The Role of Intravenous Ironin Cancer-Related Anemia
The Role of Intravenous Ironin Cancer-Related Anemia
ABSTRACT: Patients with cancer may have an absolute or functional iron deficiency as a result of their disease or its treatment. These conditions can lead to an insufficient supply of iron for incorporation into erythrocytes during supportive care with erythropoiesis-stimulating proteins for chemotherapy. The use of supplemental iron therapy is well established in patients with chronic kidney disease and anemia, but less well studied in the oncology/hematology setting. Furthermore, the use of oral iron formulations in patients with cancer and anemia is limited by poor absorption in the duodenum, arduous dosing requirements (three times a day), and a high likelihood of gastrointestinal side effects. Two recent studies have shown that intravenous (IV) iron (iron dextran or ferric gluconate) increases the hematopoietic response rates in cancer patients who were receiving chemotherapy and treated with epoetin alfa (Procrit) for anemia. The effects on hemoglobin levels and measures of iron metabolism were notably greater with IV iron formulations than with oral iron formulations. The results from several ongoing trials of IV iron in patients treated with epoetin alfa or darbepoetin alfa (Aranesp) for chemotherapy-induced anemia should lead to a greater understanding of the role of IV iron supplementation in improving the hematopoietic responses in these patients.
Anemia is a common complication of cancer and its treatment, and can be attributed to several factors, the most evident being the myelosuppressive effects of chemotherapy and the immunosuppressive effects of chronic disease. The anemia of chronic disease in cancer is mediated by the emergence of malignant cells that induce the expression of a variety of proinflammatory cytokines from immune cells. The consequences of this inflammatory state include insufficient production of erythropoietin by the kidneys, a blunted response to erythropoietin that leads to inhibition of erythropoiesis, impaired proliferation of erythroid progenitor cells, and dysregulation of iron homeostasis (reviewed by Weiss and Goodnough). In addition, direct effects of chemotherapeutics, particularly platinum compounds, on the kidneys can also lead to a decrease in the production of erythropoietin. These factors all contribute to lower hemoglobin (Hgb) levels and, consequently, impair quality of life in patients with cancer receiving chemotherapy.
Current management of chemotherapy-induced anemia centers on therapeutic erythropoiesis-stimulating proteins (ESPs) such as recombinant human erythropoietin (epoetin alfa [Procrit]) and the novel long-acting ESP darbepoetin alfa (Aranesp). Epoetin alfa has been shown to increase Hgb levels in patients with cancer treated with chemotherapy, with associated reductions in the need for red blood cell transfusions and improvements in quality of life.[3-9] Likewise, darbepoetin alfa alleviates chemotherapy-induced anemia and improves quality of life in patients with cancer, with the additional benefit of making a reduced dosing schedule possible.[10-15] The responses to therapy with ESPs are inadequate, however, in approximately one-third of patients with cancer and anemia who undergo chemotherapy,[3-7,10-12] possibly owing to an insufficiency of iron for erythrocyte incorporation during the rapid induction of erythropoiesis stimulated by ESPs. Analysis of pretreatment laboratory values in patients who were being considered for treatment with epoetin alfa found that iron deficiency was a significant cause of their anemia, with 17% of patients having ferritin levels less than 100 ng/mL, 59% having transferrin saturation (TSAT) less than 20%, and 27% having content of reticulocyte Hgb less than 32 g/dL. The use of supplemental iron is well established in patients with chronic kidney disease and anemia, but its effectiveness in patients with cancer is less clear.
Dysregulation of Iron Metabolism in Anemia
Labile iron and iron stores are generally kept in dynamic equilibrium in the reticuloendothelial system. Developing erythrocytes in the bone marrow obtain iron from the pool of labile iron. Anemia related to iron deficiency may result from a patient not having sufficient labile iron available for incorporation into erythrocytes despite having adequate iron stores (as in patients with anemia of chronic disease) or from a state of iron depletion within the iron stores (as in patients with an absolute iron deficiency).
A number of markers of iron homeostasis can be used to differentiate between anemia of chronic disease and absolute iron deficiency (Table 1).[2,19-21] In a population of patients with anemia of any cause, a serum ferritin level of 100 ng/mL or less was the most sensitive and specific marker of iron deficiency. Total iron-binding capacity and TSAT were less able to differentiate between iron deficiency and iron sufficiency. Furthermore, because serum ferritin levels reflect the stored iron component and soluble transferrin receptor (sTfR) levels reflect the available iron component, the sTfR/log ferritin index makes it possible to differentiate iron deficiency into iron-depleted and iron-sufficient functional iron deficiency states. The correlation between this index and the hemoglobinization of red blood cells makes it possible to map the progression of iron deficiency.
The clinical practice guidelines of the National Comprehensive Cancer Network recommend iron supplementation in patients with cancer when the ferritin levels are less than 100 ng/mL and TSAT is less than 20%. The guidelines of the American Society of Clinical Oncology and the American Society of Hematology are less specific, noting the paucity of evidence for using iron supplementation in cancer-related anemia. Oral iron supplementation is often used in patients with iron deficiency, but its effectiveness in patients receiving ESPs for chemotherapy-induced anemia is limited in that it does not provide iron rapidly enough for ESP-induced erythropoiesis.
Elevated levels of interleukin-6 and lipopolysaccharides as a consequence of inflammation lead to greater expression of the acute-phase protein hepcidin in the liver, which in turn decreases the intestinal absorption of iron.[24,25] To attempt to overcome this limited absorption, it may be necessary to give oral iron three times a day to produce sufficiently high serum levels, but this can be associated with adherence problems and gastrointestinal adverse effects and may still be ineffective because of inflammatory cytokines and hepcidin.
Parenteral iron may be an alternative to oral iron supplementation. Several intravenous (IV) formulations of iron have been developed: iron dextran, iron sucrose, and ferric gluconate (reviewed in Silverstein and Rogers). Iron dextran has been available for use in the United States for several decades, and iron sucrose and ferric gluconate have been approved only in the past few years. Iron dextran has a half-life of 5 to 20 hours, and the patient's total dose can be given in one infusion (total dose infusion [TDI]). However, delayed reactions of arthralgia, backache, chills, dizziness, fever, headache, myalgia, malaise, and nausea and vomiting have been associated with TDI; therefore, it is recommended that patients be given a test dose before the total dose is administered.
Iron sucrose and ferric gluconate are more readily available for erythropoiesis than iron dextran. Iron sucrose has a half-life of 5 to 6 hours and is transferred directly to both the reticuloendothelial system and transferrin,[28,29] while ferric gluconate has a half-life of approximately 1 hour and is transferred directly to the reticuloendothelial system, after which a bioactive form is released for binding to transferrin. The rates of serious anaphylaxis hypersensitivity, hypersensitivity reactions, and adverse drug reactions are lower with iron sucrose and ferric gluconate than with iron dextran, and test doses are not required with these agents.