INTRODUCTION
Non-alcoholic fatty liver disease (NAFLD) represents a spectrum of liver diseases ranging from hepatocellular steatosis to irreversible liver cirrhosis and is closely related to obesity and metabolic syndrome [
1]. Metabolic syndrome is characterized by obesity, hyperlipidemia, diabetes mellitus (DM), and insulin resistance. In adults, as well as hypertension, obesity, and DM, the frequency of metabolic syndrome is increasing gradually. Metabolic syndrome can be manifested as NAFLD in the liver [
2,
3,
4]. The prevalence of NAFLD is also increasing due to the increase in the rate of metabolic syndrome. NAFLD is raising the morbidity and mortality rates associated with the liver [
5]. In western countries, the morbidity of NAFLD is 20-30% of total adults and 90% of obese adults. Moreover, non-alcoholic steatohepatitis (NASH) is affecting an estimated 2-3% of the general population and up to 37% of obese individuals [
1]. Approximately 10% of patients with NAFLD progress to NASH, and 8-26% of NASH patients progress to cirrhosis [
2].
The prevalence of NAFLD in children and young adults is also increasing rapidly. Studies have reported about 3% prevalence of NAFLD in the general pediatric population and 53% in obese children [
1]. Due to the Westernized lifestyle and diet, pediatric NAFLD is expected to increase significantly in the future globally. Furthermore, NAFLD can have more severe influence to children due to longer duration of the disease. Therefore, as with adults, the importance of the early diagnosis and proper treatment of NAFLD and NASH in children is increasing in order to prevent liver cirrhosis and hepatocellular carcinoma.
NAFLD can be diagnosed after the exclusion of other liver diseases and identifying image studies of the fatty liver [
6]. To diagnose NASH, various methods-including magnetic resonance imaging (MRI) proton density-fat fraction (PDFF), which has been actively studied recently-are being used. MRI PDFF is a non-invasive and quantitative means of quantifying hepatic steatosis in patients with NAFLD [
7]. However, the exact cut-off value has yet not been established, and the MRI equipment itself is not easily obtained due to its high price. Confirmation of the disease can be made only by pathology, which is characterized as steatosis, lobular inflammation, and hepatocellular ballooning [
2,
8]. However, liver biopsy is invasive in children. Furthermore, there is the possibility of sampling error of liver biopsy specimens [
9]. Therefore, to follow up on the progression of NAFLD, repeated liver biopsies are nearly impossible, especially for children. Thus, researchers are seeking non-invasive and cost-effective tools for the diagnosis of NAFLD and NASH. They are making efforts to develop biological markers to predict the progression from simple fatty liver to NASH, liver fibrosis, cirrhosis, and hepatocellular carcinoma [
10]. In recent adult studies, serum ferritin levels were reported to be an independent predictor of advanced hepatic fibrosis in patients with NAFLD based on its correlation with hepatic inflammation and hepatic iron storage [
10]. Serum ferritin levels are known to be elevated in patients with NAFLD and seem to be related to insulin resistance and hepatocyte damage [
11]. So researchers are interested in serum ferritin as a biomarker that can reflect the inflammatory change of the liver for children as well. In fact, pediatric gastroenterologists are more earnestly seeking simple and noninvasive biologic markers for NAFLD. If simple and non-invasive biologic markers for NAFLD are found, it will be very helpful in disease management due to improved compliance of follow-up. Also early detection or screening could be possible for the pediatric NAFLD patients who may progress to liver cirrhosis. Proper medical treatment to the patients could be provided at an appropriate time accordingly. We also can expect an additional effect that might reduce patient's medical expenses from other expensive and invasive diagnostic methods and its possible complications. For these reasons, we were to investigate the clinical significance of serum ferritin in pediatric NAFLD patients as a candidate of effective and less-invasive biological marker.
DISCUSSION
Recently, NAFLD has become a very important disease in the pediatric population. As liver biopsies are invasive, reliable and noninvasive biomarkers are essential for examining pediatric NAFLD. In this study, we examined whether serum ferritin could be an effective and less-invasive biological marker that could be applied to pediatric patients to predict their disease severity.
The three-hit hypothesis is the widely known NAFLD pathogenesis that a progression to NASH and fibrosis depends on additional factors such as free fatty acids, inflammatory cytokines and adipokines, oxidative stress, and mitochondrial dysfunction in the base of obesity and insulin resistance [
1]. Serum ferritin is the primary tissue for iron-storage protein in the liver, where most extra body iron is stored. Ferritin levels can be elevated secondary to obesity, chronic alcohol consumption, chronic inflammation including viral hepatitis, histiocytic neoplasm, and steatohepatitis [
10]. Hyperferritinemia has been previously observed in obesity-related chronic inflammatory conditions such as DM, metabolic syndrome, liver cirrhosis, and NAFLD [
10]. As the ferritin concentration increases, the risk of significant liver disease also increases. In NAFLD, increased ferritin levels are considered an expression of metabolic syndrome and of hepatic damage, because of inflammatory cytokine activation [
12]. In addition, considering the pathophysiology from a different standpoint, the histological evidence of hepatic iron accumulation has been reported to be strongly associated with a hepatic fibrosis in NAFLD patients in large multicenter studies [
14]. Hepatic iron accumulation produces inflammatory cytokines, and they induce hepatic fibrosis [
8]. According to another adult study by Kowdley et al. [
10], the histological features of NAFLD, which include steatosis, hepatocellular ballooning, and fibrosis, were more severe in patients with increased serum ferritin. They concluded that serum ferritin is associated with hepatic iron deposition and worsened histological activity in patients with NAFLD. However, they also said that hyperferritinemia was associated with the histologic findings of NAFLD patients whose histological findings did not include detectable iron deposition.
In this study, the MRI 2D PDFF values and liver-related laboratory marker values, including serum ferritin, were higher in the obese group than the overweight group, which is concordant with the previous results of adult studies that indicated that NAFLD and NASH are positively correlated with obesity [
2,
8,
15,
16]. NAFLD can be divided into five grades according to the results of liver biopsy, from grade-0 to grade-4. Grade-4 indicates liver cirrhosis. According to Permutt et al. [
7], the mean MRI 2D PDFF value increased significantly with histology-determined steatosis grade: <5.0% at grade-0, 5.0-8.9% at grade-1, 8.9-16.3% at grade-2, and 16.3-25.0% at grade-3; with
p≤0.0001. However, no significant correlation in the MRI 2D PDFF values at grade-4 was found. They thought that this is because the results of the MRI 2D PDFF were well correlated with low-grade hepatic steatosis, but steatosis was not linearly correlated with NAFLD progression. Hepatic steatosis may be replaced by collagen in severe NAFLD or cirrhosis. As a result, in severe NAFLD or cirrhosis, low hepatic steatosis could be found, and there might be no differences between MRI 2D PDFF in cirrhosis and MRI 2D PDFF in grade-1 steatosis. Therefore, in patients with NAFLD, a low amount of hepatic steatosis on imaging may not indicate mild NAFLD, so other parameters should be considered to distinguish low-grade steatosis from liver cirrhosis [
7]. In this study, we tried to separate the whole population into five grades (grade 0-4). However, our population was divided into two of grade-0, two of grade-1, 11 of grade-2, and 51 of grade-3, so there were some limitations to our ability to show the relationship between MRI 2D PDFF and serum ferritin, because of the largely deviated populations of the groups. The reason that the correlation between serum ferritin and MRI 2D PDFF was not good could be explained as the severity of our patients was higher (the median of the MRI 2D PDFF is 36, the average is 33.68).
Although liver biopsy remains the gold standard for the diagnosis and staging of NASH, we could not perform liver biopsies on all patients. Therefore, we applied NAFLD severity markers. Using APRI scores, McPherson et al. [
17] demonstrated an area under the receiver operating characteristic curve (AUROC) of 0.67 for advanced fibrosis in a study of 145 adult NAFLD subjects. The AUROC values for AAR and FIB-4 were found to be 0.742 and 0.802, respectively, for advanced fibrosis in another study of 541 NAFLD patients [
18]. In our study, the correlation coefficients of APRI and FIB-4 showed 0.6682 (0.5014-0.7830) and 0.5876 (0.3956-0.7261), respectively. They both showed good statistical correlation with serum ferritin (
p<0.0001). These facts suggest the clinical usefulness of serum ferritin in pediatric NAFLD patients. We think that these NAFLD markers can make up for some of the limitations of our study. By using BMI as a continuous value, we found a good correlation with serum ferritin. These results show that serum ferritin is correlated with obesity and hepatocyte inflammation.
The pathophysiology of NAFLD is closely correlated with metabolic syndrome. Obese patients with Type 2 DM and NAFLD have been reported to have an 80% morbidity rate [
19]. Ultrasound examinations are widely implemented as an initial non-invasive diagnostic imaging tool, and some reports indicate that ultrasonography results correlate with liver biopsy and liver-related blood test results [
20]. However, it is an inadequate screening tool, because of the large deviation of results according to examiners and the risk of failure in diagnosing early fatty liver [
11,
16,
19]. An MRI can provide a significantly higher sensitivity and specificity of diagnosis of NAFLD: 98% and 99%, respectively. However, patient compliance is low due to its high cost [
5]. This is why serum ferritin arouses interest in many adult studies as an independent predictor of liver fibrosis. According to a study by Manousou et al. [
12], serum ferritin has relatively high accuracy: 78-85% sensitivity and 60-67% specificity. Although serum ferritin alone is insufficient for diagnosing NAFLD, it could be used to rule out NAFLD in those with underlying obesity or DM and high serum AST and ALT levels. In addition, serum ferritin could be used as a marker for NAFLD patients to determine the appropriate time to undergo a liver biopsy for the screening of NASH or cirrhosis [
12,
21].
In recent studies, Plasma caspase-generated cytokeratin-18 fragments (CK-18) as a biological indicator other than serum ferritin were introduced, which is indicative of the index of the apoptosis of hepatocytes in NASH. It seems to show a high specificity for the diagnosis of NASH in several studies [
22]. CK-18 is a major intermediate filament protein in the liver. Because of obesity-related liver damage, injured hepatocytes precede to apoptosis. Then, CK-18 fragments are released from hepatocytes and can be detected in serum [
23,
24]. However, according to a recent study of the multicenter, Cusi et al. [
19], Plasma CK-18 was raised significantly with any increase in steatosis, inflammation, and fibrosis, but because of low sensitivity, there was significant vagueness in the prediction of disease severity. Therefore, more research is warranted for larger populations, to develop simple and non-invasive biological markers that can provide an alternative for the histologic results of liver biopsy.
In this study, we applied serum ferritin to pediatric NAFLD patients based on previous adult studies. The results of the comparison of various liver-related tests, MRI findings, and NAFLD severity markers showed that serum ferritin was related with the severity of NAFLD. However, due to the limitations of the pediatric population, we could not compare the liver biopsy tissue of each patient with their serum ferritin level. If we could obtain the liver biopsy results of the patients divide the patients into several grades according to their results, we could describe the diagnostic value of the serum ferritin in NAFLD patients more precisely; that is the limitation of this study. In summary, serum ferritin, as a biological indicator, could have a close correlation with the severity of NAFLD in children. However, when using serum ferritin as a noninvasive marker, other factors that can affect serum ferritin levels should be controlled.