperfusion injury (IRI) during LT and is modulated by a single-nucleotide polymorphism A (-413) T.35 Buis et al.35 reported that, compared with recipients of a liver with an A-allele genotype (n=245), recipients of livers with an HO-1 TT-genotype (n=61) had dramatically elevated serum hepatic transaminases after LT and a higher incidence of PNF. HLA-C, which is the major inhibitory ligand for immunoglobulin-like receptors, inhibit the cytotoxic activity of NK cells, and therefore reduced liver inflammatory damage.59 In a large LT cohort of 459 patients, Hanvesakul et al.36 found that donor grafts with at least one HLA-C2 allele were associated with less incidence of graft dysfunction and rejection.

After LT, graft-derived cell-free DNA (GcfDNA), which is continuously released into recipient circulation because of cellular turnover, is a promising noninvasive biomarker to assess graft quality. Previous studies have showed that the elevated GcfDNA was a signal of early graft injury after LT, particularly acute cellular rejection.37,60,61,38 For example, a prospective study conducted by Schutz et al.38 demonstrated that GcfDNA increased by more than 50% 1 day following LT, probably because of the IRI. However, GcfDNA rapidly decreased to a median of <10% within 7–10 days without the recipient experiencing early graft injury over a 1 year observation period.38 This suggested that GcfDNA may be a precise and superior biomarker to predict early graft dysfunction compared with conventional liver function tests.

RNAs

Protein-coding associated RNAs, for example messenger RNA (mRNA) and noncoding RNAs including microRNAs (miRNAs), circular RNAs (circRNAs) and long noncoding RNAs (lncRNAs) are believed to be reliable markers to evaluate graft injury because of their organ specificity. Nrf2 transcription factor, which is activated by reactive oxygen species, is known to protector against liver IRI via activating phase II antioxidants.62 Zaman et al.39 demonstrated that grafts (n=6) with increased Nrf2 mRNA expression before IRI were associated with lower liver injury. Interestingly, donors with low Nrf2 mRNA levels (n=8) were significantly older than those with high levels, suggesting that older grafts experienced severe IRI39 and inferior graft quality. Additionally, Resch et al.40 reported that high gene expression of the major histocompatibility complex class 1 related chain A (MICA) mRNA in zero hour biopsies (n=88) was associated with mild graft injury and prolonged graft survival. During LT, MICA had an important role in linking the innate and adaptive immune responses via interacting with NK cells, mucosal-associated invariant T, CD8+T cells, et al.40 miR-22, a regulator of a series of pathways such as cell cycle, metabolism and kinase signaling, is relevant to cell survival, glucose metabolism, and protein translation.41 Khorsandi et al.41 rereported that low expression of graft miR-22 was associated with the incidence of PNF after DCD LT (n=21). Another study of 42 human LTs showed that high expression of donor graft miR-146b-5p was associated with the development of EAD.42 Downregulation of miR-146b increased the production of tumor necrosis factor receptor-associated factor 6, which activated the nuclear factor-kappa B (NF-κB) pathway, and in turn enhanced Treg function.42,63 In our previous study, we found that elevated donor graft miR-103 and miR-181 were significantly associated with the development of new-onset diabetes mellitus (NODM) in recipients following LT (n=30).43 NODM not only increased the risk of biliary stricture and cholangitis but also resulted in poor graft survival, serving as an indicator of poor graft quality as well.64 The two miRNAs targeted several genes related to glucose homeostasis and insulin signal transduction, which may have been the underlying mechanism.43

In a cohort of 115 human LTs, Wang et al.44 reported that low levels of donor graft circFOXN2 and circNEXTIN3 that regulated miR-135b-5p and miR-149-5p and had roles in hepatic IRI were associated with the incidence of EAD. In a mice model of IRI (Qu et al.65 identified 13 differentially expressed circRNAs (e.g., Chr3:83031528|83031748, Chr10:89473752|89483524) in postperfusion livers that were involved in more severe IRI in steatotic livers. In a rat LT model, Chen et al.45 demonstrated that lncRNA LOC103692832 in rat grafts was related to early graft injury following LT that was mediated by the expression of apoptosis-related genes like HMOX1 and ATF3. Nevertheless, the mechanisms of these potentially involved circRNAs and lncRNAs are still unclear, and further prospective or multicenter studies with larger samples are needed to verify the results.

Proteins

Sirtuin1, a histone/protein deacetylase that regulates inflammatory responses, cellular aging, and stress resistance, has an important role in autophagy induction involved in liver IRI.66 A previous study showed that high Sirtuin1 expression in grafts post-reperfusion sharply inhibited proinflammatory cytokine levels accompanied by superior liver function and improved patient survival.46 HO-1 is a rate-limiting enzyme that converts heme to biliverdin, free iron, carbon monoxide, and has anti-inflammatory and anti-oxidative activitiy.47 In addition, Nakamura et al.47 showed that high HO-1 levels in post-reperfusion liver biopsies (n=51) were associated with good liver function, dramatically enhanced Sirtuin1/LC3B expression, and protected against hepatic IRI by inducing autophagy. Notch1, a highly conserved transmembrane receptor, has been shown to reduce cellular apoptosis or necrosis and inflammatory response.55 Kageyama et al.44 demonstrated high Notch1 expression in grafts was correlated with low serum ALT levels, consistent with alleviated liver damage. In addition, Liu et al.48 found that high graft YAP expression after LT was linked with well-preserved histopathology and improved liver function at 1–7 days following LT. YAP is an effector of Hippo pathway and regulates cell proliferation and apoptosis and maintains hepatic homeostasis. FGF15, which is secreted from the ileum following inflammatory stimulation, binds to Fgfr4/Klb, which is followed by downregulation of CYP7A1 expression and inhibition of bile acid synthesis and activation of the Hippo pathway to upregulate YAP levels.49 In a rat DBD LT model, Gulfo et al.49 reported ed that low FGF15 levels in grafts was associated with more severe hepatic damage and inhibited regeneration that was mediated by increased CYP7A1 and decreased YAP levels.

The use of ECD grafts has raised the incidence of graft dysfunction, which ranges from reversible dysfunction, known as EAD, to irreversible dysfunction or PNF. Therefore, biomarkers to predict EAD and PNF are necessary in the era of ECD. CEACAM1 is a glycoprotein involved in hepatocyte differentiation and regeneration and regulation of insulin clearance, serving as a bridge between hepatic injury and metabolic homeostasis.50 Low CEACAM1 expression in human donor liver biopsies (n=60) was recognized as an independent predictor of EAD.50 In a large study cohort (n=194), Hirao et al.51 found that liver grafts with high occult collagen deposition were of increased risk of severe IRI and EAD, highlighting the effect of occult fibrosis on post-transplant outcome. In addition, Kurian et al.68 investigated several upregulated signaling pathways including NF-κB and targets such as CXCL1, IL1, TRAF6, TIPARP, TNFRSF1B, as predictors of EAD. Kornasiewicz et al.69 used graft proteomics to identify 21 significantly differentially expressed proteins in patients with (n=3) and without PNF (n=6). The proteins were mainly associated with mitochondrial oxidative phosphorylation or vital for the adenosine triphosphate-dependent turnover of proteins.

Metabolites

Cortes et al.52 used metabolomic profiling of 124 graft biopsies to identify significantly increased lysophospholipids, bile acids, phospholipids, sphingomyelins, and histidine metabolism products that were predictors for EAD. Based on the metabolic features, an EAD predictive model was established and further determined in a validation set (n=24) to have 91% sensitivity and 82% specificity. Likewise, Faitot et al.53 reported that lactate concentrations >8.3 mmol/g and phosphocholine concentrations >0.646 mmol/g were significantly associated with EAD. In our previous study, we identified metabolic profiles containing 57 dramatically differentially expressed metabolic features that were enriched in 24 common pathways including fatty acid, alanine, aspartate, thiamine, and riboflavin metabolism, the urea cycle, and ammonia recycling in PNF grafts.28 Graft metabolites and clinical characteristics were combined to develop a PNF predictive model derived from eight selected metabolic variations including achillicin, 3-hydroxypropanal, 3-oxododecanoic acid glycerides, and dopexamine in combination with clinical parameters including donor total bilirubin >2 ng/mL, graft weight >1.5 kg, cold ischemia time >10 h, graft warm ischemia time >60 m. The model had an area under curve of 0.930 for predicting PNF.28

Single cell technology

Recent advances in single cell RNA sequencing (scRNA-Seq) allow investigation of the transcriptomic landscape of single cells in organisms and have increased our understanding of the heterogeneity and relevance between cells. In a rat LT model, Yang et al.54 identified 11 kinds of cells in grafts and drew a single cell map of IRI after steatotic LT by scRNA-Seq. More importantly, they found a pro-inflammatory phenotype of Kupffer cells (KCs) that highly expressed colony-stimulating factor 3 and a subset of DCs with high expression of XCR1 that were enriched in steatotic grafts, suggesting their participation in fatty graft IRI.54 In addition, Wang et al.55 described a dynamic transcription profile of intrahepatic cells during LT by performing scRNA-Seq of grafts at preprocurement, at the end of organ preservation, and 2 h after reperfusion. They also found that a cluster of KCs that highly expressed TNFAIP3 interacting protein 3 after reperfusion, protected grafts against liver IRI.55 We believe that as research on scRNA-Seq deepens, it may provide a deeper understanding of mechanisms related to liver IRI during LT, identify grafts at increased risk of IRI and develop strategies to protect organ against liver damage. In a study published on BioRxiv, we established a graft-tolerant mouse LT model and identified two stages of graft recovery, which included an acute and stable phases.70 We also found that the interaction between CD206+MerTK+ macrophages and CD49a+CD49b NK cells regulated metabolic and immune remodeling of the graft.70

Potential biomarkers in perfusate

The donor graft and perfusate keep interplaying during preservation. Molecules including nucleic acids, proteins, and metabolites in perfusate may be associated with graft outcomes. In a review by Verhoeven et al.71 in 2014, ALT, AST, lactate dehydrogenase, lactate, adenine nucleotide level, hyaluronic acid, thrombomodulin and inflammatory markers (e.g., hypoxia-inducible factor-1α, and tumor necrosis factor-α) in perfusate and perfusate pH were useful biomarkers to assess graft quality. Machine perfusion (MP) such as hypothermic machine perfusion (HMP), hypothermic oxygenated perfusion (HOPE), and normothermic machine perfusion (NMP) continuously inject the perfusion fluid into the graft blood vessels to form a circuit, mitigating IRI and maintaining cellular metabolism in graft.72 So far, a series of current and ongoing clinical trials have shown that they were superior in reducing ischemic complications compared with static cold storage (SCS).73–76 In addition, the development of detection technology and MP have facilitated the discovery of a series of novel perfusate biomarkers for graft viability evaluation and are summarized as below and in Table 2.5,77–83

Table 2

Potential biomarkers of graft function that are found in graft perfusates

BiomarkerStudyModelGroupKey point
Bile productionPavel et al. (2019)77NMP5 discarded human DCD liversEarlier production of bile and higher bile flows during NMP were linked to better bile duct histology
Biliary bicarbonate, pH, and glucoseMatton et al. (2019)78NMP23 human donor liversHigh biliary bicarbonate and pH and low glucose were associated with bile duct injury
Bile/perfusate glucose ratio and bile/ perfusate Na+ ratioLinares-Cervantes et al. (2019)5A porcine DCD LT model; NMP/Bile/perfusate glucose ratio≤0.7 and bile/ perfusate Na+ ratio ≥1.1 were correlated with successful LT
CDmiRsVerhoeven et al. (2013)79Human LT; SCSGrafts developed ITBL (n=20) vs. Grafts without biliary strictures (n=37)CDmiRs could be predictive of bile duct injury and ITBL
miR-122Selten et al. (2017)80Human DCD/DBD LT; SCSEAD (n=35) vs. non-EAD (n=48)High miR-122 level could predict EAD
FMNMuller et al. (2019)81Human DCD/DBD LT; HOPE53 donor liversHigh FMN level could predict severe graft dysfunction following LT
D-dimerKarangwa et al. (2017)82NMP12 discarded human liversHigh D-dimer level was associated with graft damage
NGA2FVerhelst et al. (2018)83Human DCD/DBD LT; SCSPNF (n=3) vs. non-PNF (n=63)Increased NGA2F level could predict PNF

Bile production and bile composition (e.g., bile glucose and Na+) during NMP are useful biomarkers for graft synthesis function. Pavel et al.77 restored five discarded DCD livers with NMP for 12 h and found that earlier production of bile and higher bile flows during NMP contributed to better bile duct histology. In addition, Matton et al.78 showed that high biliary bicarbonate and pH, and low biliary glucose in human liver grafts (n=23) during NMP were significantly associated with high risk of bile duct injury. In a porcine LT model, Linares-Cervantes et al.5 demonstrated that a bile/perfusate glucose ratio ≤0.7 and a bile/perfusate Na+ ratio ≥1.1 within 4 h of NMP predicted graft survival after LT. Given that the role of donor graft miRNAs in predicting post-transplant outcomes, perfusate miRNAs may serve similarly. Furthermore, miRNAs have been shown to be stable in perfusate for at least 1 day.79 Verhoeven et al.79 showed that cholangiocyte-derived miRNAs (CDmiRs) in perfusate were predictive of bile duct injury and the development of ITBL. They also found that a significantly elevated hepatocyte-derived miRNA to CDmiRs ratio was associated with the incidence of ITBL. Moreover, Selten et al.80 reported that both high miR-122 levels and a high miR-122/miR-222 ratio in SCS perfusate predicted the development of EAD and poor graft survival after LT in 83 recipients.

Flavin mononucleotide (FMN), a critical molecular of generating electrons for ubiquinone reduction in mitochondrial complex 1, was shown to be associated with mitochondrial injury.81 Muller et al.81 preserved 53 grafts with HOPE and demonstrated that a high perfusate FMN level after 30 m of HOPE was strongly linked to severe graft dysfunction. Wang et al.84 infused 23 DCD livers with normothermic regional perfusion and found that the levels of perfusate FMN in transplantable grafts (n=15) were dramatically lower than those in nontransplantable grafts (n=8). D-dimer, a product of fibrin degradation, is a small protein fragment released during fibrinolysis. Karangwa et al.82 preserved 12 discard donor livers with NMP and showed that D-dimer levels >3,500 ng/mL were significantly associated with graft liver injury, suggesting that it was predictive of poor graft function.

In a multicenter cohort study, Verhelst et al.83 compared the glycome patterns in SCS perfusate in PNF (n=3) and non-PNF (n=63) groups and found that increased NGA2F, a single under galactosylated biantennary glycan, predicted the development of PNF with 100% accuracy. That highlighted the essential role of omics, especially the metabolomics, in discovering potential perfusate markers of poor graft function during LT.

Potential strategies for restoring graft function

In recent years, in vivo and ex vivo potential protective interventions that have been used to restore graft function are listed in Table 3.85–102 During the process of ex vivo therapies, the role of MP is apparent because it provides a platform for graft preconditioning.

Table 3

Potential therapies to restore donor liver function

TherapyStudyTargetModelOutcome
Gene therapyJiang et al. (2011)85Toll-like receptor 4 siRNAMice-IRI in vivoReduce liver IRI
Zhao et al. (2017)86High-mobility group box 1 siRNAMice-IRI in vivoReduce liver IRI
Gillooly et al. (2019)87siRNA against the Fas receptorRats HMP and NMPAbsorbed by rat donor livers during HMP and NMP
Goldaracena et al. (2017)88Antisense oligonucleotidePorcine LT NMPPrevent HCV replication or reinfection after LT
Cell therapyPeng et al. (2018)89DC+ apoptotic lymphocytesRat LT in vivoProlong rat survival
Sanchez-Fueyo A et al. (2020)90TregsHuman LT in vivoReduce antidonor T cell responses and play the potential role of graft rejection
Shi et al. (2017)91MSCsHuman LT in vivoSuppress acute rejection and improve graft histology
Verstegen et al. (2020)92MSCsPorcine LT HOPEAbsorbed by porcine grafts and continue to maintain paracrine activity after distribution
Extracellular vesiclesZheng et al. (2018)93EVs deprived from DCsRat IRI in vivoModulate differentiation of Tregs and protect liver against IRI
Chen et al. (2019)94EVs deprived from TregsRat LT in vivoProlong liver graft survival
Rigo et al. (2018)95EVs deprived from human liver stem cellsRats NMPAbsorbed by hepatocytes and reduce liver injury
Anti-inflammatory agentsGoldaracena et al. (2016)96Alprostadil, n-acetylcysteine, carbon monoxide, and sevofluranePorcine LT NMPReduce liver injury
Yu et al. (2019)97mcc950Porcine LT HMPReduce liver injury
VasodilatorsHara et al. (2016)98Prostaglandin E1Rat LT NMPReduce liver injury and improve bile production, energy status, and rat survival
Nassar et al. (2014)99Prostacyclin analog (epoprostenol)Porcine LT NMPHigh bile production and good histopathology
Echeverri et al. (2018)100Endothelin1 antagonist (BQ123), epoprostenol, verapamilPorcine LT NMPHigh hepatic artery flow and reduce hepatocyte injury
DefattingNagrath et al. (2009)101A cocktail*Rat NMPDecrease the intracellular lipid content of liver by 50% during 3 h perfusion
Boteon et al. (2019)102A cocktail* + L-carnitineHuman NMPDecrease liver triglycerides by 38% and macrosteatosis by 40% over 6 h perfusion

Gene therapy

Previous in vivo studies were performed to treat liver IRI by using small interfering RNA (siRNA). Jiang et al.85 silenced toll-like receptor 4, a critical mediator of inflammation, in a hepatic IRI mouse model, resulting is significant reduction of serum transferases and histological injury. In another study, Zhao et al.86 downregulated nuclear high-mobility group box 1 by transfecting mice with siRNA and found that it effectively inhibited the expression of serum inflammatory cytokines and protected the liver against IRI. Although the efficacy of hydrodynamic injection has been shown in these animal models, it is difficult to use in the clinic because of off-target effects. Recent studies of graft perfusates showed a potential to solve this problem. For example, Gillooly et al.87 found that Fas siRNA directly added to the perfusate was successfully delivered to rat livers during HMP and NMP. This technology ensured that the siRNA only targeted the grafts, opening a new door for graft reconditioning. Antisense oligonucleotide, another gene modulation agent, was demonstrated to significantly reduce miR-122 expression and inhibit hepatitis C virus replication or reinfection after LT in a porcine LT model with NMP, further confirming the possibility of ex vivo gene therapy in grafts.88

Cell therapy

In vivo cell therapies such as tolerogenic DCs, Tregs, and mesenchymal stem cells (MSCs) have a role in immunomodulation. In a rat LT model, we innovatively treated acute rejection with a combination of galectin-1-induced tolerogenic DCs and apoptotic lymphocytes, which resulted in prolonged survival of the treated rats, with 37.5% surviving over 100 days, compared with untreated, all of which died within 14 days.90 In a phase I clinical trial, Sanchez-Fueyo et al.90 demonstrated that autologous Tregs transfer was safe and effective in reducing antidonor T cell responses after LT by intravenously administering autologous Tregs to the LT candidates. In addition, Shi et al.91 found that human MSCs injection in LT recipients suppressed acute rejection and improved graft histology by upregulating the Treg/T help 17 cell ratio. Compared with in vivo treatment, ex vivo technology provides novel strategies for graft restoration. For instance, Verstegen et al.92 showed in a porcine LT model that MSCs directly added to the perfusate during HOPE were effectively distributed to the porcine grafts, which continued to maintain their paracrine activity after distribution.

Extracellular vesicles

It has been reported that the above tolerogenic cells had the potential to undergo spontaneous malignant transformation.103 Therefore, some investigators began to use MSC-, DC- and trig-derived extracellular vesicles (EVs) as alternatives to cell therapy. In in vivo mice and rat IRI models, MSC-derived EVs had a diverse set of functions including mitochondrial autophagy,104,105 inhibition of immune response106,107 and liver regeneration.108,109 Zheng et al.93 found in a rat IRI model that DC-derived EVs could protect liver against IRI through modulating differentiation of Tregs. In a rat LT model, Chen et al.94 demonstrated that injection with Tregs-derived EVs after LT suppressed the proliferation of CD8+ cytotoxic T cells and prolonged liver graft survival. Compared to the in vivo injection, the ex vivo technology has the potential to directly target donor grafts without concern for off-target effect. Rigo et al.95 successfully delivered human liver stem cells-derived EVs into the rat livers during NMP, leading to less histological damage and lower levels of AST and lactate dehydrogenase in the treated group.

Anti-inflammatory agents

Liver IRI is characterized by the activation of pro-inflammatory responses. Therefore, adding anti-inflammatory agents to perfusate may regulate immune response and alleviate graft damage. In a porcine LT model, Goldaracena et al.96 put alprostadil, n-acetylcysteine, carbon monoxide, and sevoflurane into the NMP perfusate, showing significantly decreased interleukin-6, tumor necrosis factor-α, and AST during NMP, and lower AST and bilirubin levels in serum after LT in the treated group.96 In addition, Yu et al.97 used Mcc950, which strongly inhibited the nucleotide-binding domain leucine-rich repeat containing family pyrin domain containing 3 inflammasome, as an addition to the HMP perfusate in a porcine LT model. They found that Mcc950 significantly reduced inflammatory cytokines and histological injury, and prolonged long-term survival after LT.

Vasodilators

During the ischemic phase of LT, rapid adenosine triphosphate depletion and lack of blood flow result in mitochondrial dysfunction and liver sinusoidal endothelial cell (LSEC) injury.110 After reperfusion, the injured LSECs not only produce insufficient vasodilators but also expressed P-selectin to accumulate platelets, which resulted in microcirculation disorder.110 In a rat LT model, Hara et al.98 inhibited the accumulation of platelets by adding prostaglandin E1 (PGE1) to the perfusate under normothermic conditions. PGE1 ameliorated serum liver enzymes and histologic necrosis, and significantly improved bile production and energy status. In addition, Nassar et al.99 added a prostacyclin analog (epoprostenol) to NMP perfusate to preserve porcine livers and found that the use of prostacyclin analog led to high bile production and good histopathology. Furthermore, Echeverri et al.100 compared the effects of endothelin1 antagonist (BQ123), prostacyclin analog (epoprostenol) and calcium channel antagonist (verapamil) to treat hepatic artery vasospasm induced by IRI in a porcine LT model. They demonstrated that grafts with BQ123 and verapamil treatment had higher hepatic artery flow and less hepatocyte injury compared with those treated with epoprostenol.

Defatting agents

Moderate to severe (>30%) macrosteatosis is a well-known risk factor for poor graft quality, making it necessary to defat prior to LT.14 Nagrath et al.101 treated rat fatty livers with a combination of six defatting agents normothermically and showed that the treatment could decrease the intracellular lipid content of rat liver by 50% after 3 h perfusion. Furthermore, Boteon et al.102 assessed the efficacy of the above six agents combined with additional L-carnitine in defatting human livers with severe steatosis. They found that this method reduced liver triglycerides and macrosteatosis by 38% and 40% over 6 h NMP, enhanced metabolic parameters including increased urea and bile production, and downregulated biomarkers of liver injury (e.g., lower ALT and reduced inflammatory cytokines).

Other agents

In addition to the above agents, human atrial natriuretic peptide (hANP), heavy water, marine worm super hemoglobin (M101), glycine, relaxin, and polyethylene glycols have been found to alleviate liver injury.111–116 Nigmet et al.111 added hANP, a protective cardiovascular hormone for vascular endothelia, to SCS perfusate to preserve rat livers, showing that hANP supplementation decreased transaminase release, increased bile production, and protected sinusoidal architecture. In a porcine LT model, Alix et al.113 added M101 to SCS perfusate and demonstrated that M101 significantly reduced blood levels of ALT, AST, and tumor necrosis factor α in recipients 3 days following LT. Moreover, Gassner et al.114 used glycine, a simple amino acid that protected sinusoidal cells and hepatocytes, as an addition to NMP rat liver perfusate. They found less sinusoidal dilatation and tissue damage in the treated group.

Conclusions and perspectives

This review summarized and updated biomarkers in donor blood, liver tissue or graft perfusate to evaluate early graft injury (e.g., EAD, and PNF) and ITBL, and to identify potential therapies for graft repairment during the era of ECD. We focused on studies using human liver grafts and investigations of potential biomarkers involved in anti- or pro-inflammatory processes, which in turn shape immunity, regulate graft IRI, and further influence the development of EAD, PNF, or ITBL following LT. Given that relevant mechanisms of some molecules are lacking, further prospective studies and experiments are urgently needed to clearly understand their roles.

Although various biomarkers with available prognostic and diagnostic value in graft quality assessment have been widely explored, few are currently used in clinical practice. Current challenges associated with biomarker discovery research are as follows. Firstly, the sample sizes of these studies were small and mainly limited to single centers, suggesting that large multicenter cohorts or prospective randomized clinical trials are greatly necessary. Another problem is that the studies lack standardized endpoints and control groups.117 Graft quality is commonly considered to be associated with early graft dysfunction or ITBL, yet other complications after LT (e.g., ACR, metabolic disorders, and graft steatosis or fibrosis) are still a matter of substantial debate. Therefore, we primarily summarized biomarkers predictive of EAD, PNF, and ITBL. Current studies mainly focus on finding biomarkers related to early graft injury, do not have prolonged follow-up and overlook long-term complications like ITBL. Importantly, the measurement of biomarkers should be rapid and easy and have high predictive specificity and sensitivity for graft quality. However, detection of potential biomarkers is costly and time consuming. Moreover, biomarkers need to be stable and measurable during graft procurement, preservation, and implantation.

Despite the availability of liver biopsies for histological assessment and quantification of liver injury during LT, they are invasive and only represent specific parts of the grafts. On the contrary, perfusates can be collected in large volumes and contain markers from the whole graft. In recent years, MP has constantly advanced, and it use in evaluation of graft viability has gradually increased. Nevertheless, different regions or centers have their own standards to determine graft quality.78,118 More clear international guidelines that could guide the decision for organ usage, discard, or restoration prior to LT are recommended. In addition, we believe that MP could provide a platform for graft preconditioning, making it convenient to explore novel strategies for graft repair. Although high cost and the technical complexity limit wide usage of MP at its current stage, recently completed and ongoing clinical trials will make it an indispensable part of LT.72,73

Supporting information

Supplementary Table 1

Histological scoring of hepatocellular damage.56

(DOCX)

Supplementary Table 2

Histological scoring system for assessing injury of the distal common bile duct.57

(DOCX)

Abbreviations

ACR: 

acute cellular rejection

ALT: 

alanine transferase

AST: 

aspartate transferase

circRNAs: 

circular RNAs

DBD: 

donation after brain death

DCD: 

donation after circulatory death

DCs: 

dendritic cells

EAD: 

early allograft dysfunction

ECD: 

extended criteria donor

EV: 

extracellular vesicle

FMN: 

flavin mononucleotide

GcfDNA: 

graft-derived cell-free DNA

HbA1c: 

hemoglobin A1c

HCV: 

hepatitis C virus

HMP: 

hypothermic machine perfusion

HO-1: 

Heme oxygenase-1

HOPE: 

hypothermic oxygenated perfusion

IRI: 

ischemia-reperfusion injury

ITBL: 

ischemic-type biliary lesion

KC: 

Kupffer cell

lncRNA: 

long noncoding RNA

LSEC: 

liver sinusoidal endothelial cell

LT: 

liver transplantation

MICA: 

major histocompatibility complex class 1 related chain A

miRNA: 

microRNA

MP: 

machine perfusion

mRNA: 

messenger RNA

MSC: 

mesenchymal stem cell

mtDAMP: 

mitochondria-derived damage-associated molecular pattern

NF-κB: 

nuclear factor-kappa B

NK: 

natural killer

NMP: 

normothermic machine perfusion

NODM: 

new-onset diabetes mellitus

PGE1: 

Prostaglandin E1

PNF: 

primary graft nonfunction

scRNA-Seq: 

single cell RNA sequencing

SCS: 

static cold storage

siRNA: 

small interfering RNA

Treg: 

regulatory T lymphocyte

Declarations

Funding

This article was funded by the National Natural Science Foundation of China (No. 82171757) and the Zhejiang Province Natural Science Foundation of China (No. LZ22H030004).

Conflict of interest

The authors have no conflict of interests related to this publication.

Authors’ contributions

Conceived of the paper (QL), wrote the original draft (YL), generated the figures (YL, HH), reviewed and edited the paper (QL, LC, RC, JL, SZ). All the authors agreed to the published version of the manuscript.

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