Value of hepatic iron measurements in early hemochromatosis and determination of the critical iron level associated with fibrosis

The role of the measurement of hepatic iron in the diagnosis of genetic hemochromatosis was studied, with particular reference to the differentiation of early hemochromatosis from alcoholic siderosis and the critical hepatic iron concentration associated with fibrosis in hemochromatosis. Hepatic iron was measured in 30 homozygous relatives of 17 hemochromatosis probands, 8 heterozygous relatives, 51 patients with alcoholic liver disease and 40 control subjects. Hepatic iron concentrations were greatly increased in the majority of homozygous hemochromatosis subjects, and there was little overlapwith the other groups. In the absence of alcoholism, fibrosis or cirrhosis in hemochromatosis was present only with hepatic iron concentrations above a threshold of approximately 400 μmoles per gm (22.3 mg per gm) dry weight. In some heterozygous hemochromatosis subjects and in some alcoholic patients, hepatic iron concentrations were in the range seen in young homozygous subjects. However, an age‐related rise in hepatic iron was seen only in hemochromatosis homozygotes, and calculation of an hepatic iron index (hepatic iron/age) resulted in a clear distinction between homozygotes and the other three groups. It is concluded: (a) that chemical measurement of hepatic iron concentration, when corrected for the age of the subject, reliably distinguishes early hemochromatosis from alcoholic siderosis, and (b), that there appears to be a threshold level of hepatic iron above which there is a high risk of fibrosis

HLA typing in idiopathic hemochromatosis: Distinction between homozygotes and heterozygotes with biochemical expression

In a study of 20 families with idiopathic hemochromatosis, relatives of probands were classified as either homozygous, heterozygous, or normal according to their HLA phenotype. An abnormality in the serum iron concentration, total iron‐binding capacity, or serum ferritin concentration was present in all homozygotes and in 25% of heterozygotes. In heterozygotes, the mean total iron‐binding capacity was significantly decreased, and the mean hepatic iron concentration was significantly increased compared to normals. However, in contrast to homozygotes, clinical evidence of iron overload was not observed in heterozygotes, and there was no biochemical or histological evidence of liver disease resulting from excessive iron stores. Progressive iron overload did not develop in 44 heterozygotes who were studied for up to 16 yr

Diagnosis of hemochromatosis in young subjects: Predictive accuracy of biochemical screening tests

The reliability of serum iron, transferrin saturation, and serum ferritin in the detection of early iron overload in hemochromatosis was determined in 120 young (700 μg/L. We conclude that the combination of serum ferritin and transferrin saturation is a reliable screening regimen for the detection of hemochromatosis and for predicting the level of body iron stores in young hemochromatosis subjects

Idiopathic hemochromatosis: demonstration of homozygous-heterozygous mating by HLA typing of families

In five families with idiopathic (hereditary) hemochromatosis, clinical and biochemical expression of the disease occurred in offspring of probands, suggesting an autosomal dominant mode of inheritance. However, HLA typing of subjects indicated that a homozygous-heterozygous mating almost certainly had occurred in four of the five families, resulting in homozygous offspring. Thus, in these families inheritance of the hemochromatosis trait was best explained in terms of an autosomal recessive or intermediate mode of inheritance. This study demonstrates the value of HLA typing in identifying homozygous-heterozygous matings in hemochromatosis families

Is all genetic (hereditary) hemochromatosis HLA-associated

1. GH in Australia is significantly associated with the HLA-A3 antigen, which is the only independent marker for the disease (B7 in linkage disequilibrium with A3). 2. The haplotype A3, B7, DR2 is the only one with increased prevalence in this disease, presumably due to its being the predominant haplotype among early immigrants. 3. Exceptions to HLA association in GH are rare and can be explained by: (1) incorrect HLA serotyping, (2) chromosomal recombination, or (3) rare homozygous-homozygous mating. 4. These data are consistent with GH being due to a mutant gene or genes in close proximity to HLA-A. 5. Heavy alcohol ingestion does not lead to expression of hemochromatosis in heterozygous subjects