In older adults, iron dextran and ferumoxytol each had higher anaphylaxis risk at ≤1 d than iron sucrose.

SOURCE CITATION: Dave CV, Brittenham GM, Carson JL, et al. Risks for anaphylaxis with intravenous iron formulations: a retrospective cohort study. Ann Intern Med. 2022;175:656-64. 35344378.

Risks for Anaphylaxis With Intravenous Iron Formulations : A Retrospective Cohort Study.

BACKGROUND: The risks for anaphylaxis among intravenous (IV) iron products currently in use have not been assessed. OBJECTIVE: To compare risks for anaphylaxis among 5 IV iron products that are used frequently. DESIGN: Retrospective cohort study using a target trial emulation framework. SETTING: Medicare fee-for-service data with Part D coverage between July 2013 and December 2018. PARTICIPANTS: Older adults receiving their first administration of IV iron. MEASUREMENTS: The primary outcome was the occurrence of anaphylaxis within 1 day of IV iron administration, ascertained using a validated case definition. Analysis was adjusted for 40 baseline covariates using inverse probability of treatment weighting. The adjusted incidence rates (IRs) for anaphylaxis per 10 000 first administrations and odds ratios (ORs) were computed. RESULTS: The adjusted IRs for anaphylaxis per 10 000 first administrations were 9.8 cases (95% CI, 6.2 to 15.3 cases) for iron dextran, 4.0 cases (CI, 2.5 to 6.6 cases) for ferumoxytol, 1.5 cases (CI, 0.3 to 6.6 cases) for ferric gluconate, 1.2 cases (CI, 0.6 to 2.5 cases) for iron sucrose, and 0.8 cases (CI, 0.3 to 2.6 cases) for ferric carboxymaltose. Using iron sucrose as the referent category, the adjusted ORs for anaphylaxis were 8.3 (CI, 3.5 to 19.8) for iron dextran and 3.4 (CI, 1.4 to 8.3) for ferumoxytol. When cohort entry was restricted to the period after withdrawal of high-molecular-weight iron dextran from the U.S. market in 2014, the risk for anaphylaxis associated with low-molecular-weight iron dextran (OR, 8.4 [CI, 2.8 to 24.7]) did not change appreciably. Anaphylactic reactions requiring hospitalizations were observed only among patients using iron dextran or ferumoxytol. LIMITATION: Generalizability to non-Medicare populations. CONCLUSION: The rates of anaphylaxis were very low with all IV iron products but were 3- to 8-fold greater for iron dextran and ferumoxytol than for iron sucrose. PRIMARY FUNDING SOURCE: None.

A retrospective study of the safety and efficacy of low molecular weight iron dextran for children with iron deficiency anemia.

BACKGROUND: Iron deficiency anemia (IDA) affects millions of children worldwide. Oral iron replacement is effective but often poorly tolerated. Intravenous iron has been demonstrated to have utility in all ages, but pediatric use remains limited. Low molecular weight iron dextran (LMWID) has a dosing range capable of replacing iron deficits in a single infusion and has been evaluated in small pediatric cohorts, but additional safety and efficacy data are limited. Here, we evaluate the safety and efficacy of LMWID in association with an electronic medical record (EMR)-based effort to optimize dosing. PROCEDURE: A retrospective IRB-approved investigation of LMWID utilization at a tertiary pediatric hospital between January 1, 2016 and March 31, 2020 was undertaken to evaluate the therapeutic efficacy and frequency/severity of infusion-related adverse event (AE) in children and adolescents receiving LMWID. Patient demographics and LMWID dosing characteristics were collected, and primary outcome measures included laboratory response and the incidence/severity of any infusion-related events. The utilization of an EMR-based nomogram for LMWID dosing was also evaluated. RESULTS: A total of 254 infusions for 191 patients were included (ages 0.7-20.9 years), most with IDA. LMWID replaced at least 75% of the estimated iron deficit in a single infusion for 76% of patients. The mean hemoglobin and ferritin increases were 2.1 g/dl and >100 ng/ml, respectively. Infusion-related AEs were rare, occurring in only 12/254 (4.7%) of infusions and 67% during the test dose; each rapidly resolved without long-term sequelae. No AEs occurred in those <10 years of age. Premedication use markedly decreased with nomogram use without a change in AE rate. CONCLUSIONS: In a large institutional cohort, LMWID was well tolerated in children and adolescents, with most patients having their total iron deficits relieved in a single infusion. These data support expanded use of LMWID in the management of pediatric iron deficiency.

A multicenter study evaluating the effectiveness and safety of single-dose low molecular weight iron dextran vs single-dose ferumoxytol for the treatment of iron deficiency.

There are multiple intravenous (IV) iron formulations available, of which several may be administered as single-dose infusions such as low-molecular weight iron dextran (LMWID), ferumoxytol, ferric carboxymaltose, and ferric derisomaltose. However, administration of ferumoxytol as a single-dose infusion is off-label as it is approved as a two-dose series. Previous studies of ferumoxytol alone support the effectiveness and safety of the single-dose regimen, but there is a paucity of data directly comparing single-dose ferumoxytol to other single-dose IV iron formulations. This multicenter cohort study sought to affirm the safety and effectiveness of single-dose ferumoxytol compared to single-dose LMWID. Overall, 906 patients who received single-dose LMWID (n = 439) or ferumoxytol (n = 467) were identified, of whom 351 met criteria for the primary effectiveness endpoint defined as median change in hemoglobin (Hb), hematocrit (Hct), and ferritin 8 to 12 weeks from baseline. All 906 patients were included for the secondary analysis evaluating the incidence of adverse events (AE) and requirement of additional IV iron infusions. Median change in Hb (LMWID 0.5 g/dL; ferumoxytol 0.8 g/dL; P = .24), Hct (LMWID 1.1%; ferumoxytol 1.25%; P = .89), and ferritin (LMWID 87 ng/dL; ferumoxytol 71 ng/dL; P = .47) was not significantly different between groups. Both groups experienced similar rates of AEs (LMWID 2.3%; ferumoxytol 2.8%; P = .63). The LMWID patients more frequently required additional IV iron infusions (LMWID 28.5%; ferumoxtyol 16.1%; P < .001). These findings support that single-dose ferumoxytol is effective and safe, and that patients may require fewer additional infusions compared to patients who received LMWID.

Consequences of parenteral iron-dextran loading investigated in minipigs. A new model of transfusional iron overload.

Patients with blood transfusion-dependent anemias develop transfusional iron overload (TIO), which may cause cardiosiderosis. In patients with an ineffective erythropoiesis, such as thalassemia major, common transfusion regimes aim at suppression of erythropoiesis and of enteral iron loading. Recent data suggest that maintaining residual, ineffective erythropoiesis may protect from cardiosiderosis. We investigated the common consequences of TIO, including cardiosiderosis, in a minipig model of iron overload with normal erythropoiesis. TIO was mimicked by long-term, weekly iron-dextran injections. Iron-dextran loading for around one year induced very high liver iron concentrations, but extrahepatic iron loading, and iron-induced toxicities were mild and did not include fibrosis. Iron deposits were primarily in reticuloendothelial cells, and parenchymal cardiac iron loading was mild. Compared to non-thalassemic patients with TIO, comparable cardiosiderosis in minipigs required about 4-fold greater body iron loads. It is suggested that this resistance against extrahepatic iron loading and toxicity in minipigs may at least in part be explained by a protective effect of the normal erythropoiesis, and additionally by a larger total iron storage capacity of RES than in patients with TIO. Parenteral iron-dextran loading of minipigs is a promising and feasible large-animal model of iron overload, that may mimic TIO in non-thalassemic patients.

Evaluation of the reported rates of hypersensitivity reactions associated with iron dextran and ferric carboxymaltose based on global data from VigiBase™ and IQVIA™ MIDAS® over a ten-year period from 2008 to 2017.

Objectives: It is hypothesized that the risk of hypersensitivity reactions (HSRs) may be lower with ferric carboxymaltose than iron dextran because of its non-dextran carbohydrate moiety. This study compares the risk of HSRs between iron dextran and ferric carboxymaltose.Methods: This was a retrospective pharmacoepidemiological study with a case-population design covering 2008-2017. Global exposure data were estimated using IQVIA™ sales data. Spontaneously reported HSR data were retrieved from the World Health Organization database (VigiBase™) using different search criteria including: the Standardized MedDRA® Query (SMQ) 'Anaphylactic reaction'; type I-IV HSR terms; narrow terms for anaphylactic/anaphylactoid reactions; and cases with a fatal outcome.Results: Total exposure in 100 mg doses was 117.3 million for iron dextran and 84.2 million for ferric carboxymaltose. The relative risk (with 95% confidence interval) for ferric carboxymaltose versus iron dextran was 4.18 (3.88-4.50) for SMQ Anaphylactic reaction; 12.9 (9.90-16.7) for type I-IV HSRs; 1.72 (1.45-2.04) for anaphylactic/anaphylactoid reactions; and 1.92 (1.24-2.99) for death.Conclusion: The risk of spontaneously reported HSRs was consistently higher with ferric carboxy-maltose than with iron dextran over the period 2008-2017. Thus, this study does not support that dextran-free intravenous irons are associated with fewer HSRs than iron dextran.

Intravenous iron supplementation does not increase infectious disease risk in hemodialysis patients: a nationwide cohort-based case-crossover study.

BACKGROUND: Studies have reported conflicting findings on the infection risk posed by intravenous iron supplementation among hemodialysis (HD) patients. We used a novel study design to assess associations between intravenous iron and infectious diseases. METHODS: Patients initiating HD between 1998 and 2008 were extracted from Taiwan's National Health Insurance Research Database. Their first infectious disease in the period between 1.5 years after dialysis initiation and 2010 was identified and defined as the index date. Through the case-crossover design, the odds of exposure to intravenous iron within the 1-month period immediately preceding the index date (i.e., the case period) were compared with iron exposure in three different matched control periods for the same enrollee, thus possibly reducing some unmeasured confounders. RESULTS: A total of 1410 patients who met our enrollment criteria were extracted from incident HD patients. The odds of intravenous iron exposure during the case period versus total control periods exhibited no significant difference (odds ratio: 1.000, 95% confidence interval: 0.75-1.33). In subgroup analyses, this association remained nonsignificant across patients with diabetes mellitus, heart failure, chronic lung disease, venous catheter for HD, and higher iron load. CONCLUSIONS: We found that intravenous iron supplementation did not increase short-term infection risk among HD patients.

Protective Effect of Astragaloside IV on Hepatic Injury Induced by Iron Overload.

Suitable content of iron is essential for human body, but iron overload is associated with many kinds of diseases including chronic liver damage. Recently, researchers find that iron overload promotes hepatocyte autophagy and apoptosis. However, the mechanism of iron overload in liver damage remains unclear. In this study, Lo2 cells were selected as the research object, iron dextran was a model drug, and astragaloside IV was a therapeutic drug to explore the role of iron overload. MTT assay and Annexin/PI double staining were used to measure cell viability and apoptosis. Ultrastructure was observed by transmission electron microscopy. The expression levels of apoptosis and autophagy-related proteins were determined by real-time PCR and Western Blot. The results showed that iron dextran could significantly inhibit Lo2 cell viability and increase the apoptosis rate, while astragaloside IV could reverse the inhibition of Lo2 cell viability and decrease the apoptosis rate. Transmission electron microscopy showed a significant increase in the number of autophagosomes after administration of iron dextran, and the application of astragaloside IV reduced the production of autophagosomes. LC3II/I was significantly upregulated in the model group but decreased in the astragaloside IV treatment group, and P62 showed the opposite trend. Iron dextran significantly upregulated the expression of Bax and downregulated Bcl2, while astragaloside IV reversed this trend. Finally, the inhibition of hepcidin caused by iron dextran was counteracted by astragaloside IV. In conclusion, the experimental results show that the iron overload model mainly induces excessive autophagy and apoptosis of hepatocytes, thus causing damage to hepatocytes, but astragaloside IV plays a certain therapeutic role in reversing this damage.

Protocol and baseline data for a prospective open-label explorative randomized single-center comparative study to determine the effects of various intravenous iron preparations on markers of oxidative stress and kidney injury in chronic kidney disease (IRON-CKD).

BACKGROUND: Intravenous (IV) iron is frequently used to treat iron deficiency/anemia in patients who are unable to tolerate oral iron or the oral iron is not sufficient toreplete iron requirements. However, safety concerns regarding the potential increase in oxidative stress and other adverse effects persist and it remains unclear whether all iron preparations are equivalent. Indeed, the comparative risk of adverse events with IV iron preparations has not been extensively assessed. We hypothesize that IV iron leads to changes in oxidative stress, endothelial function, and potential renal damage depending on the iron formulation (related to the generation of "free" or catalytic labile iron) and this may result in more tubular and glomerular injury manifested as increased proteinuria and raised neutrophil gelatinase-associated lipocalin (NGAL) levels in patients with chronic kidney disease (CKD). METHODS: IRON-CKD is a prospective, open-label, explorative, randomized, single-center study designed to compare the safety and efficacy of three parenteral iron preparations: low-molecular-weight iron dextran-Cosmofer, iron sucrose-Venofer, and iron isomaltoside-Monofer. The study includes 40 adults who have established CKD stages 3-5 and serum ferritin (SF) of less than 200 µg/L or transferrin saturation (TS) of less than 20% (or both); they were randomly assigned in a 1:1:1:1 ratio to 200 mg iron dextran, 200 mg iron sucrose, 200 mg iron isomaltoside, or 1000 mg iron isomaltoside. After randomization, participants undergo baseline assessments and then an iron infusion. Each participant is followed up at 2 h, day 1, week 1, and months 1 and 3. At each follow-up visit, patients undergo clinical review, measurement of pulse wave velocity (PWV), blood tests for renal function, and collection of serum/plasma samples for oxidative stress and inflammatory markers. The primary outcomes are measures of oxidative stress, inflammatory markers, and markers of acute renal injury in comparison with baseline measures of each iron preparation and between each of the iron preparations. Secondary objectives include effects on hematinic profiles and hemoglobin concentrations, changes in arterial stiffness, incidence of significant side effects, and change in patients' quality of life. RESULTS: Between October 2015 and April 2018, 521 individuals were identified as potential participants; 216 were contacted, 56 expressed an interest, 49 attended a screening visit, and 40 were confirmed to meet the eligibility criteria and were randomly assigned. The mean age was 58.8 (standard error of the mean 2.2) years, and 23 (58%) were male. All patients were white and English-speaking. The mean SF was 68.8 µg/L, TS was 21.4%, and haemoglobin was 122.6 g/L at randomization for the whole group. The mean estimated glomerular filtration rate was 28.2 mL/min/1.73 m2 the urinary protein/ creatinine ratio was 154.2 mg/mmol, and CRP was 7.5 mg/L. DISCUSSION: IRON-CKD will provide important information on the short-term effects of three preparations of IV iron in CKD patients with biochemical functional or absolute iron deficiency on measures of oxidative stress, inflammation, endothelial function, and renal injury. TRIAL REGISTRATION: European Clinical Trials Database (EudraCT) number 2010-020452-64 .

Safety of Intravenous Iron - Cosmofer and Monofer Therapy in Peritoneal Dialysis and Non-Dialysis-Dependent Chronic Kidney Disease Patients.

Safety of parenteral iron therapy is critical and has been demonstrated in several studies, but concerns persist on safety. We performed a retrospective single-center study investigating the safety and efficacy of parenteral iron administration using 2 iron preparations-Monofer and Cosmofer (Pharmacosmos A/S, Holbaek, Denmark)-in patients with chronic kidney disease (CKD), on peritoneal dialysis (PD) and non-dialysis. A database of CKD patients receiving intravenous (IV) iron was analyzed. Side effects were recorded during infusion, post-infusion, and after 48 hours. In a population of CKD patients (non-dialysis and PD), IV iron is safe with few major adverse effects for these 2 IV iron preparations studied with similar dosing schedules. These data provide reassurance on the relative short-term safety of IV iron preparations regarding acute infusion-related hypersensitivity reactions.

Lactoferrin plus health education versus total dose infusion (TDI) of low-molecular weight (LMW) iron dextran for treating iron deficiency anemia (IDA) in pregnancy: a randomized controlled trial.

BACKGROUND: Iron deficiency anemia (IDA) is one of the most common medical disorder disturbing pregnancies particularly in low resources countries, and contributes significantly to morbidities and mortalities. Thus, early diagnosis and prompt management of IDA is highly recommended. AIM: To Test the efficacy and safety of oral lactoferrin plus health education provided by a nurse versus total dose infusion (TDI) of low-molecular weight (LMW) iron dextran for treating IDA in the second and third trimester of pregnancy. DESIGN: A prospective interventional, randomized, parallel-group, single-center longitudinal study. SETTING: Woman's Health Assiut University Hospital, Assiut, Egypt, at the outpatient clinic and inpatient unit. It comprised 120 cases divided into two groups as pineapple flavored lactoferrin oral sachets 100 mg twice daily with health education (group A) and TDI of LMW iron dextran (group B). MAIN OUTCOME MEASURES: The primary efficacy parameter was clinical improvement and the amount of increase in hemoglobin concentration by 4 weeks after therapy, secondary outcome measures included measurement of the rest of RBC, and iron indices, the adverse effects related to iron therapy and the patient compliance to the treatment. RESULTS: There was insignificant difference between both groups regarding sociodemographic data, parity and mean gestational age. Both groups showed a significant clinical improvement of anemia 4 weeks post-therapy. There was no statistically significant difference in mean Hb level improvement in both groups after 1 month of therapy. However, mean corpuscular volume (MCV) and mean corpuscular hemoglobin (MCH) improved significantly more in group B than A while iron indices (serum iron and serum ferritin) were significantly more in group A than group B. CONCLUSIONS: Pineapple flavored lactoferrin oral sachets plus health education can be widely used as an alternative to TDI iron dextran supplementation due to clinical as well as laboratory improvement of IDA during pregnancy after 1 month of treatment. Proper health education of the pregnant women with nurse recommendations of balanced diet containing good sources of iron would increase awareness of pregnant women and help eradicate IDA with its serious sequel during pregnancy.

Transient power elevation during iron dextran infusion in a patient with a continuous-flow left ventricular assist device.

Anemia is common in patients with mechanical circulatory support and is associated with increased morbidity. Repletion using parenteral iron infusions has been proven to be beneficial in patients with heart failure. In this report, we describe a case of increased power and flows of continuous-flow left ventricular assist device (LVAD) during an iron dextran infusion. We subsequently studied the effects of iron dextran infusion in an in vitro LVAD mock circulatory loop. The observed increase in flow and power was most likely due to drug-patient interaction rather than drug-LVAD interaction. Mock loops and in vivo animal models may be necessary for proactive evaluation of the safety of intravenous (IV) preparations in this patient population.

Bone abnormalities in young male rats with iron intervention and possible mechanisms.

Studies suggest iron overload may cause bone lesion. The mechanisms are not well understood at present. Therefore, this study was designed to observe the effect of iron overload on bone metabolism in young male rats and explore its possible mechanism. Eighteen SD rats were randomly assigned to iron-loading and control groups. Fe-dextran (250 mg/kg of body weight) was injected intraperitoneally into the rats from iron-loading group, every other day for 5 weeks. The bone mineral density (BMD) of femur, length and diameter of tibia, and histological microstructure of femur and vertebra was determined. The concentrations of serum superoxide dismutase (SOD) and malondialdehyde (MDA) were assayed by ELISA. The mRNA expression of cytokines was detected by real-time PCR. The results showed an obvious bone abnormality after iron intervention, such as significantly decreased content of Ca in bone tissue, shorter length of tibia, lower BMD of femur, and obvious lesion of bone microarchitecture. At the same time, with iron intervention, the concentrations of serum SOD decreased but MDA increased; the mRNA expression of osteocalcin and osteoprotegerin (OPG) decreased, whereas that of receptor activator of nuclear factor kappa B ligand (RANKL) and IL-6 increased significantly. In summary, iron overload indeed give rise to the abnormal changes of bone metabolism independently. Increased bone resorption, and probably decreased bone formation are involved in the process of bone lesion caused by iron overload. Oxidative stress and RANKL participate in the pathological process, and IL-6 may play a supporting role.

Evaluation of the safety of iron dextran with parenteral nutrition in the paediatric inpatient setting.

AIM: Practitioners often avoid administering iron dextran in parenteral nutrition (PN) for hospitalised children because of the concern for anaphylaxis. The primary aim of the present study was to determine the risk of anaphylaxis associated with exposure to PN containing iron dextran in the inpatient setting. METHODS: Charts were reviewed for all children admitted to The Children's Hospital of Philadelphia from January 1, 2011 to December 30, 2013 who received PN containing low molecular weight (LMW) iron dextran. Subject characteristics, primary diagnoses and PN orders were evaluated. The pharmacy adverse events database was queried for adverse drug reactions. RESULTS: Over three years, 89 subjects received PN containing a maintenance dose of LMW iron dextran with a total of 2774 days of exposure. Subjects ranged from two months to 21 years of age and received between 1 and 196 days of PN containing iron dextran. The mean dose of iron dextran in children decreased as the weight category increased from <5 kg (0.21 ± 0.05 mg/kg/day) to ≥40 kg (1.9 ± 0.5 mg/day; P-value for trend <0.005). No anaphylactic reactions occurred in any subjects. CONCLUSIONS: PN containing a maintenance dose of LMW iron dextran can be safely administered to hospitalised children, and further studies are need to evaluate the potential to prevent iron deficiency anaemia and the need for additional IV iron infusions.