Identification of homozygous hemochromatosis subjects by measurement of hepatic iron index

The value of measurement of hepatic iron concentration and determination of the hepatic iron index in distinguishing homozygotes from heterozygotes for hemochromatosis was examined. The study group included 42 homozygotes with an unequivocal diagnosis of hemochromatosis and six individuals who had initial equivocal results but were established as homozygous after extensive follow-up. These were compared with 15 heterozygotes with no sign of increasing body iron stores who had undergone liver biopsy because of an initial suspicion of raised iron levels. In these subjects a hepatic iron concentration of greater than 75 mumol/gm dry weight was clearly indicative of homozygous hemochromatosis. Body iron accumulation was age-related both in homozygotes and in these heterozygotes with mild biochemical abnormalities (r = 0.476; p = 0.001 and r = 0.689; p = 0.01, respectively), with a rate of accretion of approximately 5 mumol/gm dry weight/year in homozygotes and 0.9 mumol/gm dry weight/year in heterozygotes. Thus, lower values in young subjects may be consistent with homozygosity, and higher values in older individuals are consistent with heterozygosity. To overcome this problem, the hepatic iron index (hepatic iron concentration divided by age in years) was analyzed and found to separate the two groups effectively, with no homozygote having an index of less than 1.9 and no heterozygote having an index of greater than 1.5. These results in a series of patients who have been followed for a median of 3 yr (range = 1 to 30 yr) validate the use of the hepatic iron index to discriminate hemochromatosis homozygotes from heterozygotes with raised levels of serum ferritin, transferrin saturation or both.     

Human leukocyte antigen typing of siblings in hereditary hemochromatosis: a cost approach.

To assess the clinical value of human leukocyte antigen typing in the diagnosis and management of hereditary hemochromatosis, 105 siblings of 35 proband cases of hemochromatosis were retrospectively analyzed to study whether the exclusion of human leukocyte antigen typing would have adversely affected management. All siblings and probands had already been tested for human leukocyte antigen-A and human leukocyte antigen-B typing, serum ferritin and transferrin saturation. The median age of siblings was 55 yr (range = 11 to 82). Siblings were categorized according to putative genotype (homozygote, heterozygote and normal) using human leukocyte antigen typing. Phenotypic expression of hemochromatosis was considered to be iron overload as indicated by an elevated ferritin (male = greater than 350 micrograms/L, female = greater than 200 micrograms/L) and/or transferrin saturation (greater than 55%). Six of 37 homozygotes had a normal ferritin and transferrin saturation, with five of these patients under 32 yr old. No putative heterozygotes with both an abnormal ferritin and transferrin saturation were seen, although 12 of 48 (25%) heterozygotes had either an elevated ferritin or transferrin saturation. Twenty of 20 normal siblings had a normal ferritin and transferrin saturation. To assess the cost of screening with and without human leukocyte antigen typing, a cost model simulation was used that compared the costs of both methods in a hypothetical family (proband, homozygote, heterozygote and normal sibling).(ABSTRACT TRUNCATED AT 250 WORDS)     

Relationship of body iron stores to levels of serum ferritin, serum iron, unsaturated iron binding capacity and transferrin saturation in patients with iron storage disease

None of the methods for assessing total body iron burden in patients with hemochromatosis is satisfactory. Although it is commonly believed that a relationship exists between serum ferritin levels and total iron burden, the extent of this relationship has not previously been documented. In the present investigation we measured the total body iron burden of 88 patients with putative hemochromatosis, 54 of whom were homozygotes for the 845G-->A (C282Y) mutation. The total body iron stores were estimated from the volume of red cells removed during therapeutic phlebotomy corrected for an estimated 2 mg/day dietary iron absorbed during the phlebotomy period; the amount of storage iron was compared to the serum ferritin, serum iron, unsaturated iron binding capacity, and transferrin saturation before the beginning of phlebotomy. The serum ferritin proved to be the best predictor of body iron stores. The correlation between all of the analytes and the body iron burden was greater in patients homozygous for the C282Y mutation than in those who were not, including the compound heterozygotes for C282Y and H63D. The body iron burden tended to be greater in patients homozygous for the C282Y mutation than the other patients at any other given ferritin level. We conclude that the serum ferritin level does provide some information regarding total iron burden but even in the case of C282Y homozygotes, the correlation is not very strong.     

A population-based study of the biochemical and clinical expression of the H63D hemochromatosis mutation

BACKGROUND & AIMS: Two major mutations are defined within the hemochromatosis gene, HFE. Although the effects of the C282Y mutation have been well characterized, the effects of the H63D mutation remain unclear. We accessed a well-defined population in Busselton, Australia, and determined the frequency of the H63D mutation and its influence on total body iron stores. METHODS: Serum transferrin saturation and ferritin levels were correlated with the H63D mutation in 2531 unrelated white subjects who did not possess the C282Y mutation. RESULTS: Sixty-two subjects (2.1%) were homozygous for the H63D mutation, 711 (23.6%) were heterozygous, and 1758 (58.4%) were wild-type for the H63D mutation. Serum transferrin saturation was significantly increased in male and female H63D homozygotes and heterozygotes compared with wild-types. Serum ferritin levels within each gender were not influenced by H63D genotypes. Elevated transferrin saturation > or = 45% was observed in a greater proportion of male H63D carriers than male wild-types. Male H63D homozygotes (9%) and heterozygotes (3%) were more likely to have both elevated transferrin saturation and elevated ferritin > or = 300 ng/mL than male wild-types (0.7%). Homozygosity for H63D was not associated with the development of clinically significant iron overload. CONCLUSIONS: Presence of the H63D mutation results in a significant increase in serum transferrin saturation but does not result in significant iron overload. In the absence of the C282Y mutation, the H63D mutation is not clinically significant.     

Evidence for heterogeneity in hereditary hemochromatosis: Evaluation of 174 persons in nine families

Hereditary hemochromatosis is an autosomal recessive disease in which the gene is linked to the HLA system. Investigation of nine unrelated probands and their family members has revealed distinct groups based on biochemical and clinical manifestations of the disease. Four different types of disease expression were identified: Group I—classic hereditary hemochromatosis with elevated transferrin saturation, serum ferritin levels, and liver iron content; Group II—severe iron overload, accelerated disease manifesting at an early age; Group III—elevated total body iron stores, normal transferrin saturation and serum ferritin levels; Group IV—markedly elevated findings on serum biochemical tests, e.g., transferrin saturation, serum ferritin levels, with minimal elevation in total body iron stores. This evidence for several clearly distinguishable modes of expression in different families suggests that more than one genetic lesion in iron metabolism may be responsible for iron overload in hereditary hemochromatosis. This genetic heterogeneity may be helpful in delineating the fundamental abnormalities in iron metabolism in this group of disorders.     

Serum ferritin concentrations and body iron stores in a multicenter, multiethnic primary-care population

How often elevated serum ferritin in primary-care patients reflects increased iron stores (normally 0.8 g in men, 0.4 g in women) is not known. The Hereditary Hemochromatosis and Iron Overload Screening (HEIRS) study screened 101,168 primary-care participants (44% Caucasians, 27% African-Americans, 14% Asians/Pacific Islanders, 13% Hispanics, 2% others). Follow-up clinical evaluation was performed in 302 of 333 HFE C282Y homozygotes regardless of iron measures and 1,375 of 1,920 nonhomozygotes with serum ferritin >300 microg/L (men), >200 microg/L (women) and transferrin saturation >50% (men), >45% (women). Quantitative phlebotomy was conducted in 122 of 175 C282Y homozygotes and 122 of 1,102 nonhomozygotes with non-transfusional serum ferritin elevation at evaluation. The estimated prevalence in the Caucasian population of C282Y homozygotes with serum ferritin >900 microg/L at evaluation was 20 per 10,000 men and 4 per 10,000 women; this constellation was predictive of iron stores >4 g in men and >2 g in women. The estimated prevalence per 10,000 of non-C282Y homozygotes with serum ferritin >900 microg/L at evaluation was 7 among Caucasians, 13 among Hispanics, 20 among African Americans, and 38 among Asians and Pacific Islanders, and this constellation was predictive of iron stores >2 g but <4 g. In conclusion, serum ferritin >900 microg/L after initial elevations of both serum ferritin and transferrin saturation is predictive of mildly increased iron stores in multiple ethnic populations regardless of HFE genotype. Serum ferritin >900 microg/L in male C282Y homozygotes is predictive of moderately increased iron stores.     

The diversity of liver diseases among outpatient referrals for an elevated serum ferritin.

BACKGROUND: The aim of the present study was to examine the diversity of liver diseases in outpatients referred because of elevated serum ferritin. METHODS: A retrospective review was performed of outpatient referrals for serum ferritin elevations made to a tertiary care centre liver clinic between 1999 and 2005. Information regarding serum ferritin, transferrin saturation, liver biopsy, liver iron concentration and final diagnosis was extracted. Patients were stratified into two groups based on ferritin concentration: ferritin concentration 300 microg/L to 1000 microg/L, and ferritin concentration greater than 1000 microg/L. RESULTS: A total of 482 charts were reviewed, of which 119 (25%) had ferritin concentrations greater than 1000 microg/L. HFE-linked hemochromatosis, nonalcoholic steatohepatitis and alcohol-related liver disease were the top three diagnoses. HFE-linked hemochromatosis accounted for 28% to 42% of the diagnoses in all subgroups. The percentage of patients diagnosed with HFE-linked hemochromatosis was similar in the ferritin 300 microg/L to 1000 microg/L and the ferritin greater than 1000 microg/L groups (P = 0.067). Among patients with ferritin greater than 1000 microg/L, 63% underwent a liver biopsy. Of those with an elevated liver iron concentration (greater than 35 micromol/g dry weight), 71% had a transferrin saturation greater than 50% (88% of C282Y homozygotes and 43% of non-C282Y homozygotes). In non-C282Y homozygotes with an elevated serum ferritin concentration greater than 1000 microg/L, 64% did not have iron overload on liver biopsy. CONCLUSION: HFE-linked hemochromatosis accounted for less than one-half of the diagnoses in an outpatient population referred for elevated ferritin, suggesting a need to search further for an alternate cause.     

Expression of the HFE hemochromatosis gene in a community-based population of elderly women

BACKGROUND AND AIM: Recent studies suggest that the clinical penetrance of associated hereditary hemochromatosis, defined as either the C282Y homozygote or compound heterozygote HFE genotype status, is much lower than previously thought. METHODS: We investigated the clinical penetrance and phenotypic expression of HFE-associated hereditary hemochromatosis in a community-based population of 1352 elderly female subjects with a mean age of 75 years. Serum transferrin saturation and ferritin levels were determined on all subjects bearing a C282Y mutation and a subset of wild-type C282Y subjects. RESULTS: The prevalences of the C282Y homozygous and compound heterozygous HFE genotypes were 0.15% (2/1352) and 2.0% (27/1352), respectively. The observed prevalence of 0.15% for C282Y homozygotes borders on significance (P = 0.054) for deviation from the Hardy-Weinberg population equilibrium calculations, which predict a prevalence of 0.49%, whereas the observed and predicted compound heterozygote prevalences were not significantly different. Clinical symptoms of hemochromatosis were absent in both the C282Y homozygote subjects. Of the compound heterozygous subjects, 2/27 (7%) had elevated serum transferrin saturation and ferritin values; however, clinical symptoms of hemochromatosis were absent in both. Considered as a whole, the compound heterozygous subjects had markedly elevated means for serum iron (19.4 vs 16.0 micromol/L, P = 0.0008), transferrin saturation (34.8% vs 25.2%, P < 0.0001) and ferritin (157 vs 92 microg/L, P = 0.002) compared with the wild-type subjects. CONCLUSION: The C282Y homozygous HFE hereditary hemochromatosis genotype was under-represented in this elderly cohort, whereas the compound heterozygous genotype was not. None of the homozygous or compound heterozygous subjects expressed the phenotype of iron overload disease.     

Unsaturated iron binding capacity and transferrin saturation are equally reliable in detection of HFE hemochromatosis

OBJECTIVE: Unsaturated iron binding capacity (UIBC) has been proposed as an inexpensive alternative to transferrin saturation for detection of hereditary hemochromatosis. The aim of this study was to compare, in a hospital referral clinic, the reliability of transferrin saturation and UIBC for detection of subjects who have inherited HFE (HLA-asociated iron overload) genotypes predisposing to iron overload. METHODS: Serum transferrin saturation, UIBC, and ferritin were tested in 110 consecutive subjects. Optimum thresholds were determined from receiver operating characteristic curves. RESULTS: Of 110 subjects, 44 carried significant HFE mutations (C282Y/C282Y or C282Y/H63D). In genetically predisposed subjects with biochemical expression, the optimum threshold for transferrin saturation was 43%, giving a sensitivity of 0.88 and specificity 0.95. For UIBC, the optimum threshold was 143 microg/dL (25.6 micromol/L), giving a sensitivity of 0.91 and specificity of 0.95. In patients referred with a family history or clinical suspicion of hemochromatosis, transferrin saturation and UIBC were highly reliable predictors of genotype. In patients referred for investigation of abnormal liver enzymes without a known family history of hemochromatosis, a normal transferrin saturation or normal UIBC was highly reliable in excluding hemochromatosis. CONCLUSIONS: Transferrin saturation and UIBC have equal reliability in ability to predict hemochromatosis. UIBC should be considered as an alternative to transferrin saturation in detection of hemochromatosis.     

Quantitation of ferritin iron in plasma, an explanation for non- transferrin iron

In 33 patients with thalassemia and idiopathic hemochromatosis, plasma ferritin protein levels ranged from 36 to 5,850 micrograms/L. The iron content of this ferritin as determined by immunoprecipitation ranged from undetectable amounts to 507 micrograms/L. The mean iron content of ferritin protein in those and other subjects with plasma ferritin concentrations of over 1,000 was 6.8% +/- 2.7%. Plasma transferrin was usually saturated with iron in patients with measurable ferritin iron, but exceptions occurred. In studies using electrophoretic separation, it was shown that some ferritin iron moved to transferrin during in vitro incubation, whereas exchange in the opposite direction was extremely limited. Because some plasma ferritin iron was measured by the standard colorimetric plasma iron determination, these observations (a) indicate that plasma ferritin contains a significant amount of iron (b) indicate that a significant proportion of nontransferrin iron in individuals with nontransferrin iron as detected by standard plasma iron and total iron-binding capacity measurements is due to the presence of ferritin, and (c) suggest that large amounts of ferritin iron may affect the saturation of plasma transferrin.     

Prevalence of abnormal iron studies in heterozygotes for hereditary hemochromatosis: An analysis of 255 heterozygotes

Iron studies were compared in 434 patients from 80 hemochromatosis families classified as putative homozygotes, heterozygotes, and normal by HLA typing. There were 28 of 255 (11%) heterozygotes with an elevated serum ferritin and 22 of 255 (8.6%) with an elevated transferrin saturation. Serum ferritin (140 ± 10.2 μg/liter; mean ± standard error) was greater in heterozygotes than in normal subjects (87 ± 8.5 μg/liter; P < .05, Mann Whitney test). Transferrin saturation was greater in heterozygotes (38% ± 0.88%) than in normal patients (29% ± 1.1%; P < .0001). Mean hepatic iron concentration was 54 ± 6 μmol/g (n = 17), and the hepatic iron index was <2 in these patients. Most heterozygotes for hemochromatosis have a normal serum ferritin and transferrin saturation. Heterorygotes with minor elevations in serum ferritin or transferrin saturation do not have significant iron overload as assessed by hepatic iron concentration. © 1994 Wiley-Liss, Inc.     

Population screening for hemochromatosis: a study in 5370 Spanish blood donors

BACKGROUND/AIMS: Hereditary hemochromatosis is associated with homozygosity for C282Y mutation in the HFE gene, elevated serum transferrin saturation and excess iron deposits throughout the body. We conducted a population-based study in Spain to asses the prevalence of the HFE mutations and their effect on iron parameters. METHODS: We screened 5370 blood donors for the C282Y and H63D HFE mutations by allele-specific polymerase chain reaction. Serum iron, serum ferritin and transferrin saturation were also measured. RESULTS: We have found eight (five men and three women) blood donors who are C282Y homozygotes (0.15%) and 74 C282Y/H63D compound heterozygotes (1.38%). Four out of the eight C282Y homozygotes, all men, had high serum ferritin and transferrin saturation values. No woman was detected with both iron parameters increased. Only one of the 74 C282Y/H63D compound heterozygotes showed elevated serum ferritin and transferrin saturation values (penetrance 1.35%). Serum ferritin and transferrin saturation were significantly higher in C282Y homozygous men as compared with the rest of the genotypes. CONCLUSIONS: The C282Y/C282Y genotype frequency in Spain is 1 in 1004. The C282Y/C282Y genotype is clearly associated with an increase in iron parameters. Biochemical expression of the disease was found in 80% of the C282Y/C282Y men.     

Probability of C282Y homozygosity decreases as liver transaminase activities increase in participants with hyperferritinemia in the hemochromatosis and iron overload screening study

Hemochromatosis is considered by many to be an uncommon disorder, although the prevalence of HFE (High Iron) 282 Cys → Tyr (C282Y) homozygosity is relatively high in Caucasians. Liver disease is one of the most consistent findings in advanced iron overload resulting from hemochromatosis. Liver clinics are often thought to be ideal venues for diagnosis of hemochromatosis, but diagnosis rates are often low. The Hemochromatosis and Iron Overload Screening (HEIRS) Study screened 99,711 primary care participants in North America for iron overload using serum ferritin and transferrin saturation measurements and HFE genotyping. In this HEIRS substudy, serum hepatic transaminases activities (e.g., alanine aminotransferase [ALT] and aspartate aminotransferase [AST]) were compared between 162 C282Y homozygotes and 1,367 nonhomozygotes with serum ferritin levels >300 μg/L in men and >200 μg/L in women and transferrin saturation >45% in women and 50% in men. The probability of being a C282Y homozygote was determined for AST and ALT ranges. Mean ALT and AST activities were significantly lower in C282Y homozygotes than nonhomozygotes. The probability of being a C282Y homozygote increased as the ALT and AST activities decreased. CONCLUSION: Patients with hyperferritinemia are more likely to be C282Y homozygotes if they have normal liver transaminase activities. This paradox could explain the low yields of hemochromatosis screening reported by some liver clinics.     

Serum transferrin receptor in hereditary hemochromatosis and African siderosis

The present investigation evaluated the serum transferrin receptor concentration in subjects with nontransfusional iron overload who were identified in two separate studies on the basis of a serum ferritin level above 400 μg/L. Subjects with preciinical hereditary hemochromatosis were evaluated in the first study and those with the African form of iron overload in the second. in the first study, hereditary hemochromatosis was identified in 14 white men on the basis of a persistent elevation in transferrin saturation above 55%. The serum receptor concentration was elevated above the upper cut-off of 8.5 mg/L in two of the subjects, but the mean receptor of 6.1 ± 1.4 mg/L (mean ± 2 SE) did not differ significantly from the normal mean for this assay of 5.6 ± 0.3 mg/L. In the same study, 60 control subjects with secondary iron overload were identified on the basis of a serum ferritin persistently above 400 μg/L, with a normal serum C-reactive protein concentration but with a transferrin saturation <55%. Three of these subjects had an elevated serum receptor concentration but the mean value of 5.5 ± 0.4 mg/L did not differ from normals nor from subjects with hemochromatosis. In the second study, 49 black Africans with iron overload were divided into those with or without an elevated transferrin saturation. The mean serum receptor concentration of 5.0 ± 0.8 mg/L and 4.5 ± 0.4 mg/L, respectively, did not differ statistically. It was concluded that there is no evidence of generalized dysreguiation of the transferrin receptor in hemochromatosis or African siderosis. © 1994 Wiley-Liss, Inc.     

The effect of HFE genotypes on measurements of iron overload in patients attending a health appraisal clinic

BACKGROUND: The gene that causes most cases of hereditary hemochromatosis is designated HFE. Three mutations exist at this locus at a relatively high gene frequency. OBJECTIVE: To determine the gene frequency of the three HFE mutations and to relate genotypes to various clinical and laboratory variables. DESIGN: Observational study. SETTING: Health appraisal clinic. PATIENTS: 10,198 adults who registered for health appraisal and consented to DNA examination for hemochromatosis. Consenting patients were slightly older and had attained a slightly higher educational level than nonconsenting patients. MEASUREMENTS: Extensive medical history and laboratory tests, including complete blood count, transferrin saturation, and other chemistries; serum ferritin levels; and HFE genotype. RESULTS: In white participants, the gene frequencies were 0.063 for the C282Y mutation, 0.152 for the H63D mutation, and 0.016 for the S65C mutation. Gene frequencies were lower in other ethnic groups. In participants with HFE mutations, the average serum transferrin saturation and ferritin levels were slightly increased, as were mean hemoglobin levels and mean corpuscular volume. A transferrin saturation of 50% had a sensitivity of only 0.52 (95% CI, 0.345 to 0.686) and a specificity of 0.908 (CI, 0.902 to 0.914) for detection of homozygosity. A ferritin level of 200 microg/L in women and 250 microg/L in men had a sensitivity of 0.70 (CI, 0.540 to 0.854) and a specificity of 0.803 (CI, 0.796 to 0.811). The prevalence of iron deficiency anemia was lower in women who carried HFE mutations. CONCLUSIONS: Screening for transferrin saturation and ferritin levels does not detect all homozygotes for the major hemochromatosis mutation. Heterozygotes for HFE mutations had a lower prevalence of iron deficiency anemia.     

Screening for hemochromatosis by measuring ferritin levels: a more effective approach

Because the penetrance of HFE hemochromatosis is low, traditional population screening measuring the transferrin saturation is unlikely to be cost-effective because the majority of subjects detected neither have clinical disease nor are likely to develop it. Three independent studies show that only patients with serum ferritin concentrations more than 1000 microg/L are at risk for cirrhosis, one of the main morbidities of hemochromatosis. Among 29,699 white subjects participating in the Scripps/Kaiser hemochromatosis study, only 59 had serum ferritin levels more than 1000 microg/L; 24 had homozygous mutant or compound heterozygous mutant HFE genotypes. In all but 5 of the other subjects, the causes of elevated ferritin were excessive alcohol intake, cancer, or liver disease. Screening for hemochromatosis with serum ferritin levels will detect the majority of patients who will be clinically affected and may detect other clinically significant disease in patients who do not have hemochromatosis genotypes. Because the ferritin level of the majority of adult homozygotes for HFE mutations does not rise over long periods of time, excluding subjects with serum ferritin levels less than or equal to 1000 microg/L should not result in missed opportunities for early treatment of patients who could benefit.     

The diagnosis of iron deficiency anemia in sickle cell disease

We determined the prevalence and optimal methods for laboratory diagnosis of iron deficiency anemia in patients with sickle cell disease. Laboratory investigations of 38 nontransfused and 32 transfused patients included transferrin saturation, serum ferritin, mean corpuscular volume (MCV), and free erythrocyte protoporphyrin (FEP). Response to iron supplementation confirmed the diagnosis of iron deficiency anemia in 16% of the nontransfused patients. None of the transfused patients were iron deficient. All iron-deficient patients (mean age 2.4 yr) had a low MCV, serum ferritin less than 25 ng/ml, transferrin saturation less than 15%, and FEP less than 90 micrograms/dl RBC. Following therapy, all parameters improved and the hemoglobin concentration increased greater than 2 g/dl. A serum ferritin below 25 ng/ml was the most reliable screening test for iron deficiency. There were 13% false positive results with transferrin saturation, 3% with MCV, and 62% with FEP. FEP values correlated strongly with reticulocyte counts. The high FEP was in part due to protoporphyrin IX and not completely due to zinc protoporphyrin, which is elevated in iron deficiency. We conclude that iron deficiency anemia is a potential problem in young nontransfused sickle cell patients. Serum ferritin below 25 ng/ml and low MCV are the most useful screening tests.     

Hemochromatosis: Association of Severity of Iron Overload with Genetic Markers

ABSTRACT: We postulated that the severity of iron overload in homozygous hemochromatosis probands is related to the expression of HLA-A3 or D6S105 allele 8. Therefore, we used these markers to characterize Alabama hemochromatosis probands and normal control subjects. We then quantified the blood removed by phlebotomy to exhaust body iron stores and maintain normal serum ferritin concentrations in our hemochromatosis probands. Induction and maintenance phlebotomy requirements were significantly greater in presumed HLA-A3 homozygotes or in D6S105 allele 8 homozygotes than in homozygous probands lacking these markers. Intermediate values were observed in probands who were HLA-A3 or allele 8 heterozygotes, respectively. We also analyzed data from males and females separately. Among subjects of the same sex, the induction and maintenance phlebotomy requirements in subjects presumed to be HLA-A3 homozygotes or in allele 8 homozygotes were greater than those of other groups. Our results support the hypothesis that the severity of iron overload in hemochromatosis is determined predominantly by genetic factors, and provide evidence that two or more mutations for hemochromatosis exist. However, the design of our study does not permit a distinction to be made between allelic and locus heterogeneity for the hemochromatosis gene(s).     

Hepatic Iron Concentration in Hereditary Hemochromatosis Does Not Saturate or Accurately Predict Phlebotomy Requirements

Objective : Biochemical measurement of the hepatic iron concentration (HIC) is essential for the diagnosis of hereditary hemochromatosis (HH). The aim of this study was to determine whether the HIC at the time of diagnosis could predict the subsequent phlebotomy requirements and to determine whether saturation of HIC occurred in HH. Methods : Fifty-four patients (32 male, 22 female) with homozygous HH were evaluated, and HIC was measured in liver biopsies. Patients were subjected to weekly phlebotomy (500 ml) until the transferrin saturation was <50% and/or the serum ferritin concentration was <50 μg/L. The relationship between HIC and total body iron stores (as measured by phlebotomy requirements) was determined using both linear and nonlinear (sigmoidal model) least squares regression. Results : The HIC ranged from 3,742 to 41,040 μg/g dry wt. A linear relationship between HIC and total body iron stores (iron removed, IR, g) best described the data both in male (HIC = 1986 IR – 3494;  r = 0.83  ;   p < 0.001  ) and female HH patients (HIC = 1251 IR + 2690;  r = 0.75  ;   p < 0.001  ). Men required eight more phlebotomies (2 g iron) on average, compared with women, to reach normal iron stores. There was no evidence of saturation of hepatic iron levels at higher total body iron stores. However, accurate prediction of individual phlebotomy requirements based on the HIC or serum ferritin concentration at the time of diagnosis was not possible. Conclusion : The phlebotomy requirement for treatment of HH cannot be accurately predicted from the initial HIC or serum ferritin level. Within the range examined, hepatic iron deposition did not saturate in HH.     

Hereditary hemochromatosis

Hereditary hemochromatosis (hh, type 1 hemochromatosis) is an autosomal recessive trait characterized by hyperabsorption of dietary iron. The disease trait occurs in approximately five per thousand Caucasians of northern European descent. The causative gene, designated HFE, was isolated and characterized in 1996; most individuals with hh are homozygous for a mutation resulting in a change from cysteine to tyrosine at residue 282 of the HFE protein (C282Y). Wild-type HFE protein binds to the transferrin receptor, and by an undefined mechanism the enterocyte is "programmed" to absorb an amount of dietary iron precisely matched to the body's needs. The C282Y mutant protein is not expressed on the cell surface and does not bind to the transferrin receptor; the result is an enterocyte programmed to absorb slightly more iron than required. Most individuals with hh display a common laboratory phenotype, an elevated transferrin saturation. Iron stores in excess of normal eventually occur in most men and some women. The prevalence of organ damage due to iron overload, however, remains a controversial issue. Published estimates range from less than 1% to "nearly all." The main reason for this discrepancy has been ascertainment bias. Retrospective studies have been biased in favor of individuals with morbid complications of hh, whereas screening studies of groups such as blood donors generally include only healthy subjects. We focus here on a review of studies that have attempted to avoid ascertainment bias. If biopsy-proven hepatic fibrosis and/or cirrhosis is employed as the single criterion for disease-related morbidity, clinical penetrance of hh occurs in 4% to 25% of homozygotes. This range, although narrower than in biased studies, is still wide and requires clarification. A large-scale population-based study has been sponsored by the National Institutes of Health to address this issue. Until results become available, the pragmatic approach is to continue to screen for hemochromatosis in the primary care setting and to maintain serum ferritin values at approximately 100 micro g/L or lower with phlebotomy therapy.