Excess alcohol greatly increases the prevalence of cirrhosis in hereditary hemochromatosis

BACKGROUND & AIMS: The progression of fibrosis to cirrhosis is the most significant prognostic factor in hereditary hemochromatosis. We aimed to determine the range of hepatic iron concentration associated with cirrhosis in the absence of alcohol and other pro-fibrogenic cofactors and to quantify the contribution of excess alcohol consumption to the development of cirrhosis. METHODS: Liver biopsy data were evaluated on 224 C282Y homozygous hemochromatosis subjects. To determine the effect of alcohol alone on the development of fibrosis, subjects with viral hepatitis or nonalcoholic steatohepatitis were excluded. Subjects were divided into those who consumed less than 60 g alcohol per day and those who consumed 60 g per day or more. RESULTS: Seven percent of subjects who consumed less than 60 g per day had severe fibrosis/cirrhosis compared with 61% of excess alcohol consumers. CONCLUSIONS: Hemochromatosis subjects who drink more than 60 g alcohol per day are approximately 9 times more likely to develop cirrhosis than those who drink less than this amount, and the range of hepatic iron concentration associated with cirrhosis in the absence of cofactors was 233-675 micromol/g dry weight.     

Steatosis is a cofactor in liver injury in hemochromatosis

BACKGROUND & AIMS: Obesity-related steatosis is an increasingly common histologic finding and often coexists with other chronic liver diseases. Although obesity and steatosis are recognized risk factors for more advanced fibrosis in chronic hepatitis C and alcoholic liver disease, it has not been determined whether these factors influence the progression of other diseases in which steatosis is not a feature of the primary liver insult. METHODS: We studied 214 patients with hemochromatosis who were homozygous for the C282Y substitution in HFE and had undergone liver biopsy prior to phlebotomy. RESULTS: Steatosis was present in 41.1% of these patients, and 14.5% had moderate or severe steatosis. Median serum alanine aminotransferase (ALT) and ferritin levels were higher (P < .001), and median transferrin saturation (P = .01) and hepatic iron concentration (HIC) were lower (P = .003) in subjects with steatosis compared with subjects without steatosis. Bivariate analysis revealed a significant association between steatosis and fibrosis (P = .001). Following multiple logistic regression, steatosis was independently associated with fibrosis (odds ratio [OR] 4.3, 95% confidence interval [CI]: 2.1-8.8; P < .001) along with male sex (OR, 5.1; 95% CI: 2.0-12.5; P < .001), excess alcohol consumption (males > or = 50 g/day, females > or = 40 g/day) (OR, 3.9; 95% CI: 1.8-8.5; P = .001), and hepatic iron content (OR, 1.4; 95% CI: 1.2-1.6; P < .001). Both higher BMI (OR, 3.3; 95% CI: 1.8-6.3; P < .001) and alcohol consumption (males > or = 30 g/day, females > or = 10 g/day) (OR, 3.4; 95% CI: 1.2-10.0; P = .023) were independently associated with the presence of steatosis. CONCLUSIONS: These findings indicate that obesity-related steatosis may have a role as a cofactor in liver injury in hemochromatosis. This has important clinical implications and suggests that obesity should be actively addressed in the management of patients with hemochromatosis, as well as other liver diseases.     

Iron overload in hereditary spherocytosis: Association with hla-linked hemochromatosis

Heavy iron loading is a rare clinical finding in patients with hereditary spherocytosis. A pedigree was studied in which the proband, a 38-year-old man, had both hereditary spherocytosis and overt hemochromatosis. He had never received blood transfusions. The 8-year-old son of the proband also had hereditary spherocytosis and mildly increased iron stores. The 39-year-old brother of the proband did not have spherocytosis but did have overt hemochromatosis. Since hemochromatosis is transmitted as an HLA-linked autosomal recessive disorder, HLA haplotypes serve as markers of hemochromatosis alleles. In this pedigree only individuals with two hemochromatosis alleles (homozygosity) had heavy iron loads, whether hereditary spherocytosis was present or not. The presence of hereditary spherocytosis may have contributed to the magnitude of the iron loading but was not a major factor. Our findings suggest that nontransfusional hemochromatosis found in association with hereditary spherocytosis is due primarily to homozygosity for hemochromatosis.     

Non-invasive liver iron quantification by SQUID-biosusceptometry and serum ferritin iron as new diagnostic parameters in hereditary hemochromatosis

In the HFE-gene era, precise diagnostic parameters remain important to characterize individual iron stores, because the indication for therapy and prognosis are mainly related to the extent of iron loading. The frequently used serum ferritin interferes with non-iron related factors such as inflammation and may produce falsely positive values. We used a SQUID-biosusceptometer in a large series of patients (n = 679) to measure liver iron concentration in the differential diagnosis and therapy control of hereditary hemochromatosis (SQUID = superconducting quantum interference device). This truly non-invasive technique is sensitive, reliable, fast (online results), and also cost-effective when compared to invasive liver biopsy. Recently, ferritin iron content was propagated as a better parameter than ferritin protein. However, we found a poor correlation between ferritin iron and individual liver iron concentrations in patients with iron overload. Ferritin iron saturation varied in a range between 3 and 10%, independent from liver iron concentration. No differences were found between patients with hemochromatosis and secondary iron overload disease. Only patients with liver cell damage had increased ferritin iron saturations. In conclusion the diagnostic values of serum ferritin protein and iron to assess iron overload are limited.     

Deferasirox in patients with iron overload secondary to hereditary hemochromatosis: results of a 1‐yr Phase 2 study

This open‐label, prospective, phase 2 study evaluated the safety and efficacy of deferasirox (10 ± 5 mg/kg/d) in patients with hereditary hemochromatosis (HH) and iron overload refractory to or intolerant of phlebotomy. Ten patients were enrolled and all completed the 12‐month treatment period. There were significant decreases from baseline to end of study (i.e., 12 months) in median serum ferritin (P < 0.001), mean transferrin saturation (P < 0.05), median liver iron concentration (P < 0.001), and mean alanine aminotransferase (P < 0.05). The median time to achieve serum ferritin reduction ≥50% compared to baseline was 7.53 months. The most common adverse events were mild, transient diarrhea (n = 5) and nausea (n = 2). No patient experienced an increase in serum creatinine that exceeded the upper limit of normal. These data confirm that deferasirox was well tolerated and effective in reducing iron burden in patients with hereditary hemochromatosis and could be a safe alternative to phlebotomy in selected patients.     

Molecular pathogenesis and clinical conse-quences of iron overload in liver cirrhosis

BACKGROUND: The liver, as the main iron storage compart-ment and the place of hepcidin synthesis, is the central organ involved in maintaining iron homeostasis in the body. Exces-sive accumulation of iron is an important risk factor in liver disease progression to cirrhosis and hepatocellular carcinoma. Here, we review the literature on the molecular pathogenesis of iron overload and its clinical consequences in chronic liver diseases.
DATA SOURCES: PubMed was searched for English-language articles on molecular genesis of primary and secondary iron overload, as well as on their association with liver disease pro-gression. We have also included literature on adjuvant thera-peutic interventions aiming to alleviate detrimental effects of excessive body iron load in liver cirrhosis.
RESULTS: Excess of free, unbound iron induces oxidative stress, increases cell sensitivity to other detrimental factors, and can directly affect cellular signaling pathways, resulting in accelerated liver disease progression. Diagnosis of liver cirrhosis is, in turn, often associated with the identiifcation of a pathological accumulation of iron, even in the absence of genetic background of hereditary hemochromatosis. Iron depletion and adjuvant therapy with antioxidants are shown to cause signiifcant improvement of liver functions in patients with iron overload. Phlebotomy can have beneifcial effects on liver histology in patients with excessive iron accumulation combined with compensated liver cirrhosis of different etiology.
CONCLUSION: Excessive accumulation of body iron in liver cirrhosis is an important predictor of liver failure and avail-able data suggest that it can be considered as target for adju-vant therapy in this condition.     

Dose-related effects of dietary iron supplementation in producing hepatic iron overload in rats

The influence of varying the level of supplemental dietary iron on the development of hepatic iron overload was examined in rats. Two days after giving birth, Porton rats were fed a diet supplemented with 0, 0.5, 1 or 2% carbonyl iron, to institute dietary iron supplementation to the young via breast milk. After weaning, the offspring continued to receive the assigned diet until 32 weeks of age. Liver biopsies were taken from some rats at 8, 16 and 24 weeks of age and from all rats at 32 weeks of age, for assessment of iron overload. For both male and female rats, hepatic iron content was increased in a dose-related manner by feeding supplemented diet. Hepatic iron content of male rats tended to reach a plateau after 8–16 weeks of supplementation, while that of female rats continued to rise throughout the experimental period, such that the hepatic iron content of female rats was 2.8-fold that of similarly treated males at 32 weeks of age. Iron supplementation was associated with only moderate retardation of growth. By choosing an appropriate level of iron supplementation, good (grade III-IV) hepatic iron loading can be achieved with minimal adverse effects on the animals’ overall health.     

Hepatic iron overload in alcoholic end-stage liver disease is associated with iron deposition in other organs in the absence of HFE-1 hemochromatosis.

BACKGROUND: End-stage cirrhosis in the absence of hereditary hemochromatosis (HHC) can be associated with moderate to marked hepatic iron overload, especially in liver disease as a result of alcohol and/or hepatitis C. However, no published studies have addressed extrahepatic iron deposition in this setting. METHOD: A retrospective case series from three autopsied patients who died from end-stage cirrhosis associated with significant hepatic iron overload. Histology of vital organs was performed to detect extrahepatic iron deposition. HFE genotyping for the C282Y and H63D mutations was determined from archival tissue. Hepatic iron index and hepatic iron concentration (HIC) were quantified from formalin-fixed, paraffin-embedded tissue. Medical records were reviewed for possible causes of iron overload. RESULTS: Two patients were H63D heterozygous (H63D +/-) and one was wild type (C282Y -/-, H63D -/-). Histology revealed evidence of stainable iron in the heart and pancreas of all three subjects. Additionally, stainable iron was seen in the stomach in one subject and in the thyroid, pituitary, choroid plexus and testes in another subject. HIC ranged from 4354 to 6834 microg/g dry weight and HII from 1.8 to 2.2 (micromol/g/years). CONCLUSION: Iron overload secondary to end-stage liver disease can be associated with iron deposition in other organs in the absence of HFE-1 HHC.     

经肝铁浓度测定证实的血色病2例

2007年,中南大学湘雅二医院建立肝铁浓度测定方法,至今已测定370例患者,发现6例肝铁浓度＞5000μg/g(肝组织干重),其中2例＞15 000 μg/g,对此2例进行了系统的检查,确诊为血色病,报道如下.``病例1:患者男性,34岁,江西人,1994年发现HBsAg阳性,1999年出现肝功能异常,常服用护肝药物,住院5次,干扰素治疗半年.2005年3月开始拉米夫定治疗,9月换为阿德福韦酯,HBV DNA虽转阴,但转氨酶持续异常.伴乏力、性欲减退,但坚持上班.家属史无特殊.2007年7月首次到中南大学湘雅二医院就医.     

Survival of liver transplant recipients with hemochromatosis in the United States

BACKGROUND AND AIMS: Earlier studies have suggested that patients with hemochromatosis have poor post-transplantation survival. We aimed to compare patients with hemochromatosis to those with other causes of liver disease with regard to post-transplantation survival. METHODS: We compared the post-transplant survival of patients with and without hemochromatosis using data provided by the United Network for Organ Sharing on 50,306 adult, cadaveric liver transplantations performed in the United States between January 1, 1990, and July 18, 2006. RESULTS: During 1990-1996, the post-transplantation survival of patients with hemochromatosis (n = 177) at 1 year (79.1%), 3 years (71.8%), and 5 years (64.6%) was lower than the average 1-year (86.4%), 3-year (79.5%), and 5-year (73.8%) survival of all other transplant recipients (hazard ratio for death, 1.38; 95% confidence interval [CI], 1.12-1.71). In contrast, during 1997-2006, patients with hemochromatosis (n = 217) had excellent 1-year (86.1%), 3-year (80.8%), and 5-year (77.3%) post-transplantation survival, which was not different from the 1-year (88.4%), 3-year (80.3%), and 5-year (74.0%) post-transplantation survival of all other transplant recipients (hazard ratio for death, 0.89; 95% CI, 0.65-1.22). Adjustment for donor and recipient characteristics did not substantially change these results. Compared with recipients without hemochromatosis, those with hemochromatosis were more likely to die of cardiovascular diseases and less likely to die as a result of graft failure. CONCLUSIONS: The post-transplantation survival of patients with hemochromatosis, which was previously reported to be poor, has been excellent in the United States during the past 10 years.     

Cancer risk in patients with hereditary hemochromatosis and in their first-degree relatives

: Iron overload may be carcinogenic. Patients with hereditary hemochromatosis (HH) are reportedly at a 20-200-fold risk of intrahepatic cancer, but the reported risks for nonhepatobiliary cancers are conflicting. The risk of cancer in heterozygous individuals (estimated allele frequency, 1/10 to 1/20) is unknown. This study aimed to better assess these risks. : We performed a population-based cohort study of 1847 Swedish patients with HH and 5973 of their first-degree relatives using nationwide, population-based health and census registers. We used standardized incidence ratios (SIRs) as relative risk. : With 62 liver cancers and 128 nonhepatobiliary cancers, patients with HH were at a 20-fold risk of liver cancer (SIR, 21; 95% confidence interval [CI], 16-22) but an almost unaltered risk of all other cancers (SIR, 1.2; 95% CI, 1.0-1.4), including nonelevated risks for several gastrointestinal tract cancers. At 10 years of follow-up, the absolute risk of liver cancer was 6% among men and 1.5% among women. With 21 liver cancers and 508 nonhepatobiliary cancers, first-degree relatives were at an unaltered risk of extrahepatic cancer (SIR, 1.0; 95% CI, 0.9-1.1, including unelevated risks for gastrointestinal cancers) but at a modest and historic increased risk of hepatobiliary cancer (SIR, 1.5; 95% CI, 1.0-2.4), the histopathologic spectrum of which differed from the patients. : Patients (particularly men) with HH are at increased risk for hepatocellular cancer, although the magnitude of the risk is lower than previous estimates. Overall cancer risk in first-degree relatives does not seem to be increased.     

Duodenal cytochrome b and hephaestin expression in patients with iron deficiency and hemochromatosis

BACKGROUND & AIMS: An increased duodenal expression of the iron transporters, divalent-metal-transporter-1, and ferroportin is observed in patients with iron deficiency or hereditary hemochromatosis. Two oxidoreductases, termed duodenal cytochrome b and hephaestin, are proposed to co-operate with divalent-metal-transporter-1 and FPN1, respectively, to transfer iron from the duodenal lumen to the circulation. METHODS: In the present study, we investigated the mRNA and protein expression of Dcytb and hephaestin in duodenal biopsies from patients with iron deficiency, HFE, and non-HFE-associated hemochromatosis and in control subjects by means of real-time polymerase chain reaction, Western blot, and immunofluorescence. RESULTS: In iron deficiency a coordinated upregulation of the iron transporters divalent-metal-transporter-1 and ferroportin and of duodenal-cytochrome b and hephaestin was found, whereas in patients with HFE and non-HFE-associated hemochromatosis duodenal-cytochrome b and hephaestin protein and mRNA expression were not significantly different from control subjects. However, HFE but not non-HFE hemochromatosis patients presented with an increased duodenal ferric reductase activity. Spearman rank correlations showed that Dcytb, hephaestin, FPN1, and DMT1 mRNA expression are positively related to each other independently of the underlying disease, which ensures an efficient transepithelial transport of absorbed iron. CONCLUSIONS: Our data show that duodenal-cytochrome b activity in iron deficiency is stimulated via enhanced protein expression, whereas in HFE hemochromatosis it is up-regulated post-translationally. This points to different kinetics of intestinal iron uptake between iron deficiency and HFE hemochromatosis and also indicates that duodenal iron accumulation in HFE and non-HFE hemochromatosis is pathophysiologically different.     

Activated hepatic stellate cells participate in liver fibrosis in a patient with transfusional iron overload

We describe liver fibrosis caused by iron overload after a long history of blood transfusion in a patient with chronic renal failure. Pertinent laboratory data were: serum (s)-Fe 148 μg/dl; unsaturated iron binding capacity (UIBC) 14 μg/dl; s-ferritin 9350 ng/ml; human leukocyte antigen (HLA) A2, A24, B39, B55, Cw1, Cw7. Computed tomography revealed a high density in the liver, and laparoscopy revealed a brown liver. Liver histology showed bridging fibrosis from portal tracts. A heavy iron deposit was seen in Kupffer cells as well as in hepatocytes surrounded by fibrosis around the portal tracts. Immunocytochemistry revealed α-smooth muscle actin in many stellate cells distributed along the fibrotic area, and electron microscopy revealed infiltrating myofibroblastic stellate cells coexisting with collagen fibers around degenerated hepatocytes containing iron deposits. The findings are consistent with the notion that stellate cells play an important role in liver fibrogenesis in both genetic and transfusional iron overload hemochromatosis. Received Aug. 15, 1997; accepted Feb. 27, 1998     

Multigenic control of hepatic iron loading in a murine model of hemochromatosis

BACKGROUND & AIMS: Hereditary hemochromatosis is a common disorder of iron homeostasis characterized by increased dietary iron absorption and progressive iron accumulation, mainly in the liver. Most patients are homozygous for the C282Y mutation in the HFE gene. However, not all individuals carrying the hemochromatosis-predisposing genotype in the general population become iron loaded. Genetic modifiers have been shown to influence disease penetrance, but their number and chromosomal locations remain unknown, and their identification is hampered by complex interactions with environmental factors. To circumvent these difficulties, we used 2 strains of mice made deficient for the Hfe gene that strongly differ in their propensity to develop hepatic iron loading. METHODS: To localize the loci controlling hepatic iron loading in this murine model of hemochromatosis, we produced 1028 mice by an F2 intercross between the C57BL/6 and DBA/2 Hfe-deficient strains. We selected the 276 mice that contributed the most to the total linkage information for genotyping with 145 microsatellite markers. RESULTS: We mapped 4 modifier loci on chromosomes 7, 8, 11, and 12, with logarithm of odds scores of 14.47, 12.96, 6.04, and 6.72, respectively, in regions containing several genes recently shown to exert important roles in the regulation of iron metabolism. CONCLUSIONS: Our data provide a clear demonstration of the polygenic pattern of hepatic iron loading inheritance in Hfe-deficient mice. Examination of candidate genes residing at the loci identified in this study and genetic analysis of the syntenic chromosomal regions in humans may provide important insight into the heterogeneous disease presentation observed among HFE C282Y homozygotes.     

Two novel mutations in the SLC40A1 and HFE genes implicated in iron overload in a Spanish man

The most common form of hemochromatosis is caused by mutations in the HFE gene. Rare forms of the disease are caused by mutations in other genes. We present a patient with hyperferritinemia and iron overload, and facial flushing. Magnetic resonance imaging was performed to measure hepatic iron overload, and a molecular study of the genes involved in iron metabolism was undertaken. The iron overload was similar to that observed in HFE hemochromatosis, and the patient was double heterozygous for two novel mutations, c.-20G>A and c.718A>G (p.K240E), in the HFE and ferroportin (FPN1 or SLC40A1) genes, respectively. Hyperferritinemia and facial flushing improved after phlebotomy. Two of the patient's children were also studied, and the daughter was heterozygous for the mutation in the SLC40A1 gene, although she did not have hyperferritinemia. The patient presented a mild iron overload phenotype probably because of the two novel mutations in the HFE and SLC40A1 genes.     

Ferroportin-1 in the recurrence of hepatic iron overload after liver transplantation

Hepatic siderosis is frequent in patients with Hepatitis C virus (HCV) chronic hepatitis and considered secondary to advanced liver disease when detected in the explanted liver of cirrhotic patients submitted to transplantation. Here, we document the early recurrence of hepatic iron overload starting from host Kupffer cells and later involving hepatocytes in an Italian male submitted to liver transplantation for HCV-related cirrhosis, whose hemosiderosis was interpreted as related to a primary defect of iron handling by monocytic cells due to decreased Ferroportin-1 expression. He was negative for HFE mutations, had normal liver function, did not drink alcohol and had no erythropoietic defect. He was positive for the (CGG)_8/9 and the IVS1 –24 G > C Ferroportin-1 polymorphisms, associated with non-parenchymal iron overload, and had decreased Ferroportin-1 expression in monocytes. In conclusion, this case report documents the recurrence of progressive liver siderosis, which recalls Ferroportin disease, associated with decreased Ferroportin-1 expression in host monocytes repopulating the donor liver.     

Evaluation of cardiac and hepatic iron overload in thalassemia major patients with T2* magnetic resonance imaging

Objectives: Recent advancements have promoted the use of T2* magnetic resonance imaging (MRI) in the non-invasive detection of iron overload in various organs for thalassemia major patients. This study aims to determine the iron load in the heart and liver of patients with thalassemia major using T2* MRI and to evaluate its correlation with serum ferritin level and iron chelation therapy.

Methods: This cross-sectional study included 162 subjects diagnosed with thalassemia major, who were classified into acceptable, mild, moderate, or severe cardiac and hepatic iron overload following their T2* MRI results, respectively, and these were correlated to their serum ferritin levels and iron chelation therapy.

Results: The study found that 85.2% of the subjects had normal cardiac iron stores. In contrast, 70.4% of the subjects had severe liver iron overload. A significant but weak correlation (r?=??0.28) was found between cardiac T2* MRI and serum ferritin, and a slightly more significant correlation (r?=?0.37) was found between liver iron concentration (LIC) and serum ferritin.

Discussion: The findings of this study are consistent with several other studies, which show that patients generally manifest with liver iron overload prior to cardiac iron overload. Moreover, iron accumulation demonstrated by T2* MRI results also show a significant correlation to serum ferritin levels.

Conclusion: This is the first study of its kind conducted in Indonesia, which supports the fact that T2* MRI is undoubtedly valuable in the early detection of cardiac and hepatic iron overload in thalassemia major patients.     

Association of HFE mutations (C282Y and H63D) with iron overload in blood donors from Mexico City

Background and objective: Iron overload has been associated with HFE mutations (C282Y and H63D). We investigated the association between these mutations and high serum ferritin in a sample of healthy adult men.Design and methods: We enrolled unrelated blood donors from three hospitals in Mexico City in a cross-sectional study. Serum ferritin (SF) was determined to define iron overload, and HFE gene mutations were identified by PCR–RFLP.Results: We evaluated 2524 male blood donors and included 246 individuals for each group. We identified 108 individuals with HFE gene mutation, 20.5 % were heterozygote (wt/H63D or wt/C282Y) and the remaining homozygote (H63D/ H63D). The genotype wt/C282Y was observed in two cases, none cases with C282Y/C282Y. The allelic frequency of H63D and C282Y was 0.115 and 0.002, respectively. We observed different association for H63D allele with iron overload (OR 1.54, CI 95 %1.16-2.03) and none in allele C282Y. Although values averages were different, the extreme dispersion of serum ferritin not showed statistically significant differences between H63D and C282Y alleles and ferritin concentrations.Conclusions: The male unrelated blood donors from Mexico City with iron overload prevalence of 13.8% hold similarities with other populations from Europe o America continent, respecting the allele frequency H63D. Nevertheless, allele frequency C282Y is lower than that observed in descendents from northern Europe. We have not observed statistic difference of SF or iron overload frequency by effect of both alleles.