Functional assessment of liver regeneration after major hepatectomy.

Background: Liver regeneration is crucial to restore the functional liver mass after liver resection. The aim of this study was to evaluate the early postoperative changes in remnant liver function, volume and liver stiffness after major liver resection and their correlation with postoperative outcomes.
Methods: Patients undergoing major liver resection (≥3 segments) between February and November 2018 underwent both functional assessment using technetium-99m mebrofenin hepatobiliary scintigraphy (HBS) and CT-volumetry of the (future) remnant liver on preoperative day 1, the 5th postoperative day, and 4-6 weeks after resection. At the same time points, patients underwent transient elastography (TE) for the assessment of liver stiffness. Severe postoperative complications (Clavien-Dindo ≥ 3A) and mortality were correlated with the functional and volumetric increases of the remnant liver. Liver failure was graded according to the International Study Group of Liver Surgery (ISGLS) criteria.
Results: A total of 18 patients were included of whom 10 (56%) had severe complications and one patient (5%) developed liver failure. Function and volume of the remnant liver had increased by the 5th postoperative day from 6.9 (5.4-10.9) to 9.6 (6.7-13.8) %/min/m2, P=0.004 and from 795.5 (538.3-1,037.5) to 1,080.0 (854.0-1,283.3) mL, P<0.001, respectively. After 4-6 weeks, remnant liver volume had further increased [from 1,080.0 (854.0-1,283.3) to 1,222.0 (1,016.0-1,380.5) mL, P=0.035], however, liver function did not show any significant, further increase [from 9.6 (6.7-13.8) to 10.9 (8.8-13.6) %/min/m2, P=0.177]. Liver elasticity of the future remnant liver (FRL) increased [from 10.8 (5.7-18.7) to 17.5 (12.4-22.6) kPa, P=0.018] and gradually recovered after 4-6 weeks to a median of 10.9 (5.7-18.8) kPa (T3 vs. T4, P=0.079). Patients who had severe postoperative complications did not show a significant increase in liver function on the 5th postoperative day (P=0.203), despite increase of volume (P<0.01). Conclusions: Functional regeneration of the remnant liver predominantly occurs during the first 5 days after resection. In case of severe complications, functional regeneration is delayed, in contrast to volume increase. 2022 Hepatobiliary Surgery and Nutrition. All rights reserved.

Introduction

Posthepatectomy liver failure (PHLF) is a potentially lethal complication after major liver resection with an incidence around 7% in patients with healthy parenchyma and up to 30% in patients with liver cirrhosis (1,2). The current management is mostly supportive with a high mortality rate while PHLF is considered as the main cause of death after liver resection (3).

After hepatectomy, the remaining hepatocytes have to maintain liver function and at the same time undergo regeneration in order to restore the loss of liver mass. When this is out of balance, the risk of PHLF increases dramatically. PHLF is characterized, according to the criteria set by the International Study Group of Liver Surgery (ISGLS), by the impaired ability of the liver to maintain its function after the fifth postoperative day (4).

In order to minimize the risk of PHLF, pre-operative assessment of the remnant liver is essential. This assessment is traditionally performed using CT-volumetry, calculating the percentage of volume of the future remnant liver (FRL). However, liver function does not always correlate with liver volume and therefore, functional assessment is considered to be more reliable than volume alone in patients evaluated for major liver resection (5,6). Technecium-99m (99mTc)-mebrofenin hepatobiliary scintigraphy (HBS) is a quantitative functional test used to estimate global and segmental liver function as now routinely applied in several centers worldwide (7-9).

Additionally, liver stiffness measurements (LSM) are widely used in non-invasive assessment of liver fibrosis and are considered a safe alternative to liver biopsy (10). Besides fibrosis, liver stiffness is also influenced by factors like acute or chronic structural changes. It has been shown to correlate with parenchymal inflammation, bile outflow obstruction and complications related to portal hypertension and hepatic venous pressure gradient disorders (11-15). A recent study showed that LSM can be used to predict PHLF (16).

So far, no studies have been conducted that assess the postoperative changes in measured liver function or elasticity in relation to liver regeneration. Furthermore, there is a lack of data regarding the normal variation of liver function within a single patient; this information is crucial for patients undergoing serial HBS. Lastly, the role of LSM in the perioperative care of patients undergoing liver surgery has not been explored. The aim of this study was to evaluate the early postoperative changes in remnant liver function, volume and elasticity after major liver resection and its correlation with postoperative outcomes. This information can provide new insights that influence selection of candidates for liver resection, their postoperative monitoring and their management. We present the following article in accordance with the STROBE reporting checklist (available at https://hbsn.amegroups.com/article/view/10.21037/hbsn-20-866/rc).

Methods

Patients

All patients, aged 18 years or older, scheduled for major liver resection (resection of 3 or more Couinaud segments) were asked to participate in this single-center, prospective observational study.

Patients with bilirubin >50 µmol/L were not eligible for inclusion in the study since cholestasis impairs liver function testing using HBS due to competitive uptake between bilirubin and mebrofenin (17). These patients, all with perihilar tumors, only were included after successful preoperative biliary drainage. Furthermore, patients undergoing two-stage hepatectomy or Associating Liver Partition and Portal vein Ligation for Staged hepatectomy (ALPPS) in which regeneration takes places in two steps were also excluded in order to obtain a homogenous patient population. Other exclusion criteria were allergy to mebrofenin and pregnancy.

The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013). It was approved by the ethical review board of the Amsterdam University Medical Centers and registered under ID (No. NL63868.018.17). Informed consent was obtained from all individual participants included in the study. Patients were included between February and November 2018.

HBS and CT-volumetry

According to standard practice in our institution, all patients considered for major liver resection undergo preoperative HBS. This was repeated on the preoperative day of admission in order to examine the variation of liver function per patient and to determine the baseline value for further postoperative, measurements. HBS was repeated on postoperative day 5 to assess early regeneration and 4–6 weeks postoperatively during follow-up for assessment of the late functional recovery. HBS was acquired and processed as described previously (9).

Total liver function (TLF) is represented by the mebrofenin uptake rate (MUR; %/min). On the dynamic acquisitions, regions of interest (ROI) were drawn around the left ventricle (representing the blood pool), liver and total field of view. From these ROI’s, three time-activity curves were generated. MUR was calculated based on these parameters according to the formula described by Ekman et al. (18).

For preoperative HBS, the FRL were delineated on the SPECT datasets. Contrast-enhanced diagnostic CT-scans were assessed to assist in anatomical information using the same landmarks as for the volumetric studies. The ratio between the radioactivity counts on the FRL and the total liver represented the functional share of the FRL. This was the percentage of function attributed by the FRL and was multiplied with the TLF to calculate the FRL function.

Data on liver volume were obtained from the concomitant CT images obtained during HBS. The (future) remnant liver was outlined on an axial scan in a semi-automated fashion with manual adjustment to ensure that all extra-hepatic structures and tumors were excluded.

LSM

At the same time points as the HBS, patients underwent transient elastography (TE) for the assessment of liver stiffness. TE was performed with the Fibroscan® (Echosens, Paris, France) using the M- or XL-probe. The probe was positioned in the right midaxillary line, between the ninth to eleventh intercostal space for patients undergoing left sided resection, or just beneath the xyphoid for patients undergoing right sided resection. It was repeated at the same location for postoperative assessment (19).

A low-frequency shear wave (50 Hz), generated by a mechanical push, travels through the hepatic tissue where the velocity of wave propagation is measured. The wave velocity is proportional to tissue stiffness which is expressed in kilopascal (kPa).

The assessment was considered successful when at least 10 measurements were performed at the same location, the success rate was higher than 80% and when the interquartile range (IQR) did not exceed 30% of the median (20).

Outcomes

The primary outcome parameters were the changes in liver function and liver stiffness between baseline, postoperative day 5 and 4–6 weeks postoperatively in %/min.

Secondary outcomes were the correlation of the changes in liver function with baseline liver volume, morbidity and 90-day mortality. Severe postoperative morbidity was defined as any complication of Clavien-Dindo grade IIIa or higher within 30 days of surgery (21). PHLF was defined and graded according to ISGLS criteria. PHLF grade B or C were considered clinically relevant (22).

Statistical analysis

Continuous data are expressed as median and IQR. Discrete variables are expressed as absolute numbers and relative frequencies. Differences in non-parametric data were tested using the Wilcoxon signed rank test for paired data or the Mann-Whitney U test for unpaired data. A two-sided P value less than 0.05 was considered statistically significant. Statistical analysis was carried out using IBM SPSS Statistics (version 24.0; IBM Corp., New York, USA).

Results

In total, 24 patients were included in this study. Six were found unresectable during laparotomy due to peritoneal metastasis (n=3), progression of liver metastases (n=2) or involvement of both portal vein and hepatic artery (n=1). The remaining 18 underwent major liver resection. Patients’ characteristics are presented in .

Table 1

Patient characteristics (n=18)

Characteristics	Value
Age (years)	63 [53–71]
Male, n (%)	9 (50.0)
BMI (kg/m2)	25.0 [21.6–28.3]
BSA (m2)	1.88 [1.72–1.99]
ASA physical status classification, n (%)
1	3 (17.0)
2	7 (39.0)
3	8 (44.0)
Procedure, n (%)
Right hemihepatectomy	8 (44.0)
Extended right hemihepatectomy	5 (28.0)
Left hemihepatectomy	3 (17.0)
Segmentectomy ≥3	2 (12.0)
Indication, n (%)
Colorectal liver metastasis	4 (21.0)
Hepatocellular carcinoma	1 (6.0)
Cholangiocarcinoma	11 (61.0)
Gall bladder carcinoma	1 (6.0)
Neuro-endocrine tumor	1 (6.0)
Open, n (%)	17 (94.0)
Laparoscopic, n (%)	1 (6.0)
Pre-op TLV (mL)	1,874 [1,289–2,382]
Pre-op FRLV (%)	37.2 [32.5–53.2]
Pre-op TLF (%/min)	14.3 [13.4–16.4]
Pre-op FRLF (%/min)	5.96 [4.69–8.35]

Continuous data are expressed as median and IQR. TLV, total liver volume; FRLV, future remnant liver volume; TLF, total liver function; FRLF, future remnant liver function; IQR, interquartile range.

Postoperative outcomes

Ten patients (56%) had severe postoperative complications (CD ≥ 3A) that occurred during the first five postoperative days. These were bile leakage in four patients, septic complications in three patients, ascites requiring drainage in one patient, partial ischemia of the FRL in one patient. One patient developed PHLF and eventually died on postoperative day 11.

Preoperative assessment of the FRL

A total of 20 patients underwent HBS both preoperatively and at day of admission. Four patients did not undergo additional HBS on the day of admission because preoperative HBS was performed within the same week as the surgery.

The median time between preoperative HBS and HBS at day of admission was 18 [10-26] days. There were no differences in TLF [median 13.8 (12.0–16.2) vs. 15.4 (12.6–16.4) %/min, P=0.601) or FRL function [median 3.1 (2.7–5.3) vs. 3.6 (2.9–5.2) %/min/m2, P=0.263] between preoperative HBS and HBS at day of admission ().

Figure 1

Sequential HBS total liver function in 20 patients. HBS, hepatobiliary scintigraphy.

At preoperative HBS, the median bilirubin value was [18 (10–31) µmol/L; 1.05 (0.58–1.81) mg/dL] which did differ from the bilirubin level at day of admission [12 (8–20) µmol/L; 0.7 (0.46–1.17) mg/dL].

Likewise, there were no differences in total liver volume (TLV) [1,920 (1,316–2,341) vs. 1,802 (1,439–2,252) mL, P=0.394] and FRL volume share [41% (33–56%) vs. 47% (33–62%), P=0.730] between preoperative HBS and HBS at day of admission.

Functional and volumetric regeneration

Between baseline and postoperative day 5, overall, there was a significant increase of (future) remnant liver function, from a median value of 6.9 (5.4–10.9) to 9.6 (6.7–13.8) %/min/m2, P=0.004. Remnant liver function did not further increase significantly between postoperative day 5 to postoperative 4–6 weeks with a median of 9.6 (6.7–13.8) to 10.9 (8.8–13.6) %/min/m2, P=0.177. These changes are also shown in .

Figure 2

Change in remnant liver function (%/min) and volume (mL).

Similarly, there was a significant increase in remnant liver volume between baseline and postoperative day 5, from a median of 795.5 (538.3–1,037.5) to 1,080.0 (854.0–1,283.3) mL, P<0.001. However, in contrast to function, remnant liver volume continued to increase significantly from postoperative day 5 to postoperative 4–6 weeks with median values of 1,080.0 (854.0–1,283.3) and 1,222.0 (1,016.0–1,380.5) mL, respectively, P=0.035. See also .

When comparing patients with and without severe postoperative complications that had occurred during the first 5 postoperative days, a difference was found in the dynamics of parenchymal regeneration. Patients with severe postoperative complications (CD ≥ 3A) showed no significant increase in FRL function between baseline and postoperative day 5 (P=0.203), whereas patients without severe postoperative complications, showed significant functional increase (P=0.012). Eventually after 4–6 weeks, both groups showed a significant increase in median remnant liver function compared to baseline (P=0.012 and P=0.038). This data suggests that patients with early postoperative complications had delayed functional regeneration ().

Figure 3

Change in remnant liver function (%/min) and volume (mL) in patients with and without severe postoperative complications.

This was however not the case for liver volume, which had increased significantly at postoperative day 5 in both patients with (P=0.012) and without (P=0.005) severe postoperative complications ().

Figure 4

Change in volume (%) in all patients and in patients with and without severe postoperative complications.

Change in liver stiffness

At baseline, liver elasticity did not differ between the different groups of included pathologies, P=0.540. Between baseline and the first 5 postoperative days, there was a significant increase in liver elasticity of the FRL [from 10.8 (5.7–18.7) to 17.5 (12.4–22.6) kPa, P=0.018]. This gradually recovered after 4–6 weeks to a median of 10.9 (5.7–18.8) kPa (T3 vs. T4, P=0.079) ().

Figure 5

Change in liver elasticity (kPa) in all patients and in patients with and without severe postoperative complications.

In regard with severe postoperative complications, there were no significant differences in liver elasticity at baseline between patients with and without CD ≥ 3A complications [11.1 (5.99–14.8) vs. 8.9 (5.6–19.4) kPa; P=0.770]. Patients with CD ≥ 3A however, showed a tendency to a larger increase in liver elasticity 5 days after resection, compared to patients with no complications or less than CD ≥ 3A [2.6 (0–15.6) kPa, P=0.176, n=7 vs. 4.5 (0.1–13.5) kPa, P=0.066, n=10; ].

Discussion

Regeneration of the remnant liver occurs predominantly during the first 5 days after resection, rendering this period as crucial for the development of PHLF. In case of severe complications during the first 5 postoperative days, functional regeneration was delayed. This was not noted for volume increase. Uncompromised regeneration in the first 5 days after resection seems crucial to prevent PHLF. So far, this is the first study monitoring postoperative liver function using quantitative liver function tests before and after resection.

These results further emphasize the importance of the early postoperative course in the development of PHLF. Day 5 was chosen because in a large cohort of patients who underwent liver resection without postoperative complications, biochemical blood tests, reflecting liver function, returned to normal values on day 5, corresponding with the normalization of liver function at day 5 (23). This analogy is also found for the ‘50/50 criteria’ where PHLF is defined as a combination of prothrombin time (PT) <50% and serum bilirubin >50 µmol/L on postoperative day 5, as well as for the ISGLS criteria (22,24).

PHLF has a multifactorial etiology and occurs as a result of a decrease in hepatocellular mass in combination with patient, surgical and postoperative factors. The most common postoperative risk factors include complications such as bile leakage and septic complications, ultimately leading to a ‘second-hit’ on top of the residual capacity of the remnant liver. This combination impedes regeneration of the remnant liver and greatly enhances the risk of hepatic insufficiency. The data in this study confirm that in case of postoperative complications, there is a delay in hepatic functional regeneration further contributing to vulnerability of the liver remnant.

Inflammation is an important trigger in the initiation and augmentation of liver regeneration, however, in cases of severe, systemic inflammation such as in sepsis, the balance is shifted towards a detrimental effect, leading to hepatocellular injury, liver dysfunction and impaired regeneration (25). Furthermore, in case of bile leakage, disruption of the enterohepatic bile-gut axis leading to a loss of bile acids also contributes to PHLF. Bile acids are considered hepatotoxic in high concentration, however, they trigger hepatocyte proliferation through activation of several nuclear receptors (26,27). Early detection and management of bile leakage might therefore help to prevent PHLF.

Sequential HBS at different time points did not show differences in TLF. In one patient, the difference between the two sequential HBS studies was remarkably high: 6.2%/min (5.8 vs. 11.6 %/min). This is explained by hyperbilirubinemia occurring during the first scan, with a serum bilirubin of 69 µmol/L. The patient underwent biliary drainage resulting in a reduction of bilirubin to 40 µmol/L during the second scan. All other patients had bilirubin levels below 30 µmol/L and did not show significant differences in TLF between the scans. As reported earlier, increased plasma bilirubin affects the hepatic uptake of mebrofenin due to competitive uptake (28). It is therefore important that the use of HBS in the presence of obstructive cholestasis is restricted to patients having undergone adequate biliary drainage (29).

The discrepancy between function and volume is applicable to the regenerative response after major liver resection. As reported earlier, volume increase does not necessarily correlate with functional increase. This is especially the case in patients that have undergone liver augmenting techniques such as portal vein embolization or ALPPS (6,30). The findings reported in the latter setting corroborate the results of the present study, showing that functional liver regeneration was faster than recovery of liver volume.

Liver elasticity increased in the first 5 postoperative days after resection in this series. The increase was greater in patients with severe postoperative complications compared to patients with an uncomplicated course. Acute changes in parenchymal elasticity occur because of a variety of reasons, including hemodynamic changes, inflammation or acute cellular rejection (31,32). Preliminary studies carried out in liver transplant patients showed that changes in liver stiffness might be predictive of postoperative outcomes. LSM in the early post-transplant period showed that patients with major complications had significantly higher increase in stiffness than those without complications (32). Another study showed that stiffness values in smaller remnant livers increased more than in larger remnant livers (33). Therefore, the change of remnant liver stiffness might reflect the efficiency of liver regeneration and potentially predicts liver failure. Furthermore, parenchymal edema could also influence liver stiffness, and also have a role in the development of PHLF with increased portal pressure and ascites. Until now, LSM has not been applied for monitoring patients after liver resection or for diagnosing acute liver pathologies. More prospective studies are needed to evaluate the application of LSM in this setting as a quick and non-invasive bedside method to assess patients at risk of PHLF.

This study has several limitations, including the small sample size and the heterogeneous patient population. Furthermore, there is a heterogeneity in the extent of the resections performed and therefore, in the remnant liver function and volume fractions recorded. Even though the first severe complications occurred during the first five postoperative days, it is yet uncertain how complications occurring in a later stage affect subsequent liver regeneration.

In conclusion, this study demonstrated that functional liver regeneration predominantly occurred in the first 5 days after resection while the increase in liver volume progressed for 4–6 weeks. Postoperative complications significantly delayed the recovery of liver function, increasing the risk of (remnant) liver failure.

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