Next Article in Journal
Low-Glycemic-Index/Load Desserts Decrease Glycemic and Insulinemic Response in Patients with Type 2 Diabetes Mellitus
Next Article in Special Issue
Nutritional Status and Quality of Life in Hospitalised Cancer Patients Who Develop Intestinal Failure and Require Parenteral Nutrition: An Observational Study
Previous Article in Journal
Psychological Aspects and Eating Habits during COVID-19 Home Confinement: Results of EHLC-COVID-19 Italian Online Survey
Previous Article in Special Issue
Vitamin C in Home Parenteral Nutrition: A Need for Monitoring
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Serum Scoring and Quantitative Magnetic Resonance Imaging in Intestinal Failure-Associated Liver Disease: A Feasibility Study

1
Intestinal Failure Service, Gastrointestinal Services, University College London Hospitals NHS Foundation Trust, London NW1 2BU, UK
2
UCL Division of Medicine, University College London, London WC1E 6BT, UK
3
UCL Centre for Medical Imaging, University College London, London WC1E 6BT, UK
4
Department of Medical Physics, University College London Hospitals NHS Foundation Trust, London WC1N 3BG, UK
5
UCL Institute for Liver and Digestive Health, University College London, London WC1E 6BT, UK
*
Authors to whom correspondence should be addressed.
Submission received: 23 May 2020 / Revised: 8 July 2020 / Accepted: 13 July 2020 / Published: 19 July 2020
(This article belongs to the Special Issue Intestinal Failure and Home Parenteral Nutrition)

Abstract

:
(1) Background: Intestinal failure-associated liver disease (IFALD) in adults is characterized by steatosis with variable progression to fibrosis/cirrhosis. Reference standard liver biopsy is not feasible for all patients, but non-invasive serological and quantitative MRI markers for diagnosis/monitoring have not been previously validated. Here, we examine the potential of serum scores and feasibility of quantitative MRI used in non-IFALD liver diseases for the diagnosis of IFALD steatosis; (2) Methods: Clinical and biochemical parameters were used to calculate serum scores in patients on home parenteral nutrition (HPN) with/without IFALD steatosis. A sub-group underwent multiparameter quantitative MRI measurements of liver fat fraction, iron content, tissue T1, liver blood flow and small bowel motility; (3) Results: Compared to non-IFALD (n = 12), patients with IFALD steatosis (n = 8) demonstrated serum score elevations in Enhanced Liver Fibrosis (p = 0.032), Aspartate transaminase-to-Platelet Ratio Index (p < 0.001), Fibrosis-4 Index (p = 0.010), Forns Index (p = 0.001), Gamma-glutamyl transferase-to-Platelet Ratio Index (p = 0.002) and Fibrosis Index (p = 0.001). Quantitative MRI scanning was feasible in all 10 sub-group patients. Median liver fat fraction was higher in IFALD steatosis patients (10.9% vs 2.1%, p = 0.032); other parameter differences were non-significant; (4) Conclusion: Serum scores used for non-IFALD liver diseases may be useful in IFALD steatosis. Multiparameter MRI is feasible in patients on HPN.

1. Introduction

Intestinal failure associated liver disease (IFALD) refers to a clinical state of hepatic injury arising as a result of intestinal failure (IF) and / or its treatment [1,2,3]. As a major complication of IF, it remains a major indication for intestinal transplantation (with or without liver transplantation) [1] and accounts for almost 30% of all deaths related to home parenteral nutrition (HPN) [4]. The aetiology is multifactorial where both parenteral nutrition (PN)- [5,6,7,8,9,10,11,12,13,14] and non-PN-related factors [10,15,16,17,18,19,20,21,22,23,24] contribute [25,26].
Recently, ESPEN defined IFALD as a complication occurring as a result of one or more factors relating to IF including PN and arising in the absence of another primary parenchymal liver pathology such as hepatotoxicity or biliary obstruction [3]. Once modifiable causes have been minimised, the definitive treatment for IFALD is intestinal transplantation. Isolated intestinal transplantation may reverse hepatic fibrosis [27] and UK experience indicates survival with isolated small bowel grafts is longer than that for liver-containing grafts [28,29]. Interestingly, the pathophysiology of IFALD in adults differs from the paediatric population, where steatosis with variable progression to fibrosis dominate, as opposed to predominantly cholestasis in children [25,30].
Despite the clinical importance, specific diagnostic criteria for IFALD in adults do not exist. Although liver biopsy is considered the gold standard, it is invasive with an attendant risk of complications, and therefore unsuitable for longitudinal monitoring. Furthermore, it is subject to sampling error and no validated consensus reporting tool for IFALD histology has been developed.
There is therefore a clinical need for accurate non-invasive markers both for diagnosis and disease progression from steatosis to fibrosis. Standard liver function tests (LFTs) are used routinely for monitoring patients with chronic IF, but deranged LFTs are have low specificity in IFALD, with reported prevalence in HPN populations of 5–85% [4,14,29,31]. Nine different diagnostic serum scoring systems for the presence of IFALD have been described, relating to different pathological subtypes [2,32], but none have been validated and their use has led to heterogeneity in the literature. Indeed, Sasdelli et al. [2] recently demonstrated wide variance in IFALD prevalence in a single HPN cohort depending on the diagnostic criteria used.
Composite serum scores have also been studied in relation to diagnostic and prognostic use in non-IFALD chronic liver diseases such as non-alcoholic fatty liver disease (NAFLD) and chronic viral hepatitides. The aspartate transaminase (AST)-to-platelet ratio index (APRI) carries moderate accuracy in predicting fibrosis and cirrhosis in patients with chronic hepatitis C [33,34], chronic hepatitis B [35,36,37] and NAFLD [38,39]. Data on the use of APRI in paediatric IFALD are conflicting, although it has been correlated with fibrosis [40,41,42,43]. In adult IFALD, APRI was correlated with biochemical and histologic cholestasis, but not fibrosis [44]. The Fibrosis 4 (Fib4) score correlates with fibrosis in chronic hepatitis B [45,46], NAFLD [47] and HIV/HCV co-infection [48], but in IFALD has been correlated with cholestasis rather than fibrosis [44]. Neither score has been specifically studied in relation to IFALD steatosis. The clinical utility of a number of other scores have been studied in various non-IFALD chronic liver diseases including the Forns index [49,50,51], Enhanced Liver Fibrosis (ELF) score [52,53,54,55,56], Fibrosis Index [49], gamma-glutamyl transferase (GGT)-to-platelet ratio (GPR) score [57] and the NAFLD fibrosis score [58,59,60], all of which have potential for clinical use but are not part of routine clinical practice. Finally, a few proprietary serum panels have also been assessed. Fibrotest has been shown to accurately predict fibrosis across a range of chronic liver diseases [61,62], while FibroMeter [63] and Hepascore [64] have been correlated with fibrosis in NAFLD and chronic Hepatitis C, respectively. The role of these scores in IFALD requires further investigation—it is possible that serum scores may be useful for the diagnosis/monitoring of IFALD, particularly as steatosis and fibrosis are pathophysiological phenomena common with other chronic liver diseases. It seems appropriate to assess the performance of these scores in the diagnosis of IFALD steatosis in the first instance, before assessing their use in disease progression to IFALD fibrosis.
Radiological assessment is routinely used in other chronic liver diseases including NAFLD and viral hepatitis. Ultrasound is readily available, inexpensive and accessible at the patient bedside, but quantitative approaches suffer from high inter- and intra-observer variability [65,66]. Results in IFALD patients are mixed—the detection of steatosis matches the results in the general population [2,67], but imaging-based quantitative measures have been unsuccessful in staging fibrosis [68,69]. Biomechanical sonographic methods such as transient elastography, in widespread use for the assessment of liver fibrosis in non-IFALD chronic liver diseases, have in adult IFALD patients correlated with histological cholestasis and serum bilirubin but not fibrosis [44]. Acoustic radiation force impulse ultrasound elastography has been more promising, with a biopsy-validated differentiation between absent/mild and moderate/severe fibrosis in paediatric IFALD patients [70].
Magnetic resonance imaging (MRI) has an established role in the assessment of chronic liver diseases, but the use of quantitative MRI methods for the assessment of chronic liver disease remains largely in the research rather than clinical setting. Proton magnetic resonance spectroscopy (1H-MRS) can be used for reference standard measurements of hepatic steatosis [68,71] and has demonstrated increased fat–water ratios in patients with IFALD [28,29]. Chemical shift imaging-based measurements of the liver fat fraction have reported a prevalence of steatosis of 28.6% in patients with chronic IF, but it is unclear how many of these patients had IFALD [72]. In any case, 1H-MRS measurements of liver fat have in current practice been superseded by proton density fat fraction (PDFF) measurements [73] and, while a study indirectly inferring these measurements in IFALD patients have estimated moderate–severe steatosis (average 19.6% liver fat fraction) [74], no formal liver MRI PDFF measurements data in patients with IFALD have been reported.
Once patients are in the scanner, MRI also provides the opportunity to explore the use of other quantitative MRI methods for the evaluation of chronic liver disease. For example, liver PDFF measurements rely on T2* mapping data which can also be used to derive robust estimates of liver iron concentration [73,75], and may be of interest in assessing metabolic consequences of long-term parenteral nutrition [76]. Measurements of liver T1 have been correlated with fibrosis in chronic liver disease [77] and measurements of portal venous and hepatic arterial blood flow using phase-contrast MRI have been correlated with the severity of portal hypertension [78]. In conjunction, these measures have the potential to yield pathophysiological insights into IFALD.
Imaging of the abdomen can also enable the severity of MRI-quantified liver disease to be evaluated with other potential markers of intestinal tract dysfunction such as small bowel motility. The quantification of small bowel motility using cine MRI has proven useful in the assessment of inflammatory bowel disease [79], and while dysmotility is a reported feature of IF [80], there are no published MRI small bowel motility data in patients with IFALD.
Finally, probing multiple organs with different quantitative MRI methods enables the assimilation of these measurements to derive composite scores—so-called ‘multiparametric MRI’— with the potential to yield more robust and comprehensive indices of disease than individual quantitative MRI measurements in isolation.
There is therefore a clear need to develop robust non-invasive markers for routine clinical use in IFALD. The aims of this study were (i) to assess the clinical utility of serum scores used in the management of non-IFALD chronic liver diseases for the diagnosis of IFALD steatosis, and (ii) to assess the feasibility of performing multiparameter quantitative MRI studies in a cohort of patients on HPN and explore differences in these parameters in IFALD steatosis patients.

2. Methods

2.1. Study Design and Participants

This was a single-centre, cross-sectional study of patients with type 3 IF on HPN. Patients were identified from the IF database at University College London Hospitals (UCLH). Electronic medical records were interrogated, including results of previous radiological tests. Data on patients’ demographics, history of disease, clinical treatment, medications, and nutritional therapy were collected. To determine potential cofounders, clinical and nutritional variables were recorded. Clinical variables included pathophysiological classification of IF, small bowel length, co-morbidities, presence of remaining colon, use of hepatotoxic medications, use of antibiotics, prevalence of catheter related blood stream infection episodes, use of Taurolock TM and Curos TM disinfecting port protectors and results of hydrogen breath tests assessing for small intestinal bacterial overgrowth. The following nutritional variables were measured: age of initiation of PN, PN duration, number of days of PN infusion per week, number of days of PN lipid infusion per week, dose of PN lipid infusion, type of PN lipid preparation, mean kilocalories in PN solutions per day, presence of oral intake and presence of enteral intake. Patients were classified into an ‘IFALD steatosis’ group if ultrasound (US), computed tomography (CT), MRI or magnetic resonance cholangiopancreatography (MRCP) imaging performed within the previous six months had reported parenchymal liver steatosis in the absence of cholestasis or advanced liver disease (inclusive of a second review) [1]. Patients were classified into a ‘non-IFALD’ group if imaging performed within the previous six months had reported no parenchymal liver abnormalities. Exclusion criteria were malignancy, lack of hepatic imaging in the preceding six months or imaging demonstrating cholestasis or advanced liver disease.

2.2. Laboratory Tests

For the serum study, blood samples were collected at UCLH during planned hospital visits. Serum levels of haemoglobin, white cell count, platelet count, sodium, potassium, urea, creatinine, estimated glomerular filtration rate, magnesium, phosphate, vitamin D, glucose, total cholesterol, triglycerides, and C-reactive protein were measured. In addition, liver function tests including bilirubin, AST, alanine transaminase (ALT), alkaline phosphatase (ALP), GGT, albumin, international normalized ration (INR), and prothrombin time were evaluated. For the purpose of the study, mean levels of bilirubin, AST, ALT, ALP, and GGT, from the last six months were used. Other serum tests associated with liver function such as antimitochondrial antibodies, total bile acids, procollagen III N-terminal peptide (PIIINP), haptoglobin, apolipoprotein A1 and ferritin were also measured. Composite serum scores were also measured at a single time point as shown in Table 1.

2.3. MRI Scanning

For the MRI feasibility study, patients from both IFALD and non-IFALD groups were approached. Demographic and clinical data were collected as per the serum study. Local ethics committee approval was obtained (UCL Research Ethics Committee, Approval no. 07/Q0502/15), and all participating patients provided informed written consent. Patients were eligible to participate in the MRI feasibility study if they had no MRI contraindications (such as claustrophobia or previous non-MR safe metallic implants). All scans were undertaken in the afternoon to allow time for patients to attend after morning PN discontinuation. Scans were scheduled on the same day as outpatient clinical appointments to maximise patient convenience.
Imaging was performed on a 3T scanner (Ingenia, Philips Healthcare, Best, Netherlands), with a 16-channel body coil (SENSE XL Torso, Philips Healthcare, Best, Netherlands). Briefly, a multiparametric MRI protocol was used that included (a) anatomical axial, coronal and sagittal breath-hold balanced steady-state free precession imaging for anatomical planning, (b) liver PDFF measurements images and T2* maps for measurement of liver iron concentration using the Philips mDixon Quant sequences, (c) liver T1 mapping using multi-inversion time coronal spectral pre-saturation with inversion recovery spin echo sequences [82], (d) caval subtraction two-dimensional phase-contrast MRI measurements of portal venous, infrahepatic and suprahepatic inferior vena caval flow [83] and (e) coronal dynamic cine balanced fast field echo imaging with coverage of the whole small bowel volume for measurement of small bowel motility [84]. Full methodological acquisition and post-processing details can be found in Appendix A. All MRI scanning was undertaken by a radiographer (L.C.) with over 5 years of experience in abdominal imaging and trained in planning caval subtraction phase-contrast MRI studies.
The primary outcome was the number of eligible consenting patients who completed full MRI protocols with all datapoints collected (target 80% with study failure if <50% patients underwent MRI scans or <50% datapoints were collected). Secondary exploratory analyses of measurements of liver PDFF measurements, liver iron concentration, and liver T1 were based on averages from regions of interest (ROIs) drawn on each of the nine Couinaud liver segments, ROIs drawn on each vessel for bulk flow phase-contrast MRI measurements and manual segmentation of small bowel for small bowel motility. Post-processing and segmentation processes are described in detail in Appendix A. ROI placement and segmentation was undertaken by a hepato-pancreatico-biliary radiologist (M.D.C.) with over 10 years of experience in abdominal imaging, blinded to the patient group.

2.4. Statistical Analysis

Data were analysed using SPSS software package version 24.0 (SPSS, Inc., Chicago, Illinois, USA) and R 4.0. Mean and standard deviation (SD) or median and range were used to summarize values. Shapiro–Wilks tests were performed to test normal distribution of numerical data. Comparison of mean/medians between groups were done using t-tests for parametric analyses, Mann–Whitney U-test for non-parametric analyses, and Wilcoxon signed rank for comparing against a hypothetical median. Frequency data were compared using Fisher’s exact test. p-values less than 0.05 were considered statistically significant. Sample size and power calculations were performed based on a study measuring APRI in paediatric patients with IF [40]. Calculation using an α-value of 0.05 and a β-value of 0.80 reported a minimum sample size of 22 subjects, 11 for each group, for the present study.

3. Results

3.1. Serum Cohort

3.1.1. Patient Demographics

Twenty patients were divided between IFALD steatosis (n = 8) and non-IFALD (n = 12) groups as defined above. The clinical and nutritional characteristics of the two groups are shown in Table 2. Both groups were matched for age, pathophysiological classification, small bowel length, oral diet, PN energy, lipid use and number of infusions per week. Participants in the IFALD steatosis group had significantly higher BMIs (23.73 ± 3.36 kg/m2) than participants with no IFALD (19.91 ± 2.95 kg/m2). A trend towards longer PN duration was observed in the IFALD steatosis group, although this difference was not significant. In no patients of the IFALD steatosis group were there any radiological or biochemical evidence of cholestasis, fibrosis, cirrhosis or portal hypertension. Similarly, there was no evidence of liver disease (including NAFLD) prior to the development of intestinal failure in any patient.

3.1.2. Biochemical Parameters

Mean values of serum markers over the preceding six months were calculated for each patient and reported as means for each group, with results shown in Table 3 and Figure 1. Serum AST, ALT, GGT and PIIINP were all significantly elevated and outside of the normal range in the IFALD steatosis group. Serum platelet count, bilirubin and haptoglobin were also significantly different between the two groups but with mean values within the normal range. The following range of other serum variables were not found to be significantly different between the two groups: estimated glomerular filtration rate, magnesium, phosphate, vitamin D, total cholesterol, sodium, potassium, urea, haemoglobin, creatinine, white cell count, glucose, triglycerides, bile acids, ALP, ferritin, albumin, INR, prothrombin time, and Apoliprotein A1.

3.1.3. Composite Serum Scores

The most contemporaneous blood results were used to calculate composite serum scores, as shown in Table 1. Results are shown in Table 4 and Figure 1. The APRI score (p < 0.001), Fib4 score (p = 0.010), Forns Index (p = 0.001), GPR score (p = 0.002), ELF score (p = 0.032) and Fibrosis Index (p = 0.001) means were all significantly higher in the IFALD steatosis group than the non-IFALD group. No significant difference between IFALD steatosis and non-IFALD participants were reported when measuring the AST/ALT ratio and the NAFLD score.

3.2. MRI Cohort

3.2.1. Demographics

Ten patients from the serum cohort were taken forward for the MRI study and grouped into IFALD steatosis (n = 5) and non-IFALD (n = 5) groups. Demographics and clinical characteristics are shown in Table 5.

3.2.2. Feasibility Results

Results of the proportion of patients progressing through the feasibility study are shown in Figure 2. Of the 10 patients, nine were able to attend on pre-agreed dates and times for scanning. For one patient, the scan was delayed by 9 weeks. This was due to both an inability to attend on agreed dates and a late nursing HPN disconnection resulting in hospital transport being missed. All scans were performed on the same day as IF clinic appointments. No PN infusions were missed as a result of the scan. T1 mapping data were not of sufficient quality for one patient (due to scanner-related technical factors) and small bowel motility data were not obtained for two patients (due to scanning protocol errors). All other imaging data were of sufficient quality for quantification.

3.2.3. Quantitative Parameters

Median liver fat fraction was significantly higher in IFALD steatosis patients (10.90%, range 2.2–27.4%, vs non-IFALD 2.14%, range 1.4–4.2%, p = 0.032, Figure 3), but increased median liver iron concentration in IFALD steatosis patients (16.0 μmol/g, range 11.3–46.7 μmol/g vs non-IFALD 11.3 μmol/g, range 10.4–38.9 μmol/g, p = 0.222) and median liver T1 in IFALD steatosis patients (740 ms, range 594–919 ms, vs non-IFALD 715 ms, range 544–848 ms, p = 0.873) were not statistically significant. Reduced median portal vein flow in IFALD steatosis patients (56.2 mL/min/100g, range 37.5–93.0 mL/min/100g, vs non-IFALD 64.2 mL/min/100g, range 45.6–137.6 mL/min/100g, p = 0.667), estimated total liver blood flow in IFALD steatosis patients (62.1 mL/min/100g, range 27.9–119.3 mL/min/100g, vs non-IFALD 91.8 mL/min/100g, range 63.5–145.7 mL/min/100g, p = 0.151) and small bowel motility in IFALD steatosis patients (0.16 a.u., range 0.11–0.21 a.u., vs non-IFALD 0.19 a.u., range 0.07–0.21 a.u., p > 0.999) were not statistically significant (Table 6). Figure 3, Figure 4, Figure 5 and Figure 6 demonstrate examples of T2* and T1 parametric mapping (Figure 4), caval subtraction phase-contrast MRI (Figure 5) and small bowel motility studies (Figure 6).

4. Discussion

IFALD remains an important complication of chronic IF, yet agreed diagnostic criteria are lacking. In the absence of specific pharmacological interventions, intestinal transplantation is the definitive treatment, although decision making regarding the timing of transplantation can be difficult. The principle indications for transplantation in this context are progressive hepatic fibrosis or cirrhosis, for which the gold standard investigation remains liver biopsy. This procedure is associated with risk and therefore there remains a need to develop accurate non-invasive markers to stratify patients at high risk of fibrosis to inform use of liver biopsy. There has been a rapid advancement in the development of such non-invasive markers of disease progression in non-IFALD chronic liver diseases. Serum markers have been particularly widely studied, with a range of scores assessed in various pathologically distinct chronic liver diseases (Table 1). However, before considering longitudinal studies of serum markers alongside disease progression in adult IFALD, it is important to assess the utility of these markers in the diagnosis of IFALD steatosis at baseline. We therefore sought to understand the value of studying these serum scores in a larger prospective cohort by performing a retrospective study in a small single centre cohort.
Patients in our study were characterised as IFALD steatosis, in the absence of features of fibrosis, cholestasis or cirrhosis. The serum scores in Table 4 were found to be significantly elevated in the IFALD steatosis group when compared to the matched non-IFALD chronic IF group. These scores are all non-propriety and therefore can be simply calculated using routinely available laboratory tests. This appears initially counterintuitive given that these scores correlate with fibrosis to varying degrees in non-IFALD chronic liver diseases. However, the primary intention of previous association studies was with fibrosis or advanced liver disease, rather than with well-phenotyped steatosis cohorts. Additionally, it is possible that subclinical fibrosis was present in some patients in the present study; no patients had undergone prior liver biopsy. Furthermore, the pathophysiology of IFALD is much less well characterised than other chronic liver diseases. Whilst it is possible that the development of IFALD relates more closely to that of NAFLD than viral hepatitis, this has not been formally established. For example, little is known about vascular dynamics, the pathology of iron deposition, the function of hepatic stellate cells and other processes in IFALD. It is possible that some, or a combination, of these factors explain the serum score correlations found both in this small study and other non-IFALD studies.
A large range of values was observed in both groups, which may be a function of the small sample size or that subclinical fibrosis was present in some patients. The mean PN duration for the IFALD steatosis group was just over seven years, with none of the patients having progressed to fibrosis. This may be due to proactive management by the treating IF team but may also suggest that these patients had biologically ‘non-progressive’ disease, perhaps representing a more benign group than would otherwise be expected in a larger cohort. Overall, these results do suggest a larger study is warranted, particularly recruiting patients at the first point of diagnosis of IFALD steatosis, but also those with a range of hepatic injury. Further studies assessing for metabolic derangements as observed in NAFLD (e.g., insulin resistance) may be complementary.
Imaging modalities such as ultrasound, standard protocol MRI and MRCP are central in the diagnosis and surveillance of various non-IFALD chronic liver diseases. In this study, we propose a multiparametric quantitative MRI protocol that includes hepatic PDFF, T2* and T1 mapping, with caval subtraction PCMRI and small bowel cine MRI as these aim to measure liver fat, iron content, fibrosis, blood flow and small bowel motility, all of which are relevant pathophysiological factors in IFALD. This study sought to understand whether it was possible to perform multiparametric MRI in patients with chronic IF, a group who are often burdened with logistical issues impacting on clinical care, and whether recognisable outputs relating to IFALD could be obtained. We found that all patients approached proceeded to consent for the study and successfully underwent scanning with a high proportion of quantitative MRI parameters obtained. This required a proactive approach from the clinical and radiological teams: arranging scans on the same day as other hospital visits to minimise disruption, prioritising afternoon appointments to allow sufficient travel time after morning HPN disconnections, etc. Patients found the investigation acceptable and did not experience any adverse events relating to PN administration or venous catheters.
MRI PDFF measurements confirmed expected significant steatosis in the IFALD steatosis group, with four out of five in the IFALD steatosis group meeting the diagnostic criteria for non-alcoholic fatty liver disease (>5% as per guidelines [71]), but no statistically significant differences were observed with other quantitative MRI parameters.
Liver iron concentration measurements confirmed no significant iron overload in either group, which may reflect active clinical management of patient nutritional requirements. Historically, long-term PN has been associated with iron overload [85] but, more recently, PN-related iron deficiencies [86] have also been reported in the literature. It is worth noting that infusions of ferric compounds (and secondarily high ferritin levels) have been shown to affect MRI signal in patients receiving HPN [67]. The relationship between IFALD and liver iron concentration remains unclear, but a mechanistic overlap between the onset of hepatic steatosis and siderosis has been reported [87] and may yet be relevant as understanding of IFALD increases.
Liver T1, a measure of liver fibrosis, was also expectably similar in both groups and within previously reported ranges for non-fibrotic liver [88], confirming that none of the patients had progressed to fibrosis.
The relationship between hepatic blood flow measurements and CLD are complex, not least because short-term fluctuations in portal venous flow are closely related to prandial state [89,90]. Hepatic blood flow measurements are therefore normally made in the fasted state, but in this study, logistic factors were prioritised over ensuring a 4-h interval after HPN disconnection. Measures such as portal vein flow may also be significantly affected by extra-hepatic factors such as small bowel length or PN duration, neither of which were controlled for between groups. Pre-clinical studies and studies in patients with chronic liver disease have demonstrated PN-related reductions in portal vein flow [91,92]. Our study demonstrated lower caval subtraction phase-contrast MRI measurements of portal vein and total liver blood flow in IFALD steatosis patients, but these differences were not statistically significant. A wide variance of portal vein flow measurements and propagated errors in the caval subtraction phase-contrast MRI measurements [83] make these measurements prone to sample size-related type I/II errors.
Bowel motility disorders are a cause of IF and have been associated with IFALD [93]. Although short bowel syndrome patients are also likely to have abnormal small bowel motility [80], no formal quantitative studies have been reported. Abnormal intestinal motility is known to predispose to bacterial overgrowth [94], which in turn has been associated with the severity of chronic liver disease [95]. Here, we did not demonstrate any difference in MR small bowel motility in patients with IFALD steatosis, indeed reported values in both patient groups were similar to those previously reported in healthy volunteers [84]. Whilst this may reflect the mild severity of liver disease in our MRI study or variations in other factors including medications, this finding (while negative) is itself of interest in the broader context of IF.
In this exploratory study, we have proposed a range of quantitative MRI techniques, but these are not exhaustive and other quantitative methods, such as intra-voxel incoherent motion, tissue perfusion measurement using dynamic contrast enhanced/arterial spin labelling and MR elastography may also have a place in the diagnosis and surveillance of IFALD.
Although multiparametric MRI has greater resource implications than ultrasound, it provides more comprehensive information that may be useful particularly as our understanding and diagnostic criteria for IFALD evolve. Most hospitals have access to MRI scanning and more complex post-processing requirements could be met by data sharing and centralised data analysis protocols. It may be worthwhile, therefore, given this general applicability, to formally investigate the role of this MRI in the diagnosis of IFALD steatosis and IFALD fibrosis in a prospective study. Indeed, it is possible that composite scoring using combinations of serum markers as presented here with MRI outputs may prove more valuable than either alone.
The limitations of this study include the retrospective design, small sample sizes and single centre cohort. The cohort sizes did not allow for matching of many variables. Hepatic transient elastography is not routinely performed for patients with IFALD at our hospital and so it was not possible to correlate with serum scores. Ideally, even feasibility studies would typically involve greater numbers of participants but the overall numbers of patients with IFALD in any one centre will not be sufficiently high to allow for this. Selection bias was minimised by not excluding patients without available liver histology which would potentially involve only the most severe cases.

5. Conclusions

In conclusion, non-invasive diagnosis and monitoring of IFALD is an important unmet clinical need. There has been rapid development of non-invasive monitoring in non-IFALD chronic liver diseases. Given the pathological overlap with IFALD, it would seem reasonable to extend the study of IFALD markers to this group. A multiparametric IFALD-specific quantitative MRI protocol is an attractive potential imaging modality in IFALD, and this study suggests it is feasible to perform in patients on HPN. Indeed, imaging outputs may be complementary to serum scoring. Validating the associations of serum markers used here and examining the utility of multiparametric MRI in a larger prospective study would be a valuable exercise. This should ideally be on a national, multicentre basis given the insufficient numbers of patients with distinct IFALD pathologies in any single unit for meaningful analysis.

Author Contributions

Conceptualization, M.C.P.B., S.A.T., S.D.C., F.R., J.M., M.D.C. and S.M.; Data curation, M.C.P.B. and M.D.C.; Formal analysis, K.C.F., M.C.P.B., F.T., M.D.C. and S.M.; Investigation, K.C.F., M.C.P.B., S.K., L.C., A.M., A.B., F.T. and S.M.; Methodology, K.C.F., M.C.P.B., S.K., L.C., A.M., A.B., S.A.T., F.T., T.K., S.D.C., F.R., J.M., M.D.C. and S.M.; Project administration, M.C.P.B. and S.M.; Software, M.D.C.; Supervision, M.D.C. and S.M.; Visualization, K.C.F., M.C.P.B., F.T. and M.D.C.; Writing—original draft, K.C.F., M.C.P.B., S.D.C., F.R., J.M., M.D.C. and S.M.; Writing—review & editing, K.C.F., S.K., L.C., A.M., A.B., S.A.T., F.T., T.K., S.D.C., F.R., J.M., M.D.C. and S.M. All authors have read and agreed to the published version of the manuscript.

Funding

The authors acknowledge the support of the UCLH NIHR Biomedical Research Centre. Tomoko Kumagai was funded by the Medical Research Council (MRC grant code MR/R001901/1).

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Appendix A.1. MRI Image Acquisition

All imaging was performed on a Philips Ingenia 3T scanner (Best, Netherlands), with a 16-channel body coil (SENSE XL Torso, Philips Healthcare, Best, Netherlands). All scanning was undertaken by a radiographer (L.C.) with over 5 years of experience in abdominal imaging and trained in planning caval subtraction phase-contrast MRI studies.

Appendix A.1.1. Anatomical Imaging

Coronal (upper abdominal), sagittal (through the abdominal greater vessels) and axial breath-hold balanced steady-state free precession images were obtained for anatomical planning (repetition time 2.47 ms, echo time 1.23 ms, 45° flip angle, 352 × 352 matrix size, 0.994 × 0.994 mm pixel spacing, 5 mm slice thickness, 5.5 mm slice gap).

Appendix A.1.2. Proton Density Fat Fraction/T2* Mapping

Proprietary manufacturer-supplied proton density fat fraction (PDFF) sequences (mDixon Quant, Philips Healthcare, Best, Netherlands) were used. A single breath-hold three dimensional six-echo spoiled gradient echo sequence with bipolar readout (first echo time 0.99 ms, echo spacing 0.71 ms, repetition time 5.7 ms, 3° flip angle, 256 × 256 matrix size, 1.56 × 1.56 mm pixel spacing and SENSE factor 2) with signal corrected for T2* decay and complex fitting to a multipeak model of human adipose tissue to generate PDFF maps. Imaging was planned axially through the liver with 6 mm slice thickness, enabling whole-liver coverage within 20 s. Reconstructed volumes included both the PDFF and T2* maps.

Appendix A.1.3. T1 Mapping

T1 mapping was based on previously described methods [82]. Inversion recovery single-shot spin-echo with spectral fat presaturation images were obtained at six different inversion times (2000, 1000, 500, 300, 200 and 100 ms), with echo time 45 ms, repetitions times up to 16.5 s, 90˚ flip angle, 512 × 512 matrix size, 0.78 × 0.78 mm pixel spacing and SENSE factor 5.2. Twenty coronal slices (5 mm slice thickness, 6 mm slice gap), centred on the porta hepatis were obtained at each inversion time, with each volume obtained in breath-hold within 33 s.

Appendix A.1.4. Phase-Contrast MRI

Caval subtraction phase-contrast MRI was undertaken as reported previously [83]. Two-dimensional phase-contrast MRI in expiratory breath-hold with retrospective cardiac gating was planned in 2 planes for each measurement (repetition time 8.7 ms, echo time 5.22 ms, 10° flip angle, 336 × 336 matrix size, 0.808 × 0.625 mm pixel spacing, 5 mm slice thickness with 7 cardiac cycle phases). Phase-contrast MRI studies were performed through the portal vein (velocity encoding setting = 40 cm/s), infrahepatic inferior vena cava (above the renal veins, below the hepatic inferior vena cava)(velocity encoding setting = 60 cm/s) and suprahepatic inferior vena cava (above the hepatic venous inflow but below the right atrial junction) (velocity encoding setting = 80 cm/s). At the time of acquisition, images were reviewed for aliasing and velocity encoding settings were increased by 20 cm/s when appropriate. Phase maps acquired at each velocity encoding setting in opposite flow encoding direction were subtracted for correction of background phase errors, assuming stationary spin phase was identical in each image. Eddy current-induced phase errors were corrected using local phase correction filters. Acquisition time for each measurement was less than 20 s and each measurement was repeated 3 times.

Appendix A.1.5. Small Bowel Motility

Small bowel motility was imaged as reported previously [84] using an expiratory breath-hold cine three dimensional balanced fast field echo sequence (repetition time 3.7 ms, echo time 1.9 ms, 20° flip angle, 432 × 432 matrix size, 2.5 × 2.5 mm pixel spacing, 5 mm slice thickness, 5.5 mm slice gap with a temporal resolution of 1 volume per second over a 20 s breath-hold). Imaging was planned in the sagittal plane with coverage of the entire small bowel volume.

Appendix A.2. MRI Image Post-Processing

All ROI placement and segmentation was undertaken by a hepato-pancreatico-biliary radiologist (M.D.C.) with over 10 years of experience in abdominal imaging, blinded to patient group.

Appendix A.2.1. Proton Density Fat Fraction/T2* Mapping

PDFF and T2* maps were analysed offline using in-house developed Matlab code (Mathworks, Natick, Mass, USA). Circular ROIs measuring up to 20mm in diameter were placed on each of the Couinaud liver segments taking care to avoid vessels and biliary structures. ROIs were co-localised on PDFF and T2* maps, and T2* measurements were converted in liver iron concentration (μmol/g) [75]. Averages of all segmental ROIs were used as global hepatic fat fraction or liver iron concentration measurements.

Appendix A.2.2. T1 Mapping

Imaged liver volumes at each inversion time were slice-wise co-registered using FSL-FLIRT with manually segmented liver masks. Pixel-wise fitting of registered signal was then undertaken to convert data into a single T1 volume. In-house developed Matlab code (Mathworks, Natick, Mass, USA) was used to place circular ROIs measuring up to 20 mm in diameter on each of the Couinaud liver segments taking care to avoid vessels and biliary structures. Averages of all segmental ROIs were used to estimate global hepatic parenchymal T1.

Appendix A.2.3. Phase-Contrast MRI

Phase-contrast MRI post-processing was undertaken as previously [83]. Bulk vessel flow was quantified using freely available software (Segment Medviso, Lund, Sweden). Manually placed ROIs were used for vessel segmentation, with semi-automated propagation onto subsequent frames of the cardiac cycle, followed by review and manual correction where needed. The mean of triplicate bulk flow measurements was used for analysis. Using the principle of conservation of mass, total liver blood flow was estimated by measuring hepatic venous outflow by subtracting bulk flow in the infrahepatic inferior vena cava from bulk flow in the suprahepatic inferior vena cava. Liver volume was estimated by manual hepatic segmentation on coronal anatomical steady-state free precession images, using ITK-SNAP (National Institute of Health (NIH), Pennsylvania, USA). A tissue density of 1.0 g/mL was assumed [96] and all phase-contrast MRI bulk flow measurements were normalised to liver weight/volume.

Appendix A.2.4. Small Bowel Motility

Small bowel motility was quantified as previously [84]. ROIs were drawn manually over the small bowel avoiding solid organs, colon, stomach and mesenteric structures between bowel loops on the first frame of cine balanced fast field echo images (ITK-SNAP, NIH, Pennsylvania, USA). Pixel-wise motion was quantified using the standard deviation over time of the pixel’s Jacobian determinant. Small bowel segmentation masks were co-localised to motility maps, with the average of all small bowel ROIs regarded as the global small bowel motility score.

References

  1. Pironi, L.; Arends, J.; Bozzetti, F.; Cuerda, C.; Gillanders, L.; Jeppesen, P.B.; Joly, F.; Kelly, D.; Lal, S.; Staun, M.; et al. ESPEN guidelines on chronic intestinal failure in adults. Clin. Nutr. 2016, 35, 247–307. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Sasdelli, A.S.; Agostini, F.; Pazzeschi, C.; Guidetti, M.; Lal, S.; Pironi, L. Assessment of Intestinal Failure Associated Liver Disease according to different diagnostic criteria. Clin. Nutr. 2019, 38, 1198–1205. [Google Scholar] [CrossRef] [PubMed]
  3. Lal, S.; Pironi, L.; Wanten, G.; Arends, J.; Bozzetti, F.; Cuerda, C.; Joly, F.; Kelly, D.; Staun, M.; Szczepanek, K.; et al. Clinical approach to the management of Intestinal Failure Associated Liver Disease (IFALD) in adults: A position paper from the Home Artificial Nutrition and Chronic Intestinal Failure Special Interest Group of ESPEN. Clin. Nutr. 2018, 37, 1794–1797. [Google Scholar] [CrossRef]
  4. Pironi, L.; Goulet, O.; Buchman, A.; Messing, B.; Gabe, S.; Candusso, M.; Bond, G.; Gupte, G.; Pertkiewicz, M.; Steiger, E.; et al. Outcome on home parenteral nutrition for benign intestinal failure: A review of the literature and benchmarking with the European prospective survey of ESPEN. Clin. Nutr. 2012, 31, 831–845. [Google Scholar] [CrossRef]
  5. Hagi, A.; Nakayama, M.; Shinzaki, W.; Haji, S.; Ohyanagi, H. Effects of the ω-6:ω-3 Fatty acid ratio of fat emulsions on the fatty acid composition in cell membranes and the anti-inflammatory action. JPEN J. Parenter. Enteral Nutr. 2010, 34, 263–270. [Google Scholar] [CrossRef]
  6. Dupont, I.E. Peroxidation of lipid emulsions: Effects of changes in fatty acid pattern and α-tocopherol content on the sensitivity to peroxidative damage. Clin. Nutr. 1999, 18, 113–116. [Google Scholar] [CrossRef]
  7. Mutanen, A.; Nissinen, M.J.; Lohi, J.; Heikkilä, P.; Gylling, H.; Pakarinen, M.P. Serum plant sterols, cholestanol, and cholesterol precursors associate with histological liver injury in pediatric onset intestinal failure. Am. J. Clin. Nutr. 2014, 100, 1085–1094. [Google Scholar] [CrossRef] [Green Version]
  8. Raman, M.; Almutairdi, A.; Mulesa, L.; Alberda, C.; Beattie, C.; Gramlich, L. Parenteral nutrition and lipids. Nutrients 2017, 9, 388. [Google Scholar] [CrossRef] [Green Version]
  9. Zaman, N.; Tam, Y.K.; Jewell, L.D.; Coutts, R.T. Effects of intravenous lipid as a source of energy in parenteral nutrition associated hepatic dysfunction and lidocaine elimination: A study using isolated rat liver perfusion. Biopharm. Drug Dispos. 1997, 18, 803–819. [Google Scholar] [CrossRef]
  10. Christensen, R.D.; Henry, E.; Wiedmeier, S.E.; Burnett, J.; Lambert, D.K. Identifying patients, on the first day of life, at high-risk of developing parenteral nutrition-associated liver disease. J. Perinatol. 2007, 27, 284–290. [Google Scholar] [CrossRef] [Green Version]
  11. Hwang, T.L.; Lue, M.C.; Chen, L.L. Early use of cyclic TPN prevents further deterioration of liver functions for the TPN patients with impaired liver function. Hepatogastroenterology 2000, 47, 1347–1350. [Google Scholar] [PubMed]
  12. Jensen, A.R.; Goldin, A.B.; Koopmeiners, J.S.; Stevens, J.; Waldhausen, J.H.T.; Kim, S.S. The association of cyclic parenteral nutrition and decreased incidence of cholestatic liver disease in patients with gastroschisis. J. Pediatr. Surg. 2009, 44, 183–189. [Google Scholar] [CrossRef] [PubMed]
  13. Stout, S.M.; Cober, M.P. Metabolic effects of cyclic parenteral nutrition infusion in adults and children. Nutr. Clin. Pract. 2010, 25, 277–281. [Google Scholar] [CrossRef] [PubMed]
  14. Lacaille, F.; Gupte, G.; Colomb, V.; D’antiga, L.; Hartman, C.; Hojsak, I.; Kolacek, S.; Puntis, J.; Shamir, R. Intestinal failure-associated liver disease: A position paper of the ESPGHAN working group of intestinal failure and intestinal transplantation. J. Pediatr. Gastroenterol. Nutr. 2015, 60, 272–283. [Google Scholar] [CrossRef] [Green Version]
  15. Slagle, T.A.; Gross, S.J. Effect of early low-volume enteral substrate on subsequent feeding tolerance in very low birth weight infants. J. Pediatr. 1988, 113, 526–531. [Google Scholar] [CrossRef]
  16. McClure, R.J.; Newell, S.J. Randomised controlled study of clinical outcome following trophic feeding. Arch. Dis. Child. Fetal Neonatal Ed. 2000, 82, F29–F33. [Google Scholar] [CrossRef] [Green Version]
  17. Hermans, D.; Talbotec, C.; Lacaille, F.; Goulet, O.; Ricour, C.; Colomb, V. Early central catheter infections may contribute to hepatic fibrosis in children receiving long-term parenteral nutrition. J. Pediatr. Gastroenterol. Nutr. 2007, 44, 459–463. [Google Scholar] [CrossRef]
  18. Cahova, M.; Bratova, M.; Wohl, P. Parenteral nutrition-associated liver disease: The role of the gut microbiota. Nutrients 2017, 9, 987. [Google Scholar] [CrossRef] [Green Version]
  19. Lee, W.S.; Sokol, R.J. Intestinal Microbiota, Lipids, and the Pathogenesis of Intestinal Failure-Associated Liver Disease. J. Pediatr. 2015, 167, 519–526. [Google Scholar] [CrossRef] [Green Version]
  20. Luman, W.; Shaffer, J.L. Prevalence, outcome and associated factors of deranged liver function tests in patients on home parenteral nutrition. Clin. Nutr. 2002, 21, 337–343. [Google Scholar] [CrossRef]
  21. Lloyd, D.A.J.; Zabron, A.A.; Gabe, S.M. Chronic biochemical cholestasis in patients receiving home parenteral nutrition: Prevalence and predisposing factors. Aliment. Pharmacol. Ther. 2008, 27, 552–560. [Google Scholar] [CrossRef] [PubMed]
  22. Cavicchi, M.; Beau, P.; Crenn, P.; Degott, C.; Messing, B. Prevalence of liver disease and contributing factors in patients receiving home parenteral nutrition for permanent intestinal failure. Ann. Intern. Med. 2000, 132, 525–532. [Google Scholar] [CrossRef] [PubMed]
  23. Cazals-Hatem, D.; Billiauws, L.; Rautou, P.E.; Bondjemah, V.; Poté, N.; Corcos, O.; Paradis, V.; Joly, F. Ultra-short bowel is an independent risk factor for liver fibrosis in adults with home parenteral nutrition. Liver Int. 2018, 38, 174–182. [Google Scholar] [CrossRef] [PubMed]
  24. Kaufman, S.S.; Loseke, C.A.; Lupo, J.V.; Young, R.J.; Murray, N.D.; Pinch, L.W.; Vanderhoof, J.A. Influence of bacterial overgrowth and intestinal inflammation on duration of parenteral nutrition in children with short bowel syndrome. J. Pediatr. 1997, 131, 356–361. [Google Scholar] [CrossRef]
  25. Kelly, D.A. Intestinal failure-associated liver disease: What do we know today? Gastroenterology 2006, 130, S70–S77. [Google Scholar] [CrossRef]
  26. Rangel, S.J.; Calkins, C.M.; Cowles, R.A.; Barnhart, D.C.; Huang, E.Y.; Abdullah, F.; Arca, M.J.; Teitelbaum, D.H. Parenteral nutrition-associated cholestasis: An American pediatric surgical association outcomes and clinical trials committee systematic review. J. Pediatr. Surg. 2012, 47, 225–240. [Google Scholar] [CrossRef]
  27. Fiel, M.I.; Wu, H.S.; Iyer, K.; Rodriguez-Laiz, G.; Schiano, T.D. Rapid reversal of parenteral-nutrition-associated cirrhosis following isolated intestinal transplantation. J. Gastrointest. Surg. 2009, 13, 1717–1723. [Google Scholar] [CrossRef]
  28. Leggett, G.; Butler, A.; Massey, D.; Middleton, S.; Russell, N.; Woodward, J.; Green, J.; Bond, D.; Duncan, S.; Woolner, L.; et al. A summary of 10 years of transplant activity and outcomes from a UK centre for intestinal and multivisceral transplantation. Clin. Nutr. 2018, 37, S304. [Google Scholar] [CrossRef]
  29. Woodward, J.M.; Massey, D.; Sharkey, L. The Long and Short of IT: Intestinal failure-associated liver disease (IFALD) in adults—Recommendations for early diagnosis and intestinal transplantation. Frontline Gastroenterol. 2020, 11, 34–39. [Google Scholar] [CrossRef] [Green Version]
  30. Naini, B.V.; Lassman, C.R. Total parenteral nutrition therapy and liver injury: A histopathologic study with clinical correlation. Hum. Pathol. 2012, 43, 826–833. [Google Scholar] [CrossRef]
  31. Buchman, A.L.; Ament, M.E.; Sohel, M.; Dubin, M.; Jenden, D.J.; Roch, M.; Pownall, H.; Farley, W.; Awal, M.; Ahn, C. Choline deficiency causes reversible hepatic abnormalities in patients receiving parenteral nutrition: Proof of a human choline requirement: A placebo-controlled trial. JPEN J. Parenter. Enteral Nutr. 2001, 25, 260–268. [Google Scholar] [CrossRef] [PubMed]
  32. Picasso, M.C.; Fragkos, K.; Di Caro, S.; Rahman, F.; McNaughton, J.; Mehta, S.J. Composite serum liver Fibrosis/Cirrhosis scores may be associated with parenchymal liver disease in patients with chronic intestinal failure. Clin. Nutr. 2018, 37, S300. [Google Scholar] [CrossRef]
  33. Lin, Z.H.; Xin, Y.N.; Dong, Q.J.; Wang, Q.; Jiang, X.J.; Zhan, S.H.; Sun, Y.; Xuan, S.Y. Performance of the aspartate aminotransferase-to-platelet ratio index for the staging of hepatitis C-related fibrosis: An updated meta-analysis. Hepatology 2011, 53, 726–736. [Google Scholar] [CrossRef] [PubMed]
  34. Wai, C.T.; Greenson, J.K.; Fontana, R.J.; Kalbfleisch, J.D.; Marrero, J.A.; Conjeevaram, H.S.; Lok, A.S.F. A simple noninvasive index can predict both significant fibrosis and cirrhosis in patients with chronic hepatitis C. Hepatology 2003, 38, 518–526. [Google Scholar] [CrossRef] [Green Version]
  35. Shaheen, A.A.M.; Myers, R.P. Diagnostic accuracy of the aspartate aminotransferase-to-platelet ratio index for the prediction of hepatitis C-related fibrosis: A systematic review. Hepatology 2007, 46, 912–921. [Google Scholar] [CrossRef]
  36. Mummadi, R.R.; Petersen, J.R.; Xiao, S.Y.; Snyder, N. Role of simple biomarkers in predicting fibrosis progression in HCV infection. World J. Gastroenterol. 2010, 16, 5710–5715. [Google Scholar] [CrossRef]
  37. Snyder, N.; Gajula, L.; Xiao, S.Y.; Grady, J.; Luxon, B.; Lau, D.T.Y.; Soloway, R.; Petersen, J. APRI: An easy and validated predictor of hepatic fibrosis in chronic hepatitis C. J. Clin. Gastroenterol. 2006, 40, 535–542. [Google Scholar] [CrossRef]
  38. Kruger, F.C.; Daniels, C.R.; Kidd, M.; Swart, G.; Brundyn, K.; van Rensburg, C.; Kotze, M. APRI: A simple bedside marker for advanced fibrosis that can avoid liver biopsy in patients with NAFLD/NASH. S. Afr. Med. J. 2011, 101, 477–480. [Google Scholar]
  39. Yilmaz, Y.; Yonal, O.; Kurt, R.; Bayrak, M.; Aktas, B.; Ozdogan, O. Noninvasive assessment of liver fibrosis with the aspartate transaminase to platelet ratio index (APRI): Usefulness in patients with chronic liver disease: APRI in chronic liver disease. Hepat. Mon. 2011, 11, 103. [Google Scholar]
  40. Rumbo, C.; Martinez, M.I.; Cabanne, A.; Trentadue, J.; Fernández, A.; Gondolesi, G. Utility of Aminotransferase/Platelet Ratio Index to Predict Liver Fibrosis in Intestinal Failure-Associated Liver Disease in Pediatric Patients. JPEN J. Parenter. Enteral Nutr. 2017, 41, 884–889. [Google Scholar] [CrossRef]
  41. Díaz, J.J.; Gura, K.M.; Roda, J.; Perez-Atayde, A.R.; Duggan, C.; Jaksic, T.; Lo, C.W. Aspartate aminotransferase to platelet ratio index correlates with hepatic cirrhosis but not with fibrosis in pediatric patients with intestinal failure. J. Pediatr. Gastroenterol. Nutr. 2013, 57, 367–371. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  42. Hukkinen, M.; Mutanen, A.; Nissinen, M.; Merras-Salmio, L.; Gylling, H.; Pakarinen, M.P. Parenteral Plant Sterols Accumulate in the Liver Reflecting Their Increased Serum Levels and Portal Inflammation in Children with Intestinal Failure. JPEN J. Parenter. Enteral Nutr. 2017, 41, 1014–1022. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  43. Mangus, R.S.; O’Connor, M.G.; Tector, A.J.; Lim, J.D.; Vianna, R.M. Use of the aspartate aminotransferase to platelet ratio index to follow liver fibrosis progression in infants with short gut. J. Pediatr. Surg. 2010, 45, 1266–1273. [Google Scholar] [CrossRef] [PubMed]
  44. Van Gossum, A.; Pironi, L.; Messing, B.; Moreno, C.; Colecchia, A.; Derrico, A.; Demetter, P.; De Gos, F.; Cazals-Halem, D.; Joly, F. Transient Elastography (FibroScan) Is Not Correlated with Liver Fibrosis but with Cholestasis in Patients with Long-Term Home Parenteral Nutrition. JPEN J. Parenter. Enteral Nutr. 2015, 39, 719–724. [Google Scholar] [CrossRef]
  45. Xiao, G.; Yang, J.; Yan, L. Comparison of diagnostic accuracy of aspartate aminotransferase to platelet ratio index and fibrosis-4 index for detecting liver fibrosis in adult patients with chronic hepatitis B virus infection: A systemic review and meta-analysis. Hepatology 2015, 61, 292–302. [Google Scholar] [CrossRef]
  46. Kim, B.K.; Kim, D.Y.; Park, J.Y.; Ahn, S.H.; Chon, C.Y.; Kim, J.K.; Paik, Y.H.; Lee, K.S.; Park, Y.N.; Han, K.H. Validation of FIB-4 and comparison with other simple noninvasive indices for predicting liver fibrosis and cirrhosis in hepatitis B virus-infected patients. Liver Int. 2010, 30, 546–553. [Google Scholar] [CrossRef]
  47. Shah, A.G.; Lydecker, A.; Murray, K.; Tetri, B.N.; Contos, M.J.; Sanyal, A.J.; Abrams, S.; Arceo, D.; Espinosa, D.; Fairly, L.; et al. Comparison of noninvasive markers of fibrosis in patients with nonalcoholic fatty liver disease. Clin. Gastroenterol. Hepatol. 2009, 7, 1104–1112. [Google Scholar] [CrossRef] [Green Version]
  48. Sterling, R.K.; Lissen, E.; Clumeck, N.; Sola, R.; Correa, M.C.; Montaner, J.; Sulkowski, M.S.; Torriani, F.J.; Dieterich, D.T.; Thomas, D.L.; et al. Development of a simple noninvasive index to predict significant fibrosis in patients with HIV/HCV coinfection. Hepatology 2006, 43, 1317–1325. [Google Scholar] [CrossRef]
  49. Kayadibi, H.; Yasar, B.; Ozkara, S.; Serdar, M.A.; Kurdas, O.O.; Gonen, C. The diagnostic accuracy of the Forns index, platelet count and AST to Platelet Ratio Index derived fibrosis index for the prediction of Hepatitis C virus-related significant liver fibrosis and cirrhosis. Scand. J. Clin. Lab. Investig. 2014, 74, 240–247. [Google Scholar] [CrossRef]
  50. Wong, G.L.H.; Wong, V.W.S.; Choi, P.C.L.; Chan, A.W.H.; Chan, H.L.Y. Development of a non-invasive algorithm with transient elastography (Fibroscan) and serum test formula for advanced liver fibrosis in chronic hepatitis B. Aliment. Pharmacol. Ther. 2010, 31, 1095–1103. [Google Scholar] [CrossRef]
  51. Forns, X.; Ampurdanès, S.; Llovet, J.M.; Aponte, J.; Quintó, L.; Martínez-Bauer, E.; Bruguera, M.; Sánchez-Tapias, J.M.; Rodés, J. Identification of chronic hepatitis C patients without hepatic fibrosis by a simple predictive model. Hepatology 2002, 36, 986–992. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  52. Mayo, M.J.; Parkes, J.; Adams-Huet, B.; Combes, B.; Mills, A.S.; Markin, R.S.; Rubin, R.; Wheeler, D.; Contos, M.; West, A.B.; et al. Prediction of clinical outcomes in primary biliary cirrhosis by serum enhanced liver fibrosis assay. Hepatology 2008, 48, 1549–1557. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  53. Lichtinghagen, R.; Pietsch, D.; Bantel, H.; Manns, M.P.; Brand, K.; Bahr, M.J. The Enhanced Liver Fibrosis (ELF) score: Normal values, influence factors and proposed cut-off values. J. Hepatol. 2013, 59, 236–242. [Google Scholar] [CrossRef] [PubMed]
  54. Xie, Q.; Zhou, X.; Huang, P.; Wei, J.; Wang, W.; Zheng, S. The performance of enhanced liver fibrosis (ELF) test for the staging of liver fibrosis: A meta-analysis. PLoS ONE 2014, 9, e92772. [Google Scholar] [CrossRef] [PubMed]
  55. Fagan, K.J.; Pretorius, C.J.; Horsfall, L.U.; Irvine, K.M.; Wilgen, U.; Choi, K.; Fletcher, L.M.; Tate, J.; Melino, M.; Nusrat, S.; et al. ELF score ≥9.8 indicates advanced hepatic fibrosis and is influenced by age, steatosis and histological activity. Liver Int. 2015, 35, 1673–1681. [Google Scholar] [CrossRef]
  56. Guha, I.N.; Parkes, J.; Roderick, P.; Chattopadhyay, D.; Cross, R.; Harris, S.; Kaye, P.; Burt, A.D.; Ryder, S.D.; Aithal, G.P.; et al. Noninvasive markers of fibrosis in nonalcoholic fatty liver disease: Validating the European Liver Fibrosis Panel and exploring simple markers. Hepatology 2007, 47, 455–460. [Google Scholar] [CrossRef]
  57. Lemoine, M.; Shimakawa, Y.; Nayagam, S.; Khalil, M.; Suso, P.; Lloyd, J.; Goldin, R.; Njai, H.F.; Ndow, G.; Taal, M.; et al. The gamma-glutamyl transpeptidase to platelet ratio (GPR) predicts significant liver fibrosis and cirrhosis in patients with chronic HBV infection in West Africa. Gut 2016, 65, 1369–1376. [Google Scholar] [CrossRef] [Green Version]
  58. Angulo, P.; Hui, J.M.; Marchesini, G.; Bugianesi, E.; George, J.; Farrell, G.C.; Enders, F.; Saksena, S.; Burt, A.D.; Bida, J.P.; et al. The NAFLD fibrosis score: A noninvasive system that identifies liver fibrosis in patients with NAFLD. Hepatology 2007, 45, 846–854. [Google Scholar] [CrossRef]
  59. Aykut, U.E.; Akyuz, U.; Yesil, A.; Eren, F.; Gerin, F.; Ergelen, R.; Celikel, C.A.; Yilmaz, Y. A comparison of fibrometerTM NAFLD score, NAFLD fibrosis score, and transient elastography as noninvasive diagnostic tools for hepatic fibrosis in patients with biopsy-proven non-alcoholic fatty liver disease. Scand. J. Gastroenterol. 2014, 49, 1343–1348. [Google Scholar] [CrossRef]
  60. Treeprasertsuk, S.; Björnsson, E.; Enders, F.; Suwanwalaikorn, S.; Lindor, K.D. NAFLD fibrosis score: A prognostic predictor for mortality and liver complications among NAFLD patients. World J. Gastroenterol. 2013, 19, 1219–1229. [Google Scholar] [CrossRef]
  61. Friedrich-Rust, M.; Rosenberg, W.; Parkes, J.; Herrmann, E.; Zeuzem, S.; Sarrazin, C. Comparison of ELF, FibroTest and FibroScan for the non-invasive assessment of liver fibrosis. BMC Gastroenterol. 2010, 10. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  62. Poynard, T.; Morra, R.; Halfon, P.; Castera, L.; Ratziu, V.; Imbert-Bismut, F.; Naveau, S.; Thabut, D.; Lebrec, D.; Zoulim, F.; et al. Meta-analyses of FibroTest diagnostic value in chronic liver disease. BMC Gastroenterol. 2007, 7. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  63. Calès, P.; Lainé, F.; Boursier, J.; Deugnier, Y.; Moal, V.; Oberti, F.; Hunault, G.; Rousselet, M.C.; Hubert, I.; Laafi, J.; et al. Comparison of blood tests for liver fibrosis specific or not to NAFLD. J. Hepatol. 2009, 50, 165–173. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  64. Adams, L.A.; Bulsara, M.; Rossi, E.; DeBoer, B.; Speers, D.; George, J.; Kench, J.; Farrell, G.; McCaughan, G.W.; Jeffrey, G.P. Hepascore: An accurate validated predictor of liver fibrosis in chronic hepatitis C infection. Clin. Chem. 2005, 51, 1867–1873. [Google Scholar] [CrossRef]
  65. Strauss, S.; Gavish, E.; Gottlieb, P.; Katsnelson, L. Interobserver and intraobserver variability in the sonographic assessment of fatty liver. Am. J. Roentgenol. 2007, 189, 1449. [Google Scholar] [CrossRef]
  66. Cengiz, M.; Sentürk, S.; Cetin, B.; Bayrak, A.H.; Bilek, S.U. Sonographic assessment of fatty liver: Intraobserver and interobserver variability. Int. J. Clin. Exp. Med. 2014, 7, 5453–5460. [Google Scholar]
  67. Huijbers, A.; Wanten, G.; Dekker, H.M.; van der Graaf, M. Noninvasive Quantitative Assessment of Hepatic Steatosis by Proton Magnetic Resonance Spectroscopy Among Adult Patients Receiving Home Parenteral Nutrition. JPEN J. Parenter. Enteral Nutr. 2018, 42, 778–785. [Google Scholar] [CrossRef] [Green Version]
  68. Weijers, G.; Wanten, G.; Thijssen, J.M.; van der Graaf, M.; de Korte, C.L. Quantitative Ultrasound for Staging of Hepatic Steatosis in Patients on Home Parenteral Nutrition Validated with Magnetic Resonance Spectroscopy: A Feasibility Study. Ultrasound Med. Biol. 2016, 42, 637–644. [Google Scholar] [CrossRef]
  69. Bond, A.; Hayes, S.; Abraham, A.; Teubner, A.; Farrer, K.; Pironi, L.; Lal, S. Reversal of intestinal failure associated liver disease fibrosis in a patient receiving long term home parenteral nutrition. Clin. Nutr. ESPEN 2018, 28, 228–231. [Google Scholar] [CrossRef]
  70. Lawrence, A.E.; Dienhart, M.; Cooper, J.N.; Lodwick, D.; Lopez, J.J.; Fung, B.; Smith, S.; Warren, P.; Mezoff, E.; Balint, J.; et al. Ultrasound Elastography as a Non-Invasive Method to Monitor Liver Disease in Children with Short Bowel Syndrome: Updated Results. J. Pediatr. Surg. 2019, 54, 1179–1183. [Google Scholar] [CrossRef]
  71. Marchesini, G.; Day, C.P.; Dufour, J.F.; Canbay, A.; Nobili, V.; Ratziu, V.; Tilg, H.; Roden, M.; Gastaldelli, A.; Yki-Järvinen, H.; et al. EASL-EASD-EASO Clinical Practice Guidelines for the Management of Non-Alcoholic Fatty Liver Disease. Obes. Facts 2016, 9, 65–90. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  72. Jordan, T.; Popovič, P.; Rotovnik Kozjek, N. Liver steatosis in adult patients on home parenteral nutrition. Eur. J. Clin. Nutr. 2020, 74, 255–260. [Google Scholar] [CrossRef] [PubMed]
  73. Bray, T.J.P.; Chouhan, M.D.; Punwani, S.; Bridge, A.; Hall-Craggs, M.A. Fat fraction mapping using magnetic resonance imaging: Insight into pathophysiology. Br. J. Radiol. 2018, 91, 20170344. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  74. Zummo, J.; Jeppesen, P.B.; Lin, T.; Buchman, A. P2.54 Re-analysis of a randomized placebo (PBO) controlled trial of intravenous (IV) choline chloride for IFALD using state-of-the-art analytic and imaging methods and contemporary definition of IFALD. Transplantation 2019, 103, S111. [Google Scholar] [CrossRef]
  75. Paisant, A.; D’Assignies, G.; Bannier, E.; Bardou-Jacquet, E.; Gandon, Y. MRI for the measurement of liver iron content, and for the diagnosis and follow-up of iron overload disorders. Press. Medicale 2017, 46, e279–e287. [Google Scholar] [CrossRef]
  76. Massironi, S.; Cavalcoli, F.; Rausa, E.; Invernizzi, P.; Braga, M.; Vecchi, M. Understanding short bowel syndrome: Current status and future perspectives. Dig. Liver Dis. 2020, 52, 253–261. [Google Scholar] [CrossRef] [Green Version]
  77. Bradley, C.R.; Cox, E.F.; Scott, R.A.; James, M.W.; Kaye, P.; Aithal, G.P.; Francis, S.T.; Guha, I.N. Multi-organ assessment of compensated cirrhosis patients using quantitative magnetic resonance imaging. J. Hepatol. 2018, 69, 1015–1024. [Google Scholar] [CrossRef] [Green Version]
  78. Chouhan, M.D.; Mookerjee, R.P.; Bainbridge, A.; Punwani, S.; Jones, H.; Davies, N.; Walker-Samuel, S.; Patch, D.; Jalan, R.; Halligan, S.; et al. Caval Subtraction 2D Phase-Contrast MRI to Measure Total Liver and Hepatic Arterial Blood Flow. Investig. Radiol. 2017, 52, 170–176. [Google Scholar] [CrossRef]
  79. Menys, A.; Puylaert, C.; Nolthenius, C.E.T.; Plumb, A.A.; Makanyanga, J.; Tielbeek, J.; Pendse, D.; Brosens, L.A.; Rodriguez-Justo, M.; Atkinson, D.; et al. Quantified terminal ileal motility during MR enterography as a biomarker of Crohn disease activity: Prospective multi-institution study. Radiology 2018, 289, 428–435. [Google Scholar] [CrossRef]
  80. Tappenden, K.A. Pathophysiology of short bowel syndrome: Considerations of resected and residual anatomy. JPEN J. Parenter. Enteral Nutr. 2014, 38, 14S–22S. [Google Scholar] [CrossRef]
  81. Rosenberg, W.M.C.; Voelker, M.; Thiel, R.; Becka, M.; Burt, A.; Schuppan, D.; Hubscher, S.; Roskams, T.; Pinzani, M.; Arthur, M.J.P. Serum markers detect the presence of liver fibrosis: A cohort study. Gastroenterology 2004, 127, 1704–1713. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  82. Hoad, C.L.; Palaniyappan, N.; Kaye, P.; Chernova, Y.; James, M.W.; Costigan, C.; Austin, A.; Marciani, L.; Gowland, P.A.; Guha, I.N.; et al. A study of T1 relaxation time as a measure of liver fibrosis and the influence of confounding histological factors. NMR Biomed. 2015, 28, 706–714. [Google Scholar] [CrossRef] [PubMed]
  83. Chouhan, M.D.; Mookerjee, R.P.; Bainbridge, A.; Walker-Samuel, S.; Davies, N.; Halligan, S.; Lythgoe, M.F.; Taylor, S.A. Use of caval subtraction 2d phase-contrast mr imaging to measure total liver and hepatic arterial blood flow: Preclinical validation and initial clinical translation. Radiology 2016, 280, 916–923. [Google Scholar] [CrossRef] [Green Version]
  84. de Jonge, C.S.; Menys, A.; van Rijn, K.L.; Bredenoord, A.J.; Nederveen, A.J.; Stoker, J. Detecting the effects of a standardized meal challenge on small bowel motility with MRI in prepared and unprepared bowel. Neurogastroenterol. Motil. 2019, 31, e13506. [Google Scholar] [CrossRef] [PubMed]
  85. Hariz, M.B.; Goulet, O.; De Potter, S.; Girot, M.; Rambaud, C.; Colomb, V.; Corriol, O.; Ricour, C. Iron overload in children receiving prolonged parenteral nutrition. J. Pediatr. 1993, 123, 238–241. [Google Scholar] [CrossRef]
  86. Yang, C.J.; Duro, D.; Zurakowski, D.; Lee, M.; Jaksic, T.; Duggan, C. High prevalence of multiple micronutrient deficiencies in children with intestinal failure: A longitudinal study. J. Pediatr. 2011, 159, 39–44. [Google Scholar] [CrossRef] [Green Version]
  87. Dongiovanni, P.; Fracanzani, A.L.; Fargion, S.; Valenti, L. Iron in fatty liver and in the metabolic syndrome: A promising therapeutic target. J. Hepatol. 2011, 55, 920–932. [Google Scholar] [CrossRef]
  88. Gilligan, L.A.; Dillman, J.R.; Tkach, J.A.; Xanthakos, S.A.; Gill, J.K.; Trout, A.T. Magnetic resonance imaging T1 relaxation times for the liver, pancreas and spleen in healthy children at 1.5 and 3 tesla. Pediatr. Radiol. 2019, 49, 1018–1024. [Google Scholar] [CrossRef]
  89. Chouhan, M.D.; Lythgoe, M.F.; Mookerjee, R.P.; Taylor, S.A. Vascular assessment of liver disease-towards a new frontier in MRI. Br. J. Radiol. 2016, 89, 20150675. [Google Scholar] [CrossRef]
  90. Chouhan, M.; Bainbridge, A.; Lythgoe, M.; Mookerjee, R.; Halligan, S.; Taylor, S.A. SS 4.9 The negative hepatic arterial buffer response: Pre and post-prandial changes in total liver and hepatic arterial blood flow measured using caval subtraction phase contrast MRI in normal volunteers. Insights Imaging 2017, 8, S600. [Google Scholar]
  91. Iwata, T.; Kanematsu, T. Prolonged enteral fast with parenteral nutrition decreases PCO2 and flow volume in portal vein: Its association with bile secretion. Eur. Surg. Res. 1996, 28, 146–153. [Google Scholar] [CrossRef] [PubMed]
  92. Plauth, M.; Roske, A.E.; Romaniuk, P.; Roth, E.; Ziebig, R.; Lochs, H. Post-feeding hyperammonaemia in patients with transjugular intrahepatic portosystemic shunt and liver cirrhosis: Role of small intestinal ammonia release and route of nutrient administration. Gut 2000, 46, 849–855. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  93. Cowles, R.A.; Ventura, K.A.; Martinez, M.; Lobritto, S.J.; Harren, P.A.; Brodlie, S.; Carroll, J.; Jan, D.M. Reversal of intestinal failure-associated liver disease in infants and children on parenteral nutrition: Experience with 93 patients at a referral center for intestinal rehabilitation. J. Pediatr. Surg. 2010, 45, 84–88. [Google Scholar] [CrossRef] [PubMed]
  94. Sachdev, A.H.; Pimentel, M. Gastrointestinal bacterial overgrowth: Pathogenesis and clinical significance. Ther. Adv. Chronic Dis. 2013, 4, 223–231. [Google Scholar] [CrossRef]
  95. Pande, C.; Kumar, A.; Sarin, S.K. Small-intestinal bacterial overgrowth in cirrhosis is related to the severity of liver disease. Aliment. Pharmacol. Ther. 2009, 29, 1273–1281. [Google Scholar] [CrossRef]
  96. Kuo, P.C.; Li, K.; Alfrey, E.J.; Jeffrey, R.B.; Garcia, G.; Dafoe, D.C. Magnetic resonance imaging and hepatic hemodynamics: Correlation with metabolic function in liver transplantation candidates. Surgery 1995, 117, 373–379. [Google Scholar] [CrossRef]
Figure 1. Comparison of liver scores between Intestinal Failure-Associated Liver Disease (IFALD) patients and non-IFALD patients, with respect to (A) Enhanced Liver Fibrosis (ELF); (B) Aspartate transaminase-to-Platelet Ratio Index (APRI); (C) Fibrosis 4 (FIB-4); (D) Forns Index; (E) Gamma-glutamyl transferase-to-Platelet Ratio (GPR); and (F) Fibrosis Index.
Figure 1. Comparison of liver scores between Intestinal Failure-Associated Liver Disease (IFALD) patients and non-IFALD patients, with respect to (A) Enhanced Liver Fibrosis (ELF); (B) Aspartate transaminase-to-Platelet Ratio Index (APRI); (C) Fibrosis 4 (FIB-4); (D) Forns Index; (E) Gamma-glutamyl transferase-to-Platelet Ratio (GPR); and (F) Fibrosis Index.
Nutrients 12 02151 g001
Figure 2. Magnetic resonance imaging (MRI) cohort flow chart.
Figure 2. Magnetic resonance imaging (MRI) cohort flow chart.
Nutrients 12 02151 g002
Figure 3. Axial MRI Proton Density Fat Fraction map examples from (A) non-IFALD and (B) IFALD steatosis patients. Average liver fat fraction was (A) 1.4% for the non-IFALD patient as represented by the darker liver parenchyma and (B) 27.4% for the IFALD steatosis patient as represented by the brighter liver parenchyma. Note the striking disparity in subcutaneous adiposity between patients.
Figure 3. Axial MRI Proton Density Fat Fraction map examples from (A) non-IFALD and (B) IFALD steatosis patients. Average liver fat fraction was (A) 1.4% for the non-IFALD patient as represented by the darker liver parenchyma and (B) 27.4% for the IFALD steatosis patient as represented by the brighter liver parenchyma. Note the striking disparity in subcutaneous adiposity between patients.
Nutrients 12 02151 g003
Figure 4. Parametric mapping of (A) liver T2* (axial) and (B) liver T1 (coronal). Segmental regions of interest placed (A) on T2* maps were converted into liver iron concentration (average 13.6 μmol/g in this example) and (B) on T1 maps (average 848 ms in this example).
Figure 4. Parametric mapping of (A) liver T2* (axial) and (B) liver T1 (coronal). Segmental regions of interest placed (A) on T2* maps were converted into liver iron concentration (average 13.6 μmol/g in this example) and (B) on T1 maps (average 848 ms in this example).
Nutrients 12 02151 g004
Figure 5. Two-dimensional phase-contrast measurements of bulk vessel flow in the portal vein (AC), infrahepatic inferior vena cava (DF) and suprahepatic inferior vena cava (GI). Magnitude anatomical images (A,D,G) were used for vessel segmentation (dashed regions of interest), with segmentation of the portal vein (A), infrahepatic inferior vena cava (D) and suprahepatic inferior vena cava (G). These were transcribed onto matched velocity maps (B,E,H) and manually adjusted for seven-phases through the cardiac cycle. Measurements were performed in triplicate and corresponding bulk vessel flow across the cardiac cycle was averaged to estimate bulk flow in ml/min for the (C) portal vein (612 mL/min in this example), (F) infrahepatic inferior vena cava (858 mL/min in this example) and (I) suprahepatic inferior vena cava (1638 mL/min in this example). Total liver blood flow was estimated by subtracting infrahepatic from suprahepatic inferior vena cava flow (780 mL/min in this example). Bulk flow measurements were normalised to liver volume estimated from segmentation of the liver on anatomical imaging.
Figure 5. Two-dimensional phase-contrast measurements of bulk vessel flow in the portal vein (AC), infrahepatic inferior vena cava (DF) and suprahepatic inferior vena cava (GI). Magnitude anatomical images (A,D,G) were used for vessel segmentation (dashed regions of interest), with segmentation of the portal vein (A), infrahepatic inferior vena cava (D) and suprahepatic inferior vena cava (G). These were transcribed onto matched velocity maps (B,E,H) and manually adjusted for seven-phases through the cardiac cycle. Measurements were performed in triplicate and corresponding bulk vessel flow across the cardiac cycle was averaged to estimate bulk flow in ml/min for the (C) portal vein (612 mL/min in this example), (F) infrahepatic inferior vena cava (858 mL/min in this example) and (I) suprahepatic inferior vena cava (1638 mL/min in this example). Total liver blood flow was estimated by subtracting infrahepatic from suprahepatic inferior vena cava flow (780 mL/min in this example). Bulk flow measurements were normalised to liver volume estimated from segmentation of the liver on anatomical imaging.
Nutrients 12 02151 g005
Figure 6. Dynamic cine MRI small bowel imaging was used to quantify small bowel motility. Regions of interest drawn on anatomical imaging (A) were colocalised to motility maps (the standard deviation of the determinant of pixel’s Jacobian) value (B). Averages were drawn across multiple slices for entire small bowel coverage. Small bowel motility in this example was 0.21 arbitrary units.
Figure 6. Dynamic cine MRI small bowel imaging was used to quantify small bowel motility. Regions of interest drawn on anatomical imaging (A) were colocalised to motility maps (the standard deviation of the determinant of pixel’s Jacobian) value (B). Averages were drawn across multiple slices for entire small bowel coverage. Small bowel motility in this example was 0.21 arbitrary units.
Nutrients 12 02151 g006
Table 1. Selected combinations of biomarkers for the assessment of liver disease.
Table 1. Selected combinations of biomarkers for the assessment of liver disease.
NameComponentsLiver Diseases in Which the Biomarkers Have Been StudiedScore Calculation
APRIAST and Platelet CountChronic Hepatitis C, Chronic Hepatitis B, Non-alcoholic steatohepatitis (NASH), NAFLD, biliary atresia and IFALD((AST level/AST upper level of normal)/platelet count)) × 100 − [AST upper level of normal = 40] [34]
AST/ALT RatioAST and ALTAlcoholic liver disease, primary biliary cirrhosis, NAFLD and IFALDAST/ALT
ELFHyaluronic Acid (HA), PIIINP and Tissue inhibitor of metalloproteinase 1 (TIMP-1)Mixed chronic liver diseases, Chronic Hepatitis C, and primary biliary cirrhosis(2.494 + 0.84 ln (CHA) + 0.735 ln(CPIIINP) + 0.391 ln(CTIMP-1) [81]
FIB-4ALT, AST and Platelet CountHIV/HCV coinfection, Chronic Hepatitis B, NAFLD and IFALD (age × AST level/platelet count × √ALT) [48]
Forns Index Age, GGT, Cholesterol and Platelet CountChronic Hepatitis C, Chronic Hepatitis B, and alcoholic liver disease. (7.811 − 3.131 × ln(platelet count) + 0.781 × ln(GGT) + 3.467 × ln(age) − 0.014 × cholesterol) [51]
Fibrosis IndexAge, GGT, Cholesterol and Platelet CountNAFLD(−2.948 + 0.562 × Forns index + 0.288 × APRI + 0.006 × Platelet count (109/L)) [49]
GPRGGT and Platelet countHIV/Chronic Hepatitis B, coinfection((GGT level/GGT upper level of normal)/platelet count) × 100 GGT upper limit of normal: 40 (women) and 60 (men) [57]
NAFLD Fibrosis ScoreAge, Hyperglycaemia, BMI, Platelet Count, Albumin, AST and ALTNAFLD(−1.675 + 0.037 × age (years) + 0.094 × BMI (kg/m2) + 1.13 × impaired fasting glucose/diabetes (yes = 1, no = 0) + 0.99 × AST/ALT ratio − 0.013 × platelet count − 0.66 × albumin) [58]
ALT = Alanine Transaminase; APRI = Aspartate transaminase-to-Platelet Ratio Index; AST = Aspartate Transaminase; BMI = Body Mass Index; ELF = Enhanced Liver Fibrosis; FIB-4 = Fibrosis 4; GGT = Gamma-Glutamyl Transferase; GPR = Gamma-glutamyl transferase-to-Platelet Ratio; HA = Hyaluronic Acid; HCV = Hepatitis C Virus; HIV = Human Immunodeficiency Virus; IFALD = Intestinal Failure-Associated Liver Disease; NAFLD = Non-alcoholic Fatty Liver Disease; NASH = Non-alcoholic Steatohepatitis; PIIINP = Procollagen III N-terminal Peptide; TIMP-1 = Tissue inhibitor of metalloproteinase 1.
Table 2. Comparisons of clinical and nutritional characteristics between adult participants with IF diagnosed with IFALD or no IFALD by radiological examinations (mean ± SD and median (range)).
Table 2. Comparisons of clinical and nutritional characteristics between adult participants with IF diagnosed with IFALD or no IFALD by radiological examinations (mean ± SD and median (range)).
ParametersTotal (n = 20)IFALD (n = 8)Non-IFALD (n = 12)p-Value
Clinical characteristics
  Age (years)51.15 ± 17.3058.13 ± 15.9046.50 ± 17.230.145
  Gender (Males:Females)8:124:44:80.648
  BMI (kg/m2)21.27 ± 3.6323.73 ± 3.3619.91 ± 2.950.036
  Oral Diet (Yes:No)15:57:18:40.292
Pathophysiological
classification of IF
  SBS-I—n (%)2 (10%)1 (8.3%)1 (8.3%)0.833
  SBS-JC—n (%)1 (5%)1 (8.3%)0
  SBS-JIC—n (%)1 (5%)01 (8.3%)
  Dysmotility—n (%)8 (40%)3 (37.5%)5 (41.7%)
  Mechanical obstruction—n (%)2 (10%)02 (16.7%)
  Mucosal disease—n (%)6 (30%)3 (37.5%)3 (50%)
  Small bowel length (cm)100.56 ± 52.0575.00 ± 49.12132.50 ± 39.480.100
Nutritional characteristics
  PN duration (months)88.90 (77.33)85.50 (78.75)57.50 (64.75)0.980
  Age PN started (years)43.55 ± 17.6147.50 ± 17.8040.92 ± 17.760.428
  PN mean energy (kcal/day)1730.91 ± 372.021687.90 ± 419.001759.58 ± 353.670.685
  PN mean lipids (g/kg/day)0.41 ± 0.280.39 ± 0.300.41 ± 0.280.887
  Days of PN/week7 (2.50)7 (0.25)6.5 (3)0.257
  Days of PN lipids/week 2.80 ± 1.582.25 ± 1.163.17 ± 1.750.211
BMI = Body Mass Index; IF = Intestinal Failure; IFALD = Intestinal Failure-Associated Liver Disease; PN = Parenteral Nutrition; SBS-I = Short Bowel Syndrome with Ileostomy or Ileo-rectal anastomosis; SBS-JC = Short Bowel Syndrome with Jejunocolonic anastomosis; SBS-JIC = Short Bowel Syndrome with Jejunoileal anastomosis with an Intact Colon.
Table 3. Comparisons of non-invasive biochemical parameters between adult participants with IF diagnosed with IFALD or no IFALD by radiological examinations (mean ± SD and median (range)).
Table 3. Comparisons of non-invasive biochemical parameters between adult participants with IF diagnosed with IFALD or no IFALD by radiological examinations (mean ± SD and median (range)).
Biochemical ParametersNormal RangeTotal (n = 20)IFALD (n = 8)Non-IFALD (n = 12)p-Value
Platelet Count (× 109/L)150–400219.80 ± 65.53172.00 ± 42.04251.67 ± 59.350.040
C-Reactive Protein (mg/L)0–5.04.30 (8.00)0.90 (1.23)8.20 (9.70)0.005
PIIINP (μg/L)1.7–4.24.72 ± 2.266.20 ± 1.933.68 ± 1.920.018
Haptoglobin (g/L)0.3–2.01.59 ± 0.960.88 ± 0.702.07 ± 0.810.003
Bilirubin(μmol/L)0–207.35 (5.83)11.84 (6.54)6.07 (3.34)0.005
AST (IU/L)0–3128.30 ± 11.4138.88 ± 9.0821.25 ± 6.06<0.001
ALT (IU/L)10–3524.20 (19.48)36.67 (18.72)18.94 (10.82)0.040
GGT (IU/L)6–4235.00 (84.46)130.00 (93.25)23.25 (25.75)0.040
ALT = Alanine Transaminase; AST = Aspartate Transaminase; GGT = Gamma-Glutamyl Transferase; IFALD = Intestinal Failure-Associated Liver Disease; PIIINP = Procollagen III N-terminal Peptide.
Table 4. Comparisons of non-invasive hepatic fibrosis scores between adult participants with IF diagnosed with IFALD or no IFALD by radiological examinations (mean ± SD and median (range)).
Table 4. Comparisons of non-invasive hepatic fibrosis scores between adult participants with IF diagnosed with IFALD or no IFALD by radiological examinations (mean ± SD and median (range)).
Hepatic Fibrosis ScoresTotal (n = 20)IFALD (n = 8)Non-IFALD (n = 12)p-Value
ELF8.91 ± 1.349.71 ± 1.248.34 ± 1.140.032
APRI0.30 (0.40)0.63 (0.32)0.19 (0.13)<0.001
FIB-41.23 (0.60)2.21 (1.63)0.96 (0.71)0.010
Forns Index5.36 ± 2.557.48 ± 1.943.94 ± 1.830.001
GPR0.35 (0.82)1.20 (1.37)0.20 (0.22)0.002
Fibrosis Index1.49 ± 1.212.46 ± 0.980.84 ± 0.870.001
APRI = Aspartate transaminase-to-Platelet Ratio Index; ELF = Enhanced Liver Fibrosis; FIB-4 = Fibrosis 4; GPR = Gamma-glutamyl transferase-to-Platelet Ratio; IFALD = Intestinal Failure-Associated Liver Disease.
Table 5. Demographic characteristics of patients in the MRI Cohort.
Table 5. Demographic characteristics of patients in the MRI Cohort.
Parameters
Clinical characteristics
  Age (years)52.3 ± 18.0
  Gender (Males:Females)2:8
  BMI (kg/m2)20.95 ± 4.38
Pathophysiological classification of IF
  SBS—n (%) 8 (80.0%)
  Dysmotility—n (%)2 (20.0%)
Nutritional characteristics
  PN duration (months)120 ± 87
  PN mean energy (kcal/day)1151 ± 398
  PN mean lipids (g/kg/day)3.85 ±3.54
BMI = Body Mass Index; IF = Intestinal Failure; MRI = Magnetic Resonance Imaging; PN = Parenteral Nutrition; SBS = Short Bowel Syndrome.
Table 6. Comparison of MRI imaging Scores against described normal values.
Table 6. Comparison of MRI imaging Scores against described normal values.
Non-IFALD (n = 5)IFALD Steatosis (n = 5)p-Value
Median (range)Median (range)
Liver Fat Fraction (%)2.14 (1.4–4.2)10.90 (2.2–27.4)0.032
Liver Iron Concentration (μmol/g)11.3 (10.4–38.9)16.0 (11.3–46.7)0.222
Liver T1 (ms)715 (544–848)740 (594–919)0.873
Portal venous flow (qPV) (mL/min/100 g)64.2 (45.6–137.6)56.2 (37.5–93.0)0.667
Estimated Total Liver Blood Flow (eTLBF) (mL/min/100 g)91.8 (63.5–145.7)62.1 (27.9–119.3)0.151
Small Bowel Mean motility (a.u.)0.19 (0.07–0.21)0.16 (0.11–0.21)0.999

Share and Cite

MDPI and ACS Style

Fragkos, K.C.; Picasso Bouroncle, M.C.; Kumar, S.; Caselton, L.; Menys, A.; Bainbridge, A.; Taylor, S.A.; Torrealdea, F.; Kumagai, T.; Di Caro, S.; et al. Serum Scoring and Quantitative Magnetic Resonance Imaging in Intestinal Failure-Associated Liver Disease: A Feasibility Study. Nutrients 2020, 12, 2151. https://0-doi-org.brum.beds.ac.uk/10.3390/nu12072151

AMA Style

Fragkos KC, Picasso Bouroncle MC, Kumar S, Caselton L, Menys A, Bainbridge A, Taylor SA, Torrealdea F, Kumagai T, Di Caro S, et al. Serum Scoring and Quantitative Magnetic Resonance Imaging in Intestinal Failure-Associated Liver Disease: A Feasibility Study. Nutrients. 2020; 12(7):2151. https://0-doi-org.brum.beds.ac.uk/10.3390/nu12072151

Chicago/Turabian Style

Fragkos, Konstantinos C., María Claudia Picasso Bouroncle, Shankar Kumar, Lucy Caselton, Alex Menys, Alan Bainbridge, Stuart A. Taylor, Francisco Torrealdea, Tomoko Kumagai, Simona Di Caro, and et al. 2020. "Serum Scoring and Quantitative Magnetic Resonance Imaging in Intestinal Failure-Associated Liver Disease: A Feasibility Study" Nutrients 12, no. 7: 2151. https://0-doi-org.brum.beds.ac.uk/10.3390/nu12072151

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop