Assessing hepatic steatosis by magnetic resonance in potential living liver donors
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Abdominal Imaging - Original Article
P: 351-356
November 2024

Assessing hepatic steatosis by magnetic resonance in potential living liver donors

Diagn Interv Radiol 2024;30(6):351-356
1. Ankara University Faculty of Medicine, Department of Radiology, Ankara, Türkiye
2. Ankara University Faculty of Medicine, Department of Gastroenterology, Ankara, Türkiye
3. Ankara University Faculty of Medicine, Department of Pathology, Ankara, Türkiye
4. Ankara University Faculty of Medicine, Department of General Surgery, Ankara, Türkiye
5. Ankara University Faculty of Medicine, Department of Biostatistics, Ankara, Türkiye
6. Bahçesehir University Faculty of Medicine, Department of General Surgery, İstanbul, Türkiye
7. Ankara University Hepatology Institute, Ankara, Türkiye
No information available.
No information available
Received Date: 05.02.2024
Accepted Date: 17.04.2024
Online Date: 06.11.2024
Publish Date: 06.11.2024
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ABSTRACT

PURPOSE

To determine the accuracy of magnetic resonance imaging-proton density fat fraction (MRI-PDFF) measurements for detecting liver fat content in potential living liver donors and to compare these results using liver biopsy findings.

METHODS

A total of 139 living liver donors (men/women: 83/56) who underwent MRI between January 2017 and September 2021 were included in this analysis retrospectively. The PDFFs were measured using both MR spectroscopy (MRS) and chemical shift-based MRI (CS-MRI) for each donor in a blinded manner.

RESULTS

Significant positive correlations were found between liver biopsy and MRS-PDFF and CS-MRI PDFF in terms of hepatic steatosis detection [r = 0.701, 95% confidence interval (CI): 0.604–0.798, r = 0.654, 95% CI: 0.544–0.765, P < 0.001, respectively). A weak level correlation was observed between liver biopsy, MRI methods, and vibration-controlled transient elastography attenuation parameters in 42 available donors. Based on receiver operating characteristic (ROC) analysis, MRS-PDFF and CS-MRI PDFF significantly distinguished >5% of histopathologically detected hepatic steatosis with an area under the ROC curve (AUC) of 0.837 ± 0.036 (P < 0.001, 95% CI: 0.766–0.907) and 0.810 ± 0.036 (P < 0.001, 95% CI: 0.739–0.881), respectively. The negative predictive values (NPVs) of MRS-PDFF and CS-MRI PDFF were 88.3% and 81.3%, respectively. In terms of distinguishing between clinically significant hepatic steatosis (≥10% on histopathology), the AUC of MRS-PDFF and CS-MRI were 0.871 ± 0.034 (P < 0.001 95% CI: 0.804–0.937) and 0.855 ± 0.036 (P < 0.001, 95% CI: 0.784–0.925), respectively. The NPVs of MRS-PDFF and CS-MRI were 99% and 92%, respectively.

CONCLUSION

The methods of MRS-PDFF and CS-MRI PDFF provide a non-invasive and accurate approach for assessing hepatic steatosis in potential living liver donor candidates. These MRI PDFF techniques present a promising clinical advantage in the preoperative evaluation of living liver donors by eliminating the requirement for invasive procedures like liver biopsy.

Keywords:
Magnetic resonance spectroscopy, proton density fat fraction, chemical shift-based magnetic resonance imaging, liver transplantation, living liver donor, metabolic-associated steatotic liver disease

Main points

• The magnetic resonance spectroscopy-proton density fat fraction (MRS-PDFF) and chemical shift-based-MR imaging (CS-MRI) PDFF methods are effective, non-invasive techniques for assessing hepatic steatosis in living liver donor candidates.

• MRI methods, with their high negative predictive value, can eliminate the need for liver biopsy by detecting clinically significant hepatic steatosis.

• The MRS-PDFF and CS-MRI PDFF methods exhibit a high level of correlation in evaluating hepatic steatosis, suggesting that they can be used interchangeably.

Metabolic dysfunction-associated steatotic liver disease (MASLD) is a public health problem that affects more than 25% of adults worldwide, causing hepatic and extrahepatic morbidity and mortality.1-3 This disease encompasses a broad spectrum of hepatic conditions, ranging from metabolic dysfunction-associated steatosis, characterized by macrovesicular hepatic steatosis that may be accompanied by mild inflammation, to metabolic dysfunction-associated steatohepatitis, which is additionally characterized by the presence of inflammation and hepatocyte injury, with or without fibrosis, cirrhosis, or hepatocellular carcinoma.1, 2 MASLD is the most prevalent chronic liver disease, especially in Western countries, and the proportion of MASLD-related cirrhosis cases among patients on liver transplantation (LT) waiting lists has increased over the years.2, 3 In Türkiye, the prevalence of MASLD is estimated to be more than 30% in the general population.4

Living donor LT (LDLT) is an important mortality-reducing treatment approach for patients with acute and chronic liver failure.5, 6 The use of LDLT has been gradually increasing due to a lack of available cadaveric liver grafts. Several factors are associated with successful graft organ survival following LT.5, 7 Donor liver steatosis is critical for successful graft function, graft, and recipient survival in the early post-transplant period, and donor safety.6-8 Although <5% hepatic steatosis is universally acceptable for liver organ donation, the inclusion thresholds of the hepatic steatosis fraction may vary among liver transplant centers. Some centers use a threshold of <10%,9, 10 while others consider <20% or <30% as acceptable for donation.11, 12 Liver biopsy remains the gold standard diagnostic method for accurately assessing hepatic steatosis. However, due to the invasive nature of biopsy, the potential for sampling errors, and intra- and inter-observer variability, there is a tendency to perform liver biopsies on select donors rather than on all potential donors.13, 14

Magnetic resonance (MR)-based fat quantification [proton density fat fraction (PDFF)] is an accurate, non-invasive method for determining and quantifying hepatic steatosis.11, 15-19 PDFF is the ratio of the MR signal from fat protons to the total MR signal from fat and water protons.20 PDFF is mainly measured using two MRI methods: magnetic resonance spectroscopy (MRS) and chemical shift (CS)-based MRI. MRS data can be acquired efficiently using a high-speed T2-corrected multi-echo sequence during a single-hold breath, minimizing motion artifacts. This streamlined approach facilitates the rapid acquisition of metabolic information from a specific voxel region, as described previously.21 Conversely, the multi-echo CS-MRI technique, which employs six echoes and is known by various commercial vendor-specific names (e.g., Multi-echo Dixon for Siemens, IDEAL IQ for GE, and mDixon Quant for Philips), can generate a comprehensive PDFF map of the entire liver. As mentioned in one of the initial studies using this technique, there is a close correlation between liver biopsy results and CS-MRI PDFF in patients with non-alcoholic fatty liver disease.22 The most significant advantages of this technique include the ability to obtain a PDFF map for the entire liver and perform measurements in different liver regions. In contrast, MRS is limited to sampling a voxel area of a few cm3. MRI is also used in donor hepatic vascular and biliary system anatomy examination.

Increasingly prevalent in the general population, MASLD poses a significant problem in LDLT, leading to morbidity and mortality in both the recipient and the donor. MRS and CS-MRI are proven techniques for assessing and quantifying liver fat presence. However, data regarding the diagnostic accuracy and utility of MRI-based fat quantification in transplant settings is limited. Accordingly, this study aims to determine the accuracy of MRS-PDFF and CS-MRI PDFF measurements for detecting and quantifying the liver fat content in potential living liver donors and to compare these results with liver biopsy findings.

Methods

Participants

This retrospective study comprised 145 potential living liver donors who underwent an MRI examination between January 2017 and September 2021. Six donors with suboptimal examinations due to artifacts were excluded from the investigation to ensure the reliability of the data analysis (Figure 1 represents patient accrual). The median time interval between MR and liver biopsy was 12 days (range: 1–30 days). Data were collected from outpatient visit charts. Percutaneous liver biopsy was performed in living liver donors who had abnormal liver injury and/or cholestatic liver tests, obesity, or hepatic steatosis detected by ultrasonography. This study was approved by the Ankara University Human Research Ethics Committee (date: October 2021, decision no: I5-365-21). Written informed consent was waived due to the study’s retrospective design.

Serum alanine aminotransferase (ALT), aspartate aminotransferase (AST), gamma-glutamyl transpeptidase (GGT), alkaline phosphatase, bilirubin, fasting glucose, lipid profiles, and complete blood cell counts were measured in our central laboratory.

Magnetic resonance imaging technique

The MRI scans were performed using a 1.5 Tesla MRI device (Aera, Siemens Healthcare, Erlangen, Germany) with an 18-channel body matrix coil and a 32-channel spine matrix coil, utilizing eight channels. In liver donor candidates, in addition to the standard non-contrast abdomen MRI protocol, the LiverLab program provided by the vendor was used to determine and quantify the presence of iron and fat accumulation in the liver. The LiverLab program integrated into liver MRI comprised three sequences: T1 volumetric interpolated breath-hold examination (VIBE) e-Dixon, VIBE q-dixon, and HISTO. The VIBE q-dixon is a single-breath-hold sequence comprising six echoes, which enables the acquisition of volumetric PDFF and R2* maps, forming the basis of CS-MRI. The HISTO sequence, forming the basis of MRS, was obtained using a 15-second breath-hold T2-corrected multi-echo stimulated echo acquisition mode sequence, utilizing a single voxel of 3 × 3 × 3 cm dimensions. The MRS data were acquired from a single voxel positioned by an experienced MR technician in a homogenous area away from vascular and biliary structures and liver edges in the right lobe during the scan.

Image analysis

The values of MRS PDFF were obtained from the report generated by the HISTO sequence provided by the manufacturer (calculated using Siemens software). Then, CS-MRI PDFF was performed on a dedicated workstation (Syngo., Siemens Healthcare), using the volumetric FF map transferred to it. The measurements of PDFF were conducted by two abdominal radiologists, with 10 (D.K.Ö.) and 2 (M.A.) years of experience. Measurements were obtained by placing three 200–300 mm2 regions of interest (ROI) in at least 3 sections of the FF map at the level of the mid-right hepatic lobe (Figure 2). The radiologists conducting the measurements were unaware of the clinical data. Inconsistent measurement results were reevaluated until a consensus was reached. In cases of similar results, measurements performed by experienced radiologists were evaluated statistically. The ROIs were positioned within the homogeneous parenchymal area, avoiding vascular and biliary structures and the liver edges. The average PDFF values for each participant were calculated.

Transient elastography

Hepatic steatosis was also measured using a FibroScan probe (Echosens, Paris, France) with an M or XL probe to cater to patients with different body types. All measurements were performed by one of the authors (Z.E.). Patients were examined after fasting overnight. The FibroScan probe was placed in the appropriate intercostal space window on the anterior axillary line. At least 10 valid measurements were obtained within 5–10 minutes. The median ratio of 10 successive measurements to the interquartile range was <30%. Simultaneously, vibration-controlled transient elastography (VCTE) was used to measure the controlled attenuation parameter (CAP) (dB/m) and liver stiffness (kPa). Morbidly obese patients [body mass index (BMI) >40 kg/m2] and severely underweight patients (BMI <16 kg/m2), patients with ascites, and patients with moderate and severe cholestasis were excluded.

Histological assessments

Two pathologists (S.K., B.S.) blinded to the clinical and biochemical data re-evaluated all liver biopsy specimens. The histological features of the samples were interpreted using the criteria of Brunt et al.23 Hepatocellular steatosis was graded on a scale of 0–3 based on the percentage of hepatocytes: 0 = <5%, 1 = 5%–33%, 2 = 33%–66%, and 3 = >66%.

Definitions

The primary endpoint was the assessment of hepatic steatosis using MRI methods, MRS-PDFF, and CS-MRI PDFF. The secondary endpoint was to compare the MRI results with the liver biopsy findings.

Statistical analysis

Descriptive statistics were summarized as percentages for categorical variables, mean and standard deviations for normally distributed continuous variables, and median, minimum, and maximum for ordinal and non-normally distributed continuous variables. Spearman’s correlation coefficient analysis was performed to determine the degree of association between PDFF and histopathology. Bootstrapping was used to estimate confidence intervals (CIs) for Spearman’s correlation coefficient. Intra-group comparison of categorical variables was performed using the McNemar test. Receiver operating characteristic (ROC) curves were used to describe and compare the performance of the diagnostics value of the MRI methods. Youden’s index was used to determine the optimal cut-off value. The PDFF measurement results were compared with the liver biopsy results. The significance level was established as α = 0.05, and the R programming language 4.3.1 was used for statistical analysis.

Results

A total of 139 potential living liver donors (men/women: 83/56) were included in this study. The median age of the donors was 31.0 years (range: 17–59 years). The median BMI was 24.9 kg/m2 (range: 17.6–33.2 kg/m2), 40% of the patients were overweight (25–29.9 kg/m2), and 18% were obese (≥30 kg/m2). Of the donors, 35% had diabetes mellitus, and 28% had hypertension. The median serum ALT level was 18 U/L (range: 6–56 U/L), the median AST level was 20 U/L (range: 10–4 U/L), and the median GGT level was 20 U/L (range: 7–95 U/L). The donors’ clinical data and laboratory values are presented in Table 1.

Hepatic steatosis was detected in 54 donors in the liver biopsy assessment. A total of 50 (36%) donors had grade 1 steatosis, 3 (2%) had grade 2 steatosis, and 1 (1%) had grade 3 steatosis, whereas 85 (61%) had no steatosis. Using the threshold values obtained from ROC analysis with MRS and CS-MRI methods, 9 out of 54 donors confirmed to have hepatic steatosis histopathologically showed no steatosis with MRS, while 12 showed no steatosis with CS-MRI. While there were 7 cases with no detected steatosis by both MRI methods, the PDFF value of 1 case using MRS and 2 cases using CS-MRI could not be obtained due to artifacts. In 5 out of 7 cases, histopathologically, there was minimal steatosis at the lower limit (5%), whereas in the remaining cases, there was mild steatosis (8%–10%).

The mean MRS-PDFF and CS-MRI PDFF were 5.8% ± 3.9% and 4.1% ± 3.9%, respectively. Significant positive correlations were found between liver biopsy and MRS-PDFF and CS-MRI-PDFF in terms of hepatic steatosis detection (r = 0.701, 95% CI: 0.604–0.798 and r = 0.654, 95% CI: 0.544–0.765, P < 0.001, respectively). Additionally, VCTE was performed on 42 available donors. The mean CAP was 248.4 ± 60.0 dB/m. A weak-moderate correlation was observed between liver biopsy, MRS-PDFF, CS-MRI PDFF, and VCTE CAP in terms of hepatic steatosis detection (r = 0.616, P < 0.001, 95% CI: 0.402–0.831, and r = 0.513, P < 0.001, 95% CI: 0.254–0.772, and r = 0.351, P = 0.017, 95% CI: 0.062–0.640, respectively) (Table 2).

An ROC analysis was performed to distinguish between clinically significant and non-significant hepatic steatosis. Significantly, MRS-PDFF and CS-MRI PDFF distinguished >5% of histopathologically detected patients of hepatic steatosis with an area under the ROC curve (AUC) of 0.837 ± 0.036 (95% CI: 0.766–0.907) and 0.810 ± 0.036 (95% CI: 0.739–0.881), P = 0.345 (Table 3, Figure 3a). The optimal thresholds for MRS-PDFF and CS-MRI were 4.65% and 3.45%, respectively. The sensitivities of MRS-PDFF and CS-MRI were 83.3% (95% CI: 71.3%–91.0%) and 74.1% (95% CI: 61.1%–83.9%, P = 0.063), respectively, whereas the specificities of MRS-PDFF and CS-MRI were 80.0% (95% CI: 70.3%–87.1%) and 71.8% (95% CI: 61.4%–80.2%, P = 0.118), respectively. The negative predictive values (NPVs) of MRS-PDFF and CS-MRI PDFF were 88.3% (95% CI, 79.3%–93.7%) and 81.3% (95% CI: 71.1%–88.5%), respectively. In terms of distinguishing clinically significant hepatic steatosis (³10% on histopathology), the AUCs of MRS-PDFF and CS-MRI were 0.871 ± 0.034, (95% CI: 0.804–0.937, P < 0.001) and 0.855 ± 0.036, (95% CI: 0.784–0.925, P < 0.001), respectively (Table 3, Figure 3b). The cut-off values were 4.65% and 3.95%, respectively. The sensitivity of MRS-PDFF was significantly better than that of CS-MRI PDFF for distinguishing significant hepatic steatosis (³10% on histopathology) [97.2% (95% CI: 85.8%–99.5%) vs. 80.6% (95% CI: 0.65.0%–90.2%), P = 0.031]. The specificities of these MRI methods were 73.8% (95% CI: 64.5%–81.3%) and 78.6% (95% CI: 69.8%–85.5%, P = 0.302), respectively.

The NPVs of MRS-PDFF and CS-MRI were 98.7% (95% CI: 93.0%–99.8%) and 92% (95% CI: 84.5%–96.1%), respectively.

Discussion

This large-sample study compared the accuracy of MRI techniques in assessing hepatic fat content in potential living liver donors. It was found that MRS-PDFF and CS-MRI PDFF accurately assessed hepatic fat content and were strongly positively correlated with evaluating hepatic steatosis by liver biopsy. However, VCTE showed a weak-moderate correlation with liver biopsy assessment and MRI methods.

Steatotic liver graft has been associated with an increased risk of graft dysfunction or graft failure, especially in the early post-transplant period, mainly due to ischemia-reperfusion injury.8 There are still unanswered questions regarding what constitutes acceptable risk concerning the level of fat content in living liver donors. The prevalence of MASLD is increasing globally, and LDLT is a vital therapeutic option for managing end-stage liver disease. Therefore, it is crucial to understand how to effectively assess donor liver fat content. Several previous studies have investigated the role of MRI in liver fat content assessment in both transplant and non-transplant settings.15, 24-26 A meta-analysis reported that MRI-PDFF demonstrated 89% specificity and 84% sensitivity in detecting donor candidates with >5% hepatic steatosis, as determined by liver biopsy.27 In addition, in a study of 32 potential liver donors, MRS distinguished donors with significant hepatic steatosis designated as >10% on histopathological examination. The investigators concluded that CS-MRI and MRS would eliminate the need for liver biopsy.28 In this study, MRS-PDFF and CS-MRI PDFF could distinguish between liver donors with/without clinically significant hepatic steatosis (>5%) on histopathological examination, with high NPVs. The accuracy and the NPVs of the MRI methods were increased when distinguishing donors with >10% hepatic steatosis on histopathology.

This study found cut-off values for MRS-PDFF and CS-MRI PDFF of 4.65% and 3.45%, respectively, for distinguishing >5% of hepatic steatosis, as detected by liver biopsy. These values improved the identification of histopathological liver fat content with a high NPV. These findings suggest that living donor candidates with <4.65% PDFF on MRI could potentially qualify as living liver donors. Previous studies reported no significant differences between the two MRI methods for identifying hepatic fat content.21 According to Idilman et al.29, in scanners where one of the two software tools is not available, the hepatic steatosis percentage can be accurately determined using the alternative method currently in place. However, having both methods in the standard MRI protocol for liver donors offers several advantages. The results of both methods can be used to corroborate each other. For instance, in cases of heterogeneous fat deposition or misplacement of the voxel, MRS may yield incorrect results. Furthermore, in the case of fat-water swapping artifacts, the PDFF cannot be obtained through CS-MRI. In such cases, PDFF can be determined using MRS. The increase in the correlation with histopathology when both MRI methods are used to complement each other, despite missing PDFF data, is the strongest evidence of the advantages of using both MRI methods with donors.

The VCTE CAP values exhibited a relatively weak correlation with the histopathological findings. Previous studies have reported a VCTE moderate correlation between VCTE CAP and MRI-PDFF.30, 31 This study confirms previous studies demonstrating a weak-moderate correlation between CAP and liver biopsy, as well as MRI methods assessing hepatic steatosis.

While this study demonstrated a correlation between histopathology and MRI methods in identifying hepatic fat content, it possesses several notable limitations. First, it relied on retrospective observational data from a tertiary referral center. Moreover, there is a potential for bias related to the participants’ data and confounding factors. Additionally, although all candidates underwent extensive investigation before donation and were deemed healthy, the donor’s hepatic iron content was not measured, potentially impacting fat quantification with MRI. Despite being costly techniques for routine practice, they should be acknowledged as cost-effective methods in evaluating patients before complex surgical procedures such as LT, which carry high morbidity and mortality rates in tertiary referral healthcare centers.

In conclusion, MRS-PDFF and CS-MRI PDFF accurately assess the presence and grade of hepatic fat content in potential living liver donor candidates. MRI is a non-invasive and valuable tool for use in the liver donor selection process for LDLT.

Conflict of interest disclosure

The authors declared no conflicts of interest.

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