Impact of neohepatic albumin-bilirubin scores on renal outcomes following living donor liver transplantation: a propensity score analysis

Jeong, Hye-Won; Kwon, Hye-Mee; Kim, Sung-Hoon; Yang, Seong-Mi; Jun, In-Gu; Song, Jun-Gol; Hwang, Gyu-Sam

doi:10.1016/j.aohep.2025.102111

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Table 1. Perioperative characteristics of the study population before and after propensity score matching.

Table 2. Multivariate logistic regression analysis for severe acute kidney injury after living donor liver transplantation.

Table 3. Renal outcomes of the study population before and after propensity score matching.

Table 4. Predictive value of neohepatic Albumin-Bilirubin score ≥ −1.615 for renal and graft outcomes after living donor liver transplantation.

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Keywords:

Acute kidney injury

Albumin-bilirubin score

Chronic kidney disease

Living donor liver transplantation

Abbreviations:

ABOi

AKI

ALBI

BMI

CI

CKD

CNI

CTP

DDLT

EAD

GFR

HCC

HR

IQR

KDIGO

LC

LDLT

LT

MELD

MELD-Na

OR

PRBC

PRS

PSM

PT-INR

ROC

RRT

sCr

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1Introduction

Acute kidney injury (AKI) is a frequent and critical complication of liver transplantation (LT) [1,2]. Post-LT AKI has been consistently associated with adverse post-transplant outcomes, including chronic kidney disease (CKD) and decreased patient and graft survival rates [1–4]. Consequently, identifying and mitigating risk factors for renal function deterioration are critical to improve postoperative outcomes in LT recipients.

The Albumin-Bilirubin (ALBI) score, initially developed to evaluate liver function and predict outcomes in patients with hepatocellular carcinoma (HCC) [5], has had its application extended to encompass a wide range of chronic liver diseases [6–10]. Compared with the Child-Pugh-Turcotte (CTP) score or Model for End-Stage Liver Disease (MELD) score, the ALBI score is objective and can detect smaller changes in liver dysfunction [11]. Regarding chronic liver disease, numerous publications have demonstrated that the ALBI score is highly prognostic in patients across all types and stages of chronic liver disease [6–10].

According to recent research, a higher pre-transplant ALBI score has also been shown to be associated with adverse post-transplant complications and decreased survival rates in patients undergoing LT [12–15]. As the function of the transplanted liver graft is crucial for determining the prognosis of LT recipients [11], we focused on post-reperfusion (neohepatic) ALBI scores. Therefore, this study aimed to investigate the association between neohepatic ALBI scores and post-LT renal outcomes in living donor LT (LDLT) recipients. We hypothesized that higher neohepatic ALBI scores could adversely affect renal outcomes following LDLT.

2Patients and Methods2.1Patients

We reviewed electronic medical records of patients who underwent LT at our center from January 2012 to December 2019. The study included adults (≥18 years) who underwent LDLT. Exclusion criteria were preoperative serum creatinine (sCr) level >1.4 mg/dL, diagnosis of CKD or hepatorenal syndrome, or hemodialysis at baseline.

2.2Clinical data

Data, including demographic information, donor characteristics, perioperative laboratory results, intraoperative details, and postoperative outcomes, were collected from the electronic medical records system. Collected demographics included age, sex, body mass index (BMI), comorbidities like diabetes mellitus, hypertension, coronary artery disease, and congestive heart failure, liver disease details (etiology of liver cirrhosis [LC], MELD sodium [MELD-Na] score, and CTP score), and compatibility issues such as dual donor grafts and ABO incompatibility (ABOi). Donor-related variables included donor age, sex, and total fatty change. Preoperative laboratory data included albumin, total bilirubin, creatinine, prothrombin time–international normalized ratio (PT-INR), and sodium. Intraoperative data included post-reperfusion syndrome (PRS), volume and type of fluids (crystalloid and colloid), massive transfusion, vasopressor use, anesthetic time, cold ischemic time, warm ischemic time, total ischemic time, graft-to-recipient weight ratio, intraoperative embolization, and biopump use. PRS was defined as a decrease in mean arterial pressure by more than 30 % compared to the pre-reperfusion level, persisting for at least 1 min within the initial 5 min following liver graft reperfusion [16]. Massive transfusion was defined as the transfusion of ≥10 packed red blood cell (PRBC) units within 24 h, or ≥4 PRBC units within 1 hour [17]. Intraoperative laboratory values, including albumin and bilirubin were measured at the preanhepatic phase (1 h after skin incision), anhepatic phase (30 min after liver removal), and neohepatic phase (1 h after graft reperfusion), as per our standard protocol for LT patients. The ALBI score was calculated using the formula: (log10bilirubin × 0.66) + (albumin × −0.085), where bilirubin is measured in μmol/L and albumin in g/L [5].

2.3Anesthetic technique

Standard monitoring, as recommended by the American Society of Anesthesiologists, was applied before the induction of anesthesia. Anesthetic management and patient care for LT were carried out according to our institutional protocol, as described previously [18–20]. Anesthesia was induced with thiopental sodium, fentanyl, and rocuronium. General anesthesia was maintained with volatile anesthetics (sevoflurane or desflurane) combined with a continuous infusion of fentanyl and rocuronium or vecuronium. Radial and femoral artery cannulation was performed intraoperatively for continuous arterial monitoring and central venous catheter was inserted into the internal jugular vein for fluid infusion. A Swan-Ganz catheter was inserted via a 9Fr introducer sheath to monitor pulmonary arterial pressure and cardiac output. Intraoperative volume replacement involved a ratio of 1 L of crystalloid (Plasma solution A; CJ Pharmaceutical, Seoul, Korea) to 100–200 mL of 20 % human albumin (Green Cross Co., Yong-In, Korea), aimed at maintaining albumin levels above 3 mg/dL, as guided by intraoperative albumin measurements. Mean arterial blood pressure was maintained either above the preoperative level or at least 65 mmHg. Incremental doses of inotropes, vasopressors, and additional fluids were administered according to the patient’s hemodynamic status.

2.4Surgical technique

The native liver of the recipient was dissected to expose the inferior vena cava after separating the portal vein, hepatic artery, and bile duct. After removing the native liver, the donor graft was transplanted into the recipient. An end-to-end anastomosis between the right portal vein of the donor and the portal vein of the recipient was performed after completing the hepatic vein anastomosis. Graft reperfusion was performed after completing portal vein anastomosis. Patients with postreperfusion syndrome received norepinephrine or epinephrine depending on the severity. A continuous infusion of norepinephrine was commenced to achieve a target mean arterial pressure above 70 % of the baseline. Sequential anastomosis of the hepatic artery and bile duct was performed after graft reperfusion. Postoperatively, the recipients were transferred to the intensive care unit without extubation. Detailed surgical procedures for LDLT have been described in previous studies [19]. The same type of immunosuppression protocol was used in all cases, which was comprised of tacrolimus and mycophenolate mofetil (500 mg twice daily) as the primary immunosuppressive agents after LDLT [20].

2.5Outcomes

The primary outcome of this study was severe AKI (≥stage 2), defined by the Kidney Disease: Improving Global Outcome (KDIGO) criteria [21]. AKI diagnosis was based on an increase in sCr level by ≥0.3 mg/dL within 48 h postoperatively or an increase in sCr level to ≥1.5 times the baseline value within 7 days postoperatively; as per our routine protocol for LDLT recipients, baseline sCr levels were measured the day before transplantation [22]. According to the KDIGO criteria, stage 1 AKI was defined as an increase in sCr level to 1.5–1.9 times the baseline level or by an increase in sCr level of ≥0.3 mg/dL. Stage 2 AKI was indicated by an increase in sCr level to 2.0–2.9 times the baseline level, whereas stage 3 AKI was defined as an increase in sCr level to 3.0 times the baseline level, an increase in sCr level to ≥4.0 mg/dL, or initiation of renal replacement therapy (RRT). Secondary outcomes included need for postoperative RRT, CKD, early allograft dysfunction (EAD), and overall graft failure. CKD was defined as a decrease in glomerular filtration rate (GFR) (<60 mL/min per 1.73 m2) persisting for more than 3 months at 1 year after LT [23]. EAD was defined by the presence of one or both of the following variables: bilirubin >10 mg/dL or PT (INR) >1.6 on postoperative day 7 [24]. Graft failure was defined as the necessity for re-transplantation or death, determined through medical records and the Organ Transplantation registry of our center.

2.6Statistical analysis

Continuous variables are presented as means ± standard deviation or medians with interquartile ranges (IQR) and categorical variables as frequencies and percentages. Receiver operating characteristic (ROC) curves were used to determine the optimal neohepatic ALBI cutoff for predicting severe AKI. Patients were stratified based on this cutoff, and group comparisons were performed using the Student's t-test, Mann-Whitney U test, Chi-square test, or Fisher's exact test, as appropriate. Propensity score matching (PSM) was employed to balance baseline characteristics, with logistic regression used to calculate the propensity scores. Model discrimination was evaluated using C statistics (C-statistics = 0.858), and calibration was assessed using Hosmer-Lemeshow statistics (P = 0.109). Factors associated with severe AKI, postoperative RRT, CKD, and EAD were identified using multivariate logistic regression analysis. In addition, factors associated with overall graft failure were identified using multivariate Cox proportional hazards regression analysis. The level of statistical significance was established at a p-value <0.05. Data analyses were performed using SPSS version 22.0 (IBM Corp., Armonk, NY, USA) and R version 3.5.1 (R Foundation for Statistical Computing, Vienna, Austria).

2.7Ethical statements

The Institutional Review Board of our center approved this study (protocol number: 2023–0561) and waived the requirement for informed consent due to its retrospective design.

3Results

This study included 2171 adult recipients of LDLT, with a median follow-up time of 6.6 years (IQR: 4.8–8.7 years) (Fig. 1). ROC curve analysis identified the optimal cutoff value of neohepatic ALBI for predicting severe AKI as −1.615, exhibiting a sensitivity of 0.701, specificity of 0.616, positive predictive value of 0.335, and negative predictive value of 0.882. The area under the ROC curve was 0.700 (95 % confidence interval [CI]: 0.674–0.726; P < 0.001) (Fig. 2). Based on this optimal cutoff value, the 2171 patients were stratified into two groups. Table 1 details the preoperative and intraoperative data of the study participants. Individuals with a higher ALBI score exhibited a lower incidence of hypertension but a higher prevalence of congestive heart failure and higher MELD-Na and CTP scores. Preoperatively, they had prolonged PT (INR), higher total bilirubin levels, and lower albumin, creatinine, and sodium levels. Their donors had a higher degree of fatty change in the liver tissue. In addition, these individuals had a higher incidence of dual donor LT and massive transfusions during LT. They experienced longer cold ischemic time, warm ischemic time, total ischemic time, and anesthesia duration, in addition to a higher graft-to-recipient weight ratio and a higher incidence of biopump use.

Fig. 1.

Flowchart of the study population.

Abbreviations: LT, liver transplantation; OLT, orthotopic liver transplantation; sCr, serum creatinine; LDLT, living donor liver transplantation; ALBI, Albumin-Bilirubin.

Fig. 2.

Receiver operating characteristic curve analysis of the neohepatic (post-reperfusion) Albumin-Bilirubin score for predicting severe acute kidney injury.

Abbreviations: ALBI, Albumin-Bilirubin; AUC, Area under the curve.

Table 1.

Perioperative characteristics of the study population before and after propensity score matching.

	Unmatched (n = 2171)				Propensity score matched(n = 1004)
	Total (n = 2171)	Neohepatic ALBI < −1.615(n = 1189)	Neohepatic ALBI ≥ −1.615(n = 982)	SMD	Neohepatic ALBI < −1.615(n = 502)	Neohepatic ALBI ≥ −1.615(n = 502)	SMD
Demographic variables
Age (years)	54.0 ± 8.4	54.3 ± 8.3	53.8 ± 8.6	0.059	54.3 ± 8.5	54.6 ± 8.1	0.036
Sex, male	1627 (74.9)	913 (76.8)	714 (72.7)	0.094	372 (74.1)	377 (75.1)	0.023
Body mass index (kg/m2)	24.5 ± 3.5	24.5 ± 3.4	24.4 ± 3.6	0.036	24.5 ± 3.7	24.4 ± 3.6	0.019
Diabetes mellitus	522 (24.0)	289 (24.3)	233 (23.7)	0.014	125 (24.9)	120 (23.9)	0.023
Hypertension	397 (18.3)	262 (22.0)	135 (13.8)	0.218	78 (15.5)	79 (15.7)	0.005
Coronary arterial disease	207 (9.5)	110 (9.3)	97 (9.9)	0.021	40 (8.0)	43 (8.6)	0.022
Congestive heart failure	152 (7.0)	60 (5.1)	92 (9.4)	0.168	31 (6.2)	42 (8.4)	0.084
Etiology				0.313			0.026
Hepatitis B virus	1296 (59.7)	787 (66.2)	509 (51.8)		288 (57.4)	283 (56.4)
Hepatitis C virus	150 (6.9)	76 (6.4)	74 (7.5)		37 (7.4)	38 (7.6)
Alcoholic	441 (20.3)	185 (15.6)	256 (26.1)		111 (22.1)	116 (23.1)
Other disease	284 (13.1)	141 (11.9)	143 (14.6)		66 (13.2)	65 (13.0)
MELD-Na score	13.0 ± 6.2	10.3 ± 4.3	16.3 ± 6.5	1.071	13.1 ± 5.2	13.1 ± 5.2	0.002
Child-Pugh-Turcotte score	7.6 ± 2.0	6.7 ± 1.6	8.6 ± 1.9	1.104	7.7 ± 1.8	7.7 ± 1.7	<0.001
Dual donor grafts	162 (7.5)	71 (6.0)	91 (9.3)	0.124	37 (7.4)	41 (8.2)	0.030
ABO incompatibility	512 (23.6)	300 (25.2)	212 (21.6)	0.086	127 (25.3)	121 (24.1)	0.028
Donor-related variables
Age (years)	28.6 ± 8.3	28.6 ± 8.4	28.5 ± 8.3	0.008	28.6 ± 8.5	28.6 ± 8.2	0.005
Sex, male	1466 (67.5)	780 (65.6)	686 (69.9)	0.091	350 (69.7)	351 (69.9)	0.004
Total fatty change ( %)	3.8 ± 6.7	3.3 ± 6.0	4.3 ± 7.4	0.148	4.0 ± 7.3	3.8 ± 6.7	0.038
Preoperative laboratory variables
Albumin (g/dL)	3.1 ± 0.6	3.3 ± 0.5	3.0 ± 0.6	0.593	3.1 ± 0.5	3.0 ± 0.5	0.133
Total bilirubin (mg/dL)	3.3 ± 5.7	1.6 ± 2.9	5.2 ± 7.3	0.648	2.8 ± 4.2	3.0 ± 5.0	0.043
Creatinine (mg/dL)	0.8 ± 0.2	0.8 ± 0.2	0.7 ± 0.2	0.183	0.7 ± 0.2	0.7 ± 0.2	0.077
Prothrombin time (INR)	1.4 ± 0.4	1.3 ± 0.3	1.6 ± 0.4	0.785	1.4 ± 0.5	1.4 ± 0.3	0.038
Sodium (mmol/L)	138.7 ± 4.6	139.9 ± 3.4	137.3 ± 5.5	0.568	139.0 ± 4.1	138.5 ± 4.9	0.106
Intraoperative variables
Post-reperfusion syndrome	1402 (64.6)	769 (64.7)	633 (64.5)	0.005	322 (64.1)	324 (64.5)	0.008
Albumin (L)	3.7 ± 3.3	3.6 ± 3.4	3.9 ± 3.2	0.088	4.2 ± 2.5	4.0 ± 3.7	0.061
Massive transfusion	672 (31.0)	208 (17.5)	464 (47.3)	0.671	168 (33.5)	173 (34.5)	0.021
Vasopressor use	1878 (86.5)	1040 (87.5)	838 (85.3)	0.062	439 (87.5)	437 (87.1)	0.012
Anesthetic time (h)	13.8 ± 2.3	13.2 ± 2.0	14.6 ± 2.4	0.641	14.0 ± 2.1	14.0 ± 2.2	0.001
Cold ischemic time (min)	85.7 ± 26.5	83.9 ± 26.1	87.9 ± 26.9	0.150	86.4 ± 26.0	86.9 ± 26.0	0.019
Warm ischemic time (min)	42.0 ± 16.0	41.1 ± 16.1	43.1 ± 15.7	0.127	42.6 ± 15.2	42.9 ± 16.0	0.016
Total ischemic time (min)	127.7 ± 32.4	125.0 ± 31.8	131.0 ± 32.9	0.185	128.9 ± 31.7	129.7 ± 32.6	0.023
Graft-to-recipient weight ratio	1.1 ± 0.2	1.1 ± 0.2	1.1 ± 0.3	0.173	1.1 ± 0.2	1.1 ± 0.2	0.017
Intraoperative embolization	359 (16.5)	193 (16.2)	166 (16.9)	0.018	101 (20.1)	92 (18.3)	0.046
Biopump use	276 (12.7)	112 (9.4)	164 (16.7)	0.217	58 (11.6)	79 (15.7)	0.122

Values are expressed as mean ± standard deviation, median (interquartile range), or number of patients (%), as appropriate. Abbreviations: ALBI, Albumin-Bilirubin score; SMD, standardized mean difference; MELD-Na score, Model for End-Stage Liver Disease sodium score; INR, international normalized ratio.

Among the 2171 LDLT recipients, 21.6 % (n = 469) developed severe AKI, and 2.2 % (n = 48) required postoperative RRT. Meanwhile, 72 of the 2171 patients lacked follow-up data on GFR. Among the remaining 2099 recipients, 41.9 % (n = 879) developed CKD. The incidences of EAD and overall graft failure were 5.9 % (n = 127) and 15.8 % (n = 292), respectively. A significant difference was noted in the incidence of severe AKI between the two groups (33.5 % in the higher ALBI group vs. 11.8 % in the lower ALBI group, P < 0.001) (Table 3).

Table 1 also presents preoperative and intraoperative characteristics of PSM patients (1:1 matched set, n = 1004; n = 502 in the low ALBI group and n = 502 in the high ALBI group). After PS matching, individuals with a higher ALBI score exhibited lower preoperative levels of albumin and sodium. Additionally, they had a higher frequency of intraoperative biopump use. The incidence of severe AKI was 29.9 % (n = 150) in the higher ALBI group compared with the 16.3 % (n = 82) in the lower ALBI group (P < 0.001) (Table 3).

Univariate logistic regression analysis linked a higher ALBI score with an increased risk of severe AKI (odds ratio [OR]: 3.78, 95 % CI: 3.03–4.71, P < 0.001), a finding that remained significant after adjusting for AKI-related variables (OR: 2.34, 95 % CI: 1.79–3.04, P < 0.001) as shown in Table 2. Additionally, female sex, higher BMI and CTP score, alcoholic liver disease, and longer anesthetic time were significantly associated with severe AKI. In the PSM analysis, a higher ALBI score was significantly associated with severe AKI (OR: 2.18, 95 % CI: 1.62–2.95, P < 0.001), as indicated in Table 4.

Table 2.

Multivariate logistic regression analysis for severe acute kidney injury after living donor liver transplantation.

	Univariate				Multivariate
	OR	95 % CI		P-value	OR	95 % CI		P-value
Neohepatic ALBI ≥ −1.615	3.78	3.03	4.71	<0.001	2.34	1.79	3.04	<0.001
Age (years)	0.99	0.98	1.00	0.035	0.99	0.98	1.00	0.157
Sex, male	0.68	0.54	0.85	0.001	0.67	0.52	0.87	0.003
Body mass index (kg/m2)	1.10	1.07	1.13	<0.001	1.11	1.07	1.14	<0.001
Diabetes mellitus	1.10	0.87	1.39	0.447
Hypertension	0.97	0.74	1.26	0.812
Coronary arterial disease	1.11	0.79	1.56	0.560
Etiology
Hepatitis B virus	1			<0.001	1			0.189
Hepatitis C virus	1.76	1.20	2.59	0.004	1.26	0.83	1.93	0.281
Alcoholic	1.92	1.49	2.46	<0.001	1.36	1.02	1.81	0.036
Other disease	1.59	1.18	2.15	0.003	1.09	0.77	1.54	0.618
MELD-Na score	1.09	1.07	1.10	<0.001
Child-Pugh-Turcotte score	1.34	1.27	1.40	<0.001	1.18	1.11	1.26	<0.001
Dual donor grafts	1.92	1.36	2.71	<0.001	0.84	0.53	1.35	0.471
ABO incompatibility	0.93	0.73	1.19	0.571
Donor Age (years)	1.01	0.99	1.02	0.385
Donor Sex, male	1.02	0.82	1.27	0.885
Donor total fatty change ( %)	1.01	0.99	1.02	0.380
Post-reperfusion syndrome	0.97	0.78	1.20	0.754
Albumin (L)	1.06	1.02	1.09	0.001	1.00	0.96	1.04	0.975
Massive transfusion	2.25	1.83	2.78	<0.001	1.04	0.79	1.37	0.802
Vasopressor use	1.29	0.94	1.77	0.117
Anesthetic time (h)	1.22	1.17	1.27	<0.001	1.14	1.07	1.21	<0.001
Cold ischemic time (h)	1.00	1.00	1.01	0.481
Warm ischemic time (h)	1.01	1.00	1.02	0.005	1.00	0.99	1.01	0.880
Graft-to-recipient weight ratio	0.84	0.54	1.29	0.416
Intraoperative embolization	1.05	0.80	1.38	0.731
Biopump use	1.82	1.38	2.40	<0.001

Abbreviations: OR, odds ratio; CI, confidence interval; ALBI, Albumin-Bilirubin score; MELD-Na score, Model for End-Stage Liver Disease sodium score.

Furthermore, the group with higher ALBI scores exhibited significantly greater incidences of post-RRT (4.3 % vs. 0.5 %, P < 0.001), CKD (45.2 % vs. 39.2 %, P = 0.006), EAD (9.5 % vs. 2.9 %, P < 0.001), and overall graft failure (18.2 % vs. 13.0 %, P = 0.021) (Tables 3 and 4). After PS matching, the higher ALBI score group still showed significantly higher incidences of post-RRT (2.8 % vs. 0.4 %, P = 0.003), CKD (46.9 % vs. 38.2 %, P = 0.007), and overall graft failure (16.8 % vs. 10.6 %, P = 0.019). Higher ALBI was significantly associated with post-RRT (OR: 3.80, 95 % CI: 1.53–11.31, P = 0.008, multivariate analysis; OR 7.17, 95 % CI 1.61–31.89, P = 0.010, PSM analysis), CKD (OR: 1.22, 95 % CI: 1.00–1.47, P = 0.044, multivariate analysis; OR: 1.43, 95 % CI: 1.11–1.85, P = 0.006, PSM analysis), and overall graft failure (hazard ratio [HR]: 1.30, 95 % CI: 1.01–1.68, P = 0.041, multivariate analysis; HR: 1.55, 95 % CI: 1.08–2.23, P = 0.018, PSM analysis) (Table 4).

Table 3.

Renal outcomes of the study population before and after propensity score matching.

	Unmatched (n = 2171)			Propensity score matched(n = 1004)
	Neohepatic ALBI < −1.615(n = 1189)	Neohepatic ALBI ≥ −1.615(n = 982)	P-value	Neohepatic ALBI < −1.615(n = 502)	Neohepatic ALBI ≥ −1.615(n = 502)	P-value
Acute kidney injury	626 (52.7)	729 (74.2)	<0.001	301 (60.0)	352 (70.1)	<0.001
Acute kidney injury stage (1/2/3)			<0.001			<0.001
Stage 1	486 (40.9)	400 (40.7)		219 (43.6)	202 (40.2)
Stage 2	115 (9.7)	260 (26.5)		65 (13.0)	131 (26.1)
Stage 3	25 (2.1)	69 (7.0)		17 (3.4)	19 (3.8)
Severe acute kidney injury	140 (11.8)	329 (33.5)	<0.001	82 (16.3)	150 (29.9)	<0.001
Post-renal replacement therapy	6 (0.5)	42 (4.3)	<0.001	2 (0.4)	14 (2.8)	0.003
Chronic kidney disease (unmatched, n = 2099, matched, n = 973)	454 (39.2)	425 (45.2)	0.006	186 (38.2)	228 (46.9)	0.007

Abbreviation: ALBI, Albumin-Bilirubin score.

Table 4.

Predictive value of neohepatic Albumin-Bilirubin score ≥ −1.615 for renal and graft outcomes after living donor liver transplantation.

		Crude				Multivariable adjusteda			Propensity score-matched
		Event/n	OR	95 % CI	P-value	OR	95 % CI	P-value	Event/n	OR	95 % CI	P-value
Severe acute kidney injury	Neohepatic ALBI ≥ −1.615	329/982	3.78	3.03–4.71	<0.001	2.34	1.79–3.04	<0.001	150/502	2.18	1.62–2.95	<0.001
	Neohepatic ALBI < −1.615	140/1189	1			1			82/502	1
Postoperative renal replacement therapy	Neohepatic ALBI ≥ −1.615	42/982	8.81	4.03–23.18	<0.001	3.80	1.53–11.31	0.008	14/502	7.17	1.61–31.89	0.010
	Neohepatic ALBI < −1.615	6/1189	1			1			2/502	1
Chronic kidney disease	Neohepatic ALBI ≥ −1.615	425/940	1.24	1.05–1.47	0.013	1.22	1.00–1.47	0.044	228/486	1.43	1.11–1.85	0.006
	Neohepatic ALBI < −1.615	454/1159	1			1			186/487	1
Early allograft dysfunction	Neohepatic ALBI ≥ −1.615	93/982	3.55	2.38–5.31	<0.001	1.48	0.92–2.37	0.109	30/502	1.39	0.79–2.47	0.256
	Neohepatic ALBI < −1.615	34/1189	1			1			22/502	1
		Event/n	HR	95 % CI	P-value	HR	95 % CI	P-value	Event/n	HR	95 % CI	P-value
Overall graft failure	Neohepatic ALBI ≥ −1.615	156/982	1.31	1.04–1.65	0.021	1.30	1.01–1.68	0.041	74/502	1.55	1.08–2.23	0.018
	Neohepatic ALBI < −1.615	136/1189	1			1			47/502	1

a

Adjusted by all variables in Table 2. Abbreviations: ALBI, Albumin-Bilirubin score; OR, odds ratio; CI, confidence interval; HR, hazard ratio.

4Discussion

In this large retrospective study of LDLT recipients, a high neohepatic ALBI score (≥−1.615) was independently associated with post-LT AKI, need for RRT, CKD, and overall graft failure. Even after PS matching to adjust for important preoperative and intraoperative confounders, high neohepatic ALBI scores were significantly associated with post-LT AKI, RRT, CKD, and overall graft failure.

Previous research on the impact of pre-transplant ALBI scores on post-transplant AKI has yielded inconsistent results. A retrospective study of deceased donor LT (DDLT) recipients associated high preoperative ALBI scores (>−1.48) with an increased incidence of postoperative AKI [12]. In contrast, a study focusing on LDLT recipients reported no significant difference in renal failure rates among different ALBI grades [14]. These investigations, primarily focusing on pre-transplant ALBI scores, relied on Pearson's chi-square test without adjustments for potential confounders. However, post-LT renal outcomes are significantly influenced by multiple factors, including not only preoperative status of LT recipients, which can be partially indicated by their preoperative ALBI scores, but also functionality of the transplanted graft and various perioperative factors. In our study, we selected the ALBI scores measured 1 h after graft reperfusion to reflect both the status of the recipient and the functionality of the transplanted graft, thereby enabling early detection of postoperative AKI. Additionally, we accounted for important preoperative and intraoperative confounders using multivariate logistic regression and PSM analyses. This approach enabled a clearer elucidation of the association between neohepatic ALBI scores and post-LT renal outcomes such as AKI, RRT, and CKD.

The relationship between the ALBI score and AKI has also been investigated beyond LT, including in patients with HCC and those undergoing non-liver-related interventions or surgeries. In a retrospective study of patients undergoing platinum-based transcatheter arterial chemoembolization or transarterial infusion chemotherapy for HCC, high ALBI grades (II and III) were identified as independent risk factors for an increase in sCr level [25]. Furthermore, in the context of cardiac surgery, patients with high ALBI scores (>−2.44) had a greater incidence of postoperative AKI following cardiac valvular surgery [26]. Additionally, a large study of individuals with coronary artery disease found the ALBI score to be an independent predictor of contrast-associated AKI after elective percutaneous coronary intervention, demonstrating a linear relationship between ALBI scores and the risk of developing this condition [27]. These findings underscore the ALBI score's utility as a predictor of renal outcomes not only in liver disease patients but also in broader clinical scenarios.

A high post-reperfusion ALBI score, marked by low levels of albumin and high levels of bilirubin, may be causally associated with the development of postoperative AKI in LDLT recipients. Albumin improves renal perfusion and glomerular filtration through prolonged potent renal vasodilation, a result of its reaction with oxides of nitrogen to form S-nitroso-albumin [28]. Additionally, albumin inhibits apoptosis of renal tubular cells by scavenging reactive oxygen species and transporting protective lysophosphatidic acid [29,30], while also stimulating renal tubular cell DNA synthesis [31]. Concurrently, an excess of bilirubin negatively impacts renal function through direct bile and bilirubin toxicity, as well as tubular obstruction [32,33]. Thus, the combined effects of hypoalbuminemia and hyperbilirubinemia may compromise tubular integrity and function, contributing to the development of postoperative AKI in LDLT recipients.

As demonstrated in previous literature, we propose that AKI led to an increased risk of RRT and CKD in our patients [2,34,35]. In addition, the ALBI score has been established as a sensitive marker of liver dysfunction with strong prognostic value in patients with chronic liver disease [5–11]. We suggest that this score may also serve as a surrogate marker of early graft function in the post-reperfusion period. Suboptimal graft function may initiate a cascade of adverse physiological processes, including persistent systemic inflammation, impaired immunosuppressant metabolism, hyperbilirubinemia, and deleterious hepatorenal interactions [33,36–38], collectively increasing the risk of CKD.

Further, our findings underscore the impact of neohepatic ALBI on overall graft failure in LDLT recipients. These findings are consistent with results of previous studies investigating the relationship between pre-transplant ALBI scores and post-transplant graft function. Specifically, a higher preoperative ALBI grade (grade III) and ALBI scores (≥−1.28) were associated with increased risks of EAD and graft dysfunction after LT, respectively [13,14]. Compared to previous studies, our study included advanced statistical analyses to adjust for confounding variables, thereby more robustly validating the association between neohepatic ALBI scores and EAD or graft failure. We demonstrated that high neohepatic ALBI scores are associated with overall graft failure, both in multivariate Cox proportional hazards regression and PSM analyses.

The significance of our study lies in its findings of the prognostic value of the ALBI score in LDLT recipients, who typically have relatively lower CTP and MELD scores than DDLT recipients. The ALBI score, due to its sensitivity in detecting minor changes in liver function that could not be discerned through the CTP score [11], has proven to be more effective in predicting outcomes in LDLT [13,14]. Our multivariate analysis supported these findings, demonstrating that only the ALBI score, but not MELD-Na score, was independently associated with post-LT AKI. In addition, compared to previous studies that used higher pre-transplant ALBI cutoffs (>−1.48 for AKI [12], >−1.39 for EAD [14], and ≥−1.28 for graft dysfunction [13]), our study employed a lower cutoff value (≥−1.615) for the neohepatic ALBI score. This lower cutoff demonstrates enhanced sensitivity in identifying patients at risk for poor postoperative outcomes. Moreover, our study found that neohepatic ALBI was an independent risk factor for AKI and critical long-term outcomes such as CKD and graft failure. Hence, our study contributes to the expanding evidence supporting the prognostic value of the ALBI score in LDLT recipients.

A high neohepatic ALBI score (≥−1.615) may enable early identification of high-risk patients, guiding targeted perioperative management to improve outcomes. In our practice, patients with elevated scores undergo intensified monitoring of renal function (e.g., serial measurements of serum creatinine and estimated GFR) and prompt evaluation of persistent hyperbilirubinemia to assess early graft dysfunction or biliary complications. Fluid balance is optimized to maintain hemodynamic stability, avoiding both hypotension and fluid overload, which can impair renal perfusion or cause renal congestion, respectively [39]. Blood products, crystalloids, albumin, vasopressors, or inotropes are used as needed to achieve this balance. Immunosuppressive regimens, particularly tacrolimus dosing, are carefully adjusted to minimize nephrotoxicity, especially in patients with high neohepatic ALBI scores. Strategies include delaying calcineurin inhibitor (CNI) initiation or reducing CNI exposure [40–42]. Additional measures include avoiding nephrotoxic medications and initiating early nephrology consultation [39,40]. By facilitating these individualized interventions, the neohepatic ALBI score enhances intraoperative and postoperative care in high-risk patients, potentially reducing the incidence of short- and long-term complications.

Post-LT AKI has been reported to be associated with female sex, higher BMI, alcoholic LC, higher CTP scores, and longer anesthetic time [2,43]. Therefore, the results of our multivariate analysis align with these previously established associations, emphasizing the importance of these factors in contributing to the incidence of post-LT AKI.

In this study, the neohepatic ALBI score was measured 1 h after portal vein reperfusion, before hepatic arterial reperfusion, as LDLT involves portal vein anastomosis followed by hepatic artery and bile duct anastomoses. Consequently, the score reflects early graft function under portal venous flow, capturing the initial response to reperfusion, potentially influenced by ischemia-reperfusion injury and recipient status. While hepatic arterial reperfusion, which occurs later, is critical for long-term graft function, the prognostic value of the neohepatic ALBI score lies in its ability to assess graft performance in the early post-reperfusion period, which may predict subsequent renal and graft outcomes. Future studies could explore the prognostic value of the ALBI score measured after arterial reperfusion, to evaluate the combined effects of portal and hepatic arterial flows.

Our study has some limitations. First, its retrospective nature may inherently introduce bias and confounding factors. However, we used rigorous statistical methods, including multivariate and PSM analyses, to address this limitation. Second, as the research was conducted at a single, highly specialized medical center renowned for its extensive experience in LT [19], the outcomes, including the rates of AKI and graft failure, might not be representative of other institutions with different levels of expertise or patient populations. This necessitates cautious interpretation when generalizing our findings beyond the studied cohort. Lastly, our study's cutoff points for the ALBI score in predicting AKI, derived from ROC curve analyses, were based on data from a population of a single ethnicity at a single medical center. These cutoff values may require adjustment when applied to other ethnic groups. Therefore, to validate our findings, further research involving diverse patient populations across various ethnicities is needed.

5Conclusions

Our study demonstrates that neohepatic ALBI scores are significantly associated with postoperative AKI, the need for RRT, CKD, and overall graft failure in LDLT recipients. These findings highlight the critical prognostic value of neohepatic ALBI scores in predicting renal and graft outcomes following LDLT.

Funding

This research was supported by a grant from the Korea Health Technology R&D Project through the Korea Health Industry Development Institute (KHIDI), funded by the Ministry of Health & Welfare, Republic of Korea (grant number: HR20C0026), and was also supported by grants (2023IE0008 and 2023IP0134) from the Asan Institute for Life Sciences, Asan Medical Center, Seoul, Korea.

Author contributions

Name: Hye-Won Jeong, M.D.; Contribution: This author helped in Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Project administration, Resources, Software, Supervision, Validation, Visualization, and Writing - original draft and revision; Name: Hye-Mee Kwon, M.D., Ph.D.; Contribution: This author helped in Data curation and Formal analysis; Name: Sung-Hoon Kim, M.D., Ph.D.; Contribution: This author helped in Data curation and Formal analysis; Name: Seong-Mi Yang, M.D.; Contribution: This author helped in Data curation and Formal analysis; Name: In-Gu Jun, M.D.; Contribution: This author helped in Data curation and Formal analysis; Name: Jun-Gol Song, M.D., Ph.D.; Contribution: This author helped in Conceptualization, Data curation, Formal analysis, Funding acquisition, Investigation, Methodology, Project administration, Resources, Software, Supervision, Validation, Visualization, and Writing - original draft and revision; Name: Gyu-Sam Hwang, M.D., Ph.D.; Contribution: This author helped in Conceptualization, Resources and Supervision.

Data availability statement

The datasets generated during and/or analysed during the current study are available from the corresponding author on reasonable request.

Declaration of interests

None.

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