Abstract
Iron sucrose originator (ISORIG) has been used to treat iron deficiency and iron deficiency anemia for decades. Iron sucrose similars (ISSs) have recently entered the market. In this non-clinical study of non-anemic rats, five doses (40 mg iron/kg body weight) of six ISSs marketed in Asian countries, ISORIG or saline solution (control) were administered intravenously over four weeks to compare their toxicologic effects. Vasodilatory effects, impaired renal function and hepatic damage were only observed in the ISS groups. Significantly elevated serum iron and transferrin saturation levels were observed in the ISS groups suggesting a higher release of iron resulting in higher amounts of non-transferrin bound (free) iron compared to ISORIG. This might explain the elevated oxidative stress and increased levels of inflammatory markers and antioxidant enzymes in the liver, heart and kidneys of ISS-treated animals. Physico-chemical analyses showed that the molecular structure of most of the ISSs differed greatly from that of the ISORIG. These differences may be responsible for the organ damage and oxidative stress observed in the ISS groups. Significant differences were also found between different lots of a single ISS product. In contrast, polarographic analyses of three different ISORIG lots were identical, indicating that the molecular structure and thus the manufacturing process for ISORIG is highly consistent. Data from this study suggest that ISSs and ISORIG differ significantly. Therefore, before widespread use of these products it would be prudent to evaluate additional non-clinical and/or clinical data proving the safety, therapeutic equivalence and interchangeability of ISSs with ISORIG.
Highlights
Iron deficiency (ID) is one of the world’s most prevalent nutrient deficiencies [1]
Untreated ID can lead to iron deficiency anemia (IDA), a condition in which the number of red blood cells (RBCs), the hemoglobin (Hb) level, and the volume of packed RBCs in the blood are below the normal values [2, 3]
The supernatant obtained after centrifugation at 105,000 g for 90 min was used to measure Cu, Zn superoxide dismutase (Cu, Zn-SOD) and glutathione peroxidase (GPx) activity
Summary
Iron deficiency (ID) is one of the world’s most prevalent nutrient deficiencies [1]. It has various causes, such as increased iron demands due to blood loss, growth, pregnancy, inadequate dietary intake due to poor nutrition, and inadequate gastrointestinal absorption due to malabsorption or interference with drugs and food components. Untreated ID can lead to iron deficiency anemia (IDA), a condition in which the number of red blood cells (RBCs), the hemoglobin (Hb) level, and the volume of packed RBCs in the blood are below the normal values [2, 3]. Due to the risk of life-threatening/serious anaphylactic reactions associated with i.v. iron dextran, in particular high-molecular weight iron dextran, this form of iron therapy is not generally recommended [15,16,17]. NTBI is taken up unspecifically by the liver, endocrine tissue and heart where it may catalyze a number of reactions that lead to oxidative stress and tissue damage [19, 20]. More stable iron complexes can be administered in higher doses
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