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Blood, Vol. 96 No. 1 (July 1), 2000:
pp. 76-79
CLINICAL OBSERVATIONS, INTERVENTIONS, AND THERAPEUTIC TRIALS
From the Departments of Gastroenterology, Hematology/Oncology, and
Pathology, Children's Hospital Oakland, Oakland, and the Department of
Pathology, University of California, San Francisco/Stanford Health
Care, San Francisco, CA; and the Division of Clinical Biochemistry and
Immunology, Mayo, Rochester, MN.
Chronic transfusion therapy is being used more frequently to
prevent and treat the complications of sickle cell disease. Previous studies have shown that the iron overload that results from such therapy in other patient populations is associated with significant morbidity and mortality. In this study we examined the extent of iron
overload as well as the presence of liver injury and the predictive
value of ferritin in estimating iron overload in children with sickle
cell disease who receive chronic red blood cell transfusions. A poor
correlation was observed between serum ferritin and the quantitative
iron on liver biopsy (mean 13.68 ± 6.64 mg/g dry weight;
R = 0.350, P = .142). Quantitative iron was
highly correlated with the months of transfusion
(R = 0.795, P < .001), but serum ferritin at
biopsy did not correlate with months of transfusion (R = 0.308, P = .200). Sixteen patients had
abnormal biopsies showing mild to moderate changes on evaluation of
inflammation or fibrosis. Liver iron was correlated with fibrosis score
(R = 0.50, P = .042). No complications were
associated with the liver biopsy. Our data suggest that, in patients
with sickle cell disease, ferritin is a poor marker for accurately
assessing iron overload and should not be used to direct long-term
chelation therapy. Despite high levels of liver iron, the associated
liver injury was not severe.
(Blood. 2000;96:76-79)
Red blood cell (RBC) transfusions have been actively
used for many years to treat acute illnesses in sickle cell disease
(SCD). The recent demonstration by Adams and colleagues1
that chronic RBC transfusions are effective in preventing stroke has
lead to a rapid increase in patients who are receiving chronic
transfusions and concern about the development of iron overload and
possible injury. The Stroke Prevention Trial in Sickle Cell Anemia
(STOP) study has in fact already reported an increase in serum ferritin in study participants, suggesting the development of iron overload in
these patients.2 Disease complications and early death have been associated with increased iron overload in patients with hereditary hemochromatosis and The goals of this study were to determine the severity of iron overload
in patients who receive chronic RBC transfusions, to assess whether
serum ferritin is a useful clinical marker of iron overload, and to
determine whether significant liver injury occurs in patients with SCD
who are chronically transfused.
In this study, patients participating in the Northern California
Comprehensive Sickle Cell Center (NCCSCC) and receiving chronic RBC
transfusions agreed to percutaneous liver biopsy to assess their iron
overload. These patients were participants in a chronic transfusion
protocol, initiated because of the recent increased frequency of RBC
transfusions in SCD. One of the aims of the protocol was to monitor the
degree of iron overload and liver tissue injury. According to protocol
criteria, patients were immunized to hepatitis A and B, serum ferritin
was monitored monthly and at biopsy, and liver functions (alanine
aminotransferase [ALT], aspartate aminotransferase [AST], alkaline phosphatase) were monitored bimonthly. Hepatitis serologies were obtained yearly. Serum ferritin was analyzed by heterogeneous sandwich magnetic separation assay (MSA), with a range of
0.3 to 1000 µg/L and standardized by the World Health Organization
(WHO) 1st International Standard (IS 80/802) (Unilab, San Jose, CA).
Serum ferritin at initiation of chronic transfusion therapy and peak
serum ferritin were single values measured at the respective time
points. Serum ferritin at biopsy was calculated as the average of all
measurements obtained in the 6 months preceding the biopsy. A similar
schema for determining ALT values was used. To be eligible for liver
biopsy, patients with sickle cell hemoglobinopathy must have enrolled
in a chronic monthly transfusion program, completed monthly
transfusions for a minimum of 1 year, had normal coagulation studies,
and provided informed consent.
Subjects
Iron overload
Ferritin
Liver injury Injury on liver biopsy was assessed independently by the 2 pathologists. Again, there was a strong correlation between pathologists' scores on fibrosis (R = 0.904, P < .001) and inflammation (R = 0.782, P < .001) with 84% agreement on individual scores for fibrosis and 89% agreement on individual scores for inflammation. Sixteen of the 20 samples had mild-to-moderate abnormalities on assessment of inflammation or fibrosis. The mean scores were less than 1 on both parameters, suggesting that the extent of liver injury was mild, despite the very high iron overload. Severity of liver iron overload did not correlate with inflammation (R = 0.196, P = .380), but did correlate
with fibrosis (R = 0.480, P = .042).
Iron staining pattern The 2 pathologists assessed iron intensity and distribution. There was 92% agreement between pathologists on individual scores in each location and a strong correlation between pathologists on total iron score (R = 0.988, P < .001). The mean total iron score was 33.474 ± 8.72 (possible range 0-60) (Figure 2), with mean hepatocyte score of 21.45 ± 6.832 (possible range 0-36), mean Kupffer cell score of 10.2 ± 1.196 (possible range 0-12), and mean portal tract score of 1.579 ± 1.539 (possible range 0-12). The mean hepatocyte iron score was 58% of the maximum possible score; the mean Kupffer cell score was 83% of the maximum possible score. This suggests that the intensity of staining in Kupffer cells is greater than in hepatocytes (P < .001). Although less intense iron staining occurs in hepatocytes, the hepatocyte compartment is larger than the Kupffer cell compartment and accounts for three- fifths of the total iron score. Of note, the total iron score by histologic assessment was correlated with the biochemical liver iron (R = 0.602, P = .011).
Splenectomy and liver iron The mean iron level in patients who had previously undergone splenectomy was 20.6 ± 6.25 mg/g, whereas the mean iron level in patients without previous splenectomy was 10.72 ± 4.18 mg/g (P < .01). There was a positive correlation between splenectomy and months of transfusion (R = 0.664, P < .01). In multivariate analysis, splenectomy did not appear to be an independent predictor of liver iron (P = .106), whereas months of transfusion was an independent predictor (P < .01). No significant association was noted between splenectomy and age of the patient (R = 0.296, P = .205) or ferritin at biopsy (R = 0.050, P = .840).Complications of biopsy No complications were associated with the liver biopsy. No patient developed infection related to the liver biopsy or suffered organ injury or bleeding. Hemoglobin did not decrease after liver biopsy (pre-Hb 10.9 ± 1.4 g/dL vs post-Hb 10.5 ± 1.0 g/dL) and no transfusions were required in relation to the biopsy.
Iron overload In this study, transfusion-dependent children with sickle cell disease demonstrated increased iron deposition with duration of transfusion, despite chelation therapy. From Cohen et al,8 this would imply ineffective chelation therapy or poor compliance in the entire population. Our patients were receiving 30 to 50 mg/kg per dose of deferoxamine and 14 of the 19 patients on chelation began this therapy within 2 years of starting transfusion therapy (mean lag time 13.5 ± 8.8 months, range 2-30 months).
Ferritin Plasma ferritin is correlated significantly with other measures of body storage iron in most studies but clinically is an imprecise estimate of body iron burden. In this study, plasma ferritin concentration did not correlate with liver iron. This finding is consistent with recent reports from the thalassemia literature that suggest serum ferritin may in fact be a poor and possibly misleading measure in the heavily overloaded patient.11,12 The relationship between plasma ferritin and body iron stores is distorted by ascorbate deficiency, fever, infection, inflammation, and hepatic dysfunction, all of which occur in patients with sickle cell disease.11 Brittenham et al11 found that only 57% of the variability in ferritin could be explained by the variation in hepatic iron and, therefore the usefulness of ferritin in predicting hepatic iron is limited. One means of improving the value of ferritin measurements would be the application of a logarithmic quantitation model that uses individual transfused iron values. This model has been shown to yield a median correlation between serum ferritin and transfused iron of 0.92 in patients with sickle cell disease.13Liver injury As expected, this study demonstrated a high level of iron overload. This iron overload is of concern as it may result in portal fibrosis.9 In the hemochromatosis population, increased liver iron has also been associated with inflammation5 and cancer.14Iron staining pattern The cell distribution of iron shows different patterns in hereditary hemochromatosis and transfusional overload. In hereditary hemochromatosis, the hepatocyte contains high amounts of iron, whereas the Kupffer cell or sinusoidal cell does not contain iron, except in late-stage disease, while in transfusional overload, the reverse pattern is reported.15 In this study, the intensity of iron staining in the hepatocyte and Kupffer cell, relative to the total possible score for each, was 0.58 versus 0.85, respectively, demonstrating higher relative deposition of iron in the Kupffer cell as expected in transfusional overload. However, overall, the hepatocyte accounted for a large proportion (0.6) of the total iron score. This may reflect overflow from the Kupffer cell to the heptocyte in patients who are very heavily iron overloaded as previously observed by Bothwell and colleagues.16Splenectomy and liver iron Splenectomy has been used in thalassemia and sickle cell disease to treat hypersplenism and reduce transfusion requirement. Although we were not able to demonstrate a statistically significant effect of splenectomy on liver iron in multivariate analysis, this was a preliminary study that included only 6 subjects with splenectomy, and it is possible that splenectomy will prove to have a significant effect in increasing liver iron in a larger sample. A similar increase in liver iron has been reported in splenectomized patients with E/beta thalassemia, and has been associated with an increase in intestinal iron uptake.17 Similar findings have not been described in sickle cell disease. Further studies are needed to characterize this phenomenon.Complications of biopsy It is well known that percutaneous liver biopsy is associated with a small risk of bleeding, infection, and puncture of an abdominal organ other than the liver.18 In our study, the risks were minimized by obtaining ultrasound guidance for the procedure; arresting the breathing during the biopsy, preventing laceration by the needle; completing the procedure on patients with normal coagulation studies; and providing close observation after the procedure with blood available, if needed. In the group reported in this study, no medical complications were noted. Hemoglobin did not decrease in relation to biopsy. These findings are consistent with those of Angelucci et al18 who found a complication rate of 0.2% in patients with iron overload.Conclusion In conclusion, chronic transfusion produced high levels of iron overload, ferritin was shown to be a poor clinical marker for this population, iron overload increased with duration of transfusion despite aggressive chelation, liver injury was mild, splenectomy was associated with increased liver iron, and percutaneous liver biopsy proved a safe procedure in this group of patients.
We would like to thank Ekua Hackney-Stephens for her expert clinical assistance.
Submitted November 1, 1999; accepted February 23, 2000.
Supported by NIH grants nos. M01RR01271-16 and HL-20985.
Reprints: Paul Harmatz, Gastroenterology and Nutrition, Children's Hospital Oakland, 747 52nd St, Oakland, CA 94609; e-mail: pharmatz{at}mail.cho.org.
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
1.
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Prevention of a first stroke by transfusions in children with sickle cell anemia and abnormal results on transcranial Doppler ultrasonography.
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4.
Brittenham GM, Griffith PM, Nienhuis AW, et al.
Efficacy of deferoxamine in preventing complications of iron overload in patients with thalassemia major.
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1994;331:567-573 5. Deugnier YM, Loreal O, Turlin B, et al. Liver pathology in genetic hemochromatosis: a review of 135 homozygous cases and their bioclinical correlations. Gastroenterology. 1992;102:2050-2059[Medline] [Order article via Infotrieve]. 6. Ludwig J. The nomenclature of chronic active hepatitis: an obituary. Gastroenterology. 1993;105:274-278[Medline] [Order article via Infotrieve]. 7. Desmet VJ, Gerber M, Hoofnagle JH, Manns M, Scheuer PJ. Classification of chronic hepatitis: diagnosis, grading and staging. Hepatology. 1994;19:1513-1520[Medline] [Order article via Infotrieve]. 8. Cohen A, Gayer R, Mizanin J. Long-term effect of splenectomy on transfusion requirements in thalassemia major. Am J Hematol. 1989;30:254-256[Medline] [Order article via Infotrieve].
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  P. Halonen, J. Mattila, P. Suominen, T. Ruuska, M. K. Salo, and A. Makipernaa Iron Overload in Children Who Are Treated for Acute Lymphoblastic Leukemia Estimated by Liver Siderosis and Serum Iron Parameters Pediatrics, January 1, 2003; 111(1): 91 - 96. [Abstract] [Full Text] [PDF]
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 G. M. Brittenham and D. G. Badman Noninvasive measurement of iron: report of an NIDDK workshop Blood, January 1, 2003; 101(1): 15 - 19. [Abstract] [Full Text] [PDF]
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N. Zakaria, A. Knisely, B. Portmann, G. Mieli-Vergani, J. Wendon, R. Arya, and J. Devlin Acute sickle cell hepatopathy represents a potential contraindication for percutaneous liver biopsy Blood, January 1, 2003; 101(1): 101 - 103. [Abstract] [Full Text] [PDF]
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 K. A. Schwartz, Z. Li, D. E. Schwartz, T. G. Cooper, and W. E. Braselton Earliest cardiac toxicity induced by iron overload selectively inhibits electrical conduction J Appl Physiol, August 1, 2002; 93(2): 746 - 751. [Abstract] [Full Text] [PDF]
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Section on Hematology/Oncology and Committee on Ge Health Supervision for Children with Sickle Cell Disease Pediatrics, March 1, 2002; 109(3): 526 - 535. [Abstract] [Full Text] [PDF]
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 J. P. Kushner, J. P. Porter, and N. F. Olivieri Secondary Iron Overload Hematology, January 1, 2001; 2001(1): 47 - 61. [Abstract] [Full Text] [PDF]
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Top
Abstract
Introduction
thalassemia,
