Results of the First American Prospective Study of Intravenous Iron in Oral Iron-Intolerant Iron-Deficient Gravidas

Hematologic Complications of Pregnancy

Hematologic complications are common in pregnancy and can significantly impact both maternal and fetal health. Recognizing and treating these complications can be challenging due to the limited evidence available to guide clinical consultants. Iron deficiency anemia is the most prevalent hematologic issue in pregnancy and often occurs due to increased maternal blood volume and the nutritional demands of the growing fetus. Thrombocytopenia is the second most commonly occurring hematologic issue in pregnancy and can be associated with increased blood loss and complications during childbirth. However, the most common type of thrombocytopenia in pregnancy is gestational thrombocytopenia, which does not typically require clinical management. Thus, it is important to distinguish gestational thrombocytopenia from other etiologies of thrombocytopenia in pregnancy that require immediate treatment, including immune thrombocytopenia, thrombotic thrombocytopenic purpura, preeclampsia, and HELLP (hemolysis, elevated liver enzyme levels, and low platelet levels) syndrome. Other important hematologic conditions in pregnancy include non-inherited anemias, such as autoimmune hemolytic anemia and aplastic anemia, as well as inherited anemias, such as sickle cell disease and thalassemia, which may require specialized management to optimize maternal and fetal outcomes. Additionally, bleeding disorders, such as von Willebrand disease and hemophilia, pose unique challenges in pregnancy, especially around the time of delivery, due to the risk of excessive bleeding. Lastly, thromboembolic disorders, such as venous thromboembolism (VTE), remain the leading cause of mortality in pregnancy in developed countries. Pregnancy-related hormonal changes, venous stasis, and hypercoagulability contribute to an increased thromboembolic risk, further exacerbated by additional risk factors such as obesity or a prior personal or family history of VTE. This review aims to summarize current guidelines and management of the most common hematologic disorders in pregnancy.

Surgical Management of Pregnant Patients with Inflammatory Bowel Disease

Pelvic surgery for inflammatory bowel disease (IBD) can reduce fertility. Pregnant women with IBD have higher rates of pregnancy loss and adverse outcomes. Awareness of these factors and adequate multidisciplinary monitoring throughout these high-risk pregnancies is important. Surgeons may need to manage stoma complications, assist in cesarean delivery, or even operate for severe flares or obstruction during pregnancy. In experienced hands and with adequate support from maternal fetal medicine, surgery can be safely performed in any trimester. Overall, the greatest risk to the mother and fetus remains active disease, not the medical and surgical therapies used to treat it.

Expert consensus guidelines: Intravenous iron uses, formulations, administration, and management of reactions

Intravenous iron has become an essential component for the treatment of iron deficiency and iron deficiency anemia. Individuals administering Intravenous iron should have knowledge in intravenous iron administration, including a pre-infusion assessment to evaluate infusion reaction risks, pre- and post-infusion monitoring, identification of and management of infusion reactions, accurate documentation of these reactions, laboratory monitoring and recognition and management of treatment-emergent hypophosphatemia. This comprehensive consensus provides step-by-step guidance and tools for practitioners to promote safe delivery of intravenous iron, recognition, and management of infusion reactions and treatment-emergent hypophosphatemia.

Management of iron deficiency in women of childbearing age with oral iron intolerance: a prospective, randomised, controlled trial of three doses of an iron-whey-protein formulation : Prospective RandomisEd study of women of Childbearing age with gastroInteStinal Intolerance to Oral iroN (PRECISION)

BACKGROUND

Nutritional deficit and oral iron gastrointestinal intolerance may be a common cause of iron deficiency, which can be managed by pharmacists.

AIM

To understand the prevalence of iron deficiency in women of childbearing age with a self-reported history of intolerance to oral iron and the tolerability of three doses of an iron-whey-protein formulation in the care of these women.

METHOD

Ferritin and haemoglobin levels were documented in women of childbearing age with oral iron gastrointestinal intolerance. In those with iron deficiency (ferritin < 30 µg/L), adherence, gastrointestinal tolerability, ferritin, transferrin saturation and haemoglobin levels were compared between their prior oral iron product and iron-whey-protein microspheres randomised to three doses (14 mg daily, 25 mg daily and 50 mg daily) for 12 weeks.

RESULTS

Most screened women had low iron stores (128 (62.7%); ferritin < 30 µg/L), 65 (31.9%) had moderate to severe iron deficiency (ferritin < 12 µg/L) and 33 (16.2%) had iron deficiency anaemia (ferritin < 30 µg/L, haemoglobin < 12 g/dL). Amongst the 59 women who participated in the prospective clinical study of iron-whey-protein microspheres over 12 weeks, 48 (81.4%) were classified as adherent/persistent and fewer instances of gastrointestinal intolerance were reported (0.59 ± 0.91) when compared to 12 (20.3%) and (4.0 ± 2.2) respectively while taking the prior oral iron (Fisher's Exact and T-test respectively, both p < 0.001). There was no difference in adherence or tolerability of different iron-whey-protein formulation doses. Ferritin, haemoglobin and energy levels increased significantly over 12 weeks.

CONCLUSION

Undiagnosed iron deficiency is common in women of childbearing age with a history of intolerance to oral iron and iron-whey-protein microspheres can improve adherence, GI tolerability, iron stores, haemoglobin and energy levels in these women.

CLINICAL TRIAL REGISTRATION

Clinicaltrials.gov identifier (registration includes full trial protocol): NCT04778072.

IV iron formulations and use in adults

Intravenous iron has become a major component of the therapeutic armamentarium for iron deficiency and iron deficiency anemia. The earliest formulations were associated with unacceptable toxicity. Newer formulations, with complex carbohydrate cores that bind elemental iron more tightly, allow the administration of full therapeutic doses in 15 to 60 minutes. Nonetheless, a folklore of danger, fueled by earlier formulations no longer available, continues to foment caution. Complement-mediated minor infusion reactions, referred to as complement activation-related pseudo-allergy, resolve without therapy. Inappropriate intervention with vasopressors and H1 blockers converts these minor reactions into hemodynamically significant adverse events. Four new formulations, low-molecular-weight iron dextran, ferumoxytol, ferric carboxymaltose, and ferric derisomaltose, all approved for the treatment of iron deficiency in a host of conditions, are now widely used with an excellent safety profile. Herein, the administration, safety, indications, and management of infusion reactions are discussed. Treatment-emergent hypophosphatemia, a newly recognized side effect for some formulations, is also reviewed. Based on the preponderance of published evidence, intravenous iron should be moved up-front for the treatment of iron deficiency and iron deficiency anemia in those conditions in which oral iron is suboptimal.

Neonatal outcomes from a randomized controlled trial of maternal treatment of iron deficiency anemia with intravenous ferumoxytol vs oral ferrous sulfate

BACKGROUND

Anemia in pregnancy is common worldwide and has known maternal risks. The relationship between the types of treatment offered for maternal anemia and the effects on the fetus and newborn are largely uninvestigated.

OBJECTIVE

This study aimed to investigate whether maternal treatment with intravenous ferumoxytol compared to oral ferrous sulfate results in an increase in neonatal hematologic and iron indices. These analyses were planned secondary outcomes and post hoc analysis from the trial with a primary outcome of change in maternal hemoglobin.

STUDY DESIGN

A randomized controlled trial including 124 participants with anemia by World Health Organization criteria was performed in which participants were allocated in a 1:1 ratio to either 2 infusions of 510 mg of intravenous ferumoxytol or 325 mg oral ferrous sulfate twice daily. Fetal monitoring was performed during each intravenous iron infusion. Standard univariable statistical techniques were used to compare groups and to investigate associations between maternal and neonatal hemoglobin and iron indices.

RESULTS

Cord blood hematological parameters were equivalent between groups. Hemoglobin was 15.7 g/dL vs 15.4 g/dL (P=.6) and hematocrit was 50.5% and 49.2% (P=.4) in those randomized to intravenous ferumoxytol and oral ferrous sulfate, respectively. Iron studies revealed higher cord blood ferritin concentrations in infants of participants treated with intravenous ferumoxytol (294 vs 186, P=.005). There were equivalent iron (158 vs 146, P=.4), transferrin (186 vs 196, P=.4) and total iron binding capacity (246 vs 244, P=1) in neonates of participants receiving intravenous vs oral treatment. There were no effects of the infusions observed on cardiotocography. Gestational age at birth was equivalent between groups. We noted a larger birthweight in neonates of participants treated with intravenous ferumoxytol (3215 g vs 3033 g, P=.09), which was not statistically significant. Post hoc analyses revealed a statistically significant correlation between neonatal ferritin and maternal hemoglobin (P=.006) and neonatal ferritin and maternal ferritin (P=.017) at admission for delivery.

CONCLUSION

Neonates of participants who received intravenous ferumoxytol were born with higher ferritin concentrations in cord blood, at the same gestation with the same birthweight. Participants with higher hemoglobin and ferritin indices delivered infants with higher ferritin concentrations in cord blood.

Inflammatory bowel disease in pregnancy and breastfeeding

Inflammatory bowel disease (IBD) has a peak age of diagnosis before the age of 35 years. Concerns about infertility, adverse pregnancy outcomes, and heritability of IBD have influenced decision-making for patients of childbearing age and their care providers. The interplay between the complex physiology in pregnancy and IBD can affect placental development, microbiome composition and responses to therapy. Current evidence has shown that effective disease management, including pre-conception counselling, multidisciplinary care and therapeutic agents to minimize disease activity, can improve pregnancy outcomes. This Review outlines the management of IBD in pregnancy and the safety of IBD therapies, including novel agents, with regard to both maternal and fetal health. The vast majority of IBD therapies can be used with low risk during pregnancy and lactation without substantial effects on neonatal outcomes.

The incidence, complications, and treatment of iron deficiency in pregnancy

Iron deficiency and/or iron deficiency anemia (IDA) complicate nearly 50% of pregnancies globally, negatively impacting both maternal and fetal outcomes. Iron deficiency can cause a range of symptoms that range from aggravating to debilitating including fatigue, poor quality of life, pagophagia, and restless leg syndrome. Iron deficiency and IDA are also associated with maternal complications including preterm labor, increased rates of cesarean delivery, postpartum hemorrhage, and maternal death. Fetal complications include increased rates of low birth weight and small for gestational age newborns. Prenatal maternal anemia has also been associated with autism spectrum disorders in the neonate, although causation is not established. Deficiency in the newborn is associated with compromised memory, processing, and bonding, with some of these deficits persisting into adulthood. Despite the prevalence and consequences associated with iron deficiency in pregnancy, data show that it is routinely undertreated. Due to the physiologic changes of pregnancy, all pregnant individuals should receive oral iron supplementation. However, the bioavailability of oral iron is poor and it is often ineffective at preventing and treating iron deficiency. Likewise, it frequently causes gastrointestinal symptoms that can worsen the quality of life in pregnancy. Intravenous iron formulations administered in a single or multiple dose series are now available. There is increasing data suggesting that newer intravenous formulations are safe and effective in the second and third trimesters and should be strongly considered in pregnant individuals without optimal response to oral iron repletion.

Advances in understanding the crosstalk between mother and fetus on iron utilization

A full-term pregnancy comes with significant demand for iron. Not meeting this demand has adverse effects on maternal health and on the intrauterine and postnatal development of the infant. In the infant, some of these adverse effects cannot be reversed by postnatal iron supplementation, highlighting the need to tackle iron deficiency in utero. Achieving this requires sound understanding of the pathways that govern iron transfer at the fetomaternal interface. Two pathways are emerging as key players in this context; the hepcidin/ferroportin axis pathway and the iron regulatory protein (IRPs) pathway. In late gestation, suppression of maternal hepcidin, by as yet unknown factors, is required for increasing iron availability to the growing fetus. In the placenta, the rate of iron uptake by transferrin receptor TfR1 at the apical/maternal side and of iron release by ferroportin FPN at the basal/fetal side is controlled by IRP1. In fetal hepatocytes, build up of fetal iron stores requires post-translational inhibition of FPN by the cell-autonomous action of hepcidin. In the fetal liver, FPN is also subject to additional control at the transcriptional level, possibly by the action of hypoxia-inducible factor HIF2α. The rates of apical iron uptake and basal iron release in the placenta are modulated according to iron availability in the maternal blood and the placenta's own needs. This placental modulation ensures that the amount of iron delivered to the fetal circulation is maintained within a normal range, even in the face of mild maternal iron deficiency or overload. However, when maternal iron deficiency or overload are extreme, placental modulation is not sufficient to maintain normal iron supply to the fetus, resulting in fetal iron deficiency and overload respectively. Thus, the rate of iron transfer at the fetomaternal interface is subject to several regulatory signals operating simultaneously in the maternal liver, the placenta and the fetal liver. These regulatory signals act in concert to maintain normal iron supply to the fetus within a wide range of maternal iron states, but fail to do so when maternal iron deficiency or overload are extreme. The limitations of existing experimental models must be overcome if we are to gain better understanding of the role of these regulatory signals in normal and complicated pregnancy. Ultimately, that understanding could help identify better markers of fetal iron demand and underpin novel iron replacement strategies to treat maternal and fetal iron deficiency.

Anaemia in chronic kidney disease pregnancy

AIM

To review the incidence and management of anaemia and outcomes in pregnancies in a cohort of Australian women with chronic kidney disease.

METHODS

A retrospective audit of 63 pregnancies in 52 women with chronic kidney disease.

RESULTS

Sixty-eight percent of chronic kidney disease pregnancies were complicated by haemoglobin less than 100 g/L. Iron stores were measured in only 62% of all pregnancies. Serum ferritin was less than 100 ng/ml in 95% of those tested. Erythropoietin-stimulating agents were used in 24 pregnancies (38%). Intravenous iron was used in only nine non-dialysis pregnancies.

CONCLUSION

Greater awareness of the importance of regular measurement of iron stores and appropriate levels for repletion in chronic kidney disease pregnancies amongst health professionals involved in obstetric care may result in earlier detection and treatment of iron deficiency, and potentially improve maternal and fetal outcomes.

Using Reticulocyte Hemoglobin Equivalent as a Marker for Iron Deficiency and Responsiveness to Iron Therapy

OBJECTIVE

To assess the accuracy of a simplified approach for the diagnosis of iron deficiency anemia (IDA) based on the complete blood cell count (CBC) and reticulocyte analysis.

PATIENTS AND METHODS

Five hundred fifty-six consecutive, nonselected patients referred for diagnosis and/or treatment of anemia were included in this diagnostic study to compare the performance of reticulocyte hemoglobin equivalent (RET-He) versus traditional biochemical markers for diagnosis and treatment of IDA. Complete blood count, serum ferritin, iron, and transferrin saturation were performed as clinically indicated. Reticulocyte hemoglobin equivalent was measured with a Sysmex XN-450 analyzer on the residual CBC sample. The study period was from September 20, 2017, through and including November 15, 2018.

RESULTS

Patients (N=556) were studied at baseline, of whom 150 were subsequently treated with intravenous iron. Receiver operating characteristic analysis yielded an RET-He cut-off of 30.7 pg to identify IDA (area under curve, 0.733; 95% CI, 0.692 to 0.775), with 68.2% sensitivity and 69.7% specificity. Patients (n=240) were seen at follow-up, with 57 treated and 183 not treated with intravenous iron. Responsiveness was defined as a hemoglobin increase of ≥1.0 g: a combination of RET-He <28.5 pg and hemoglobin value <10.3 g/dL had 84% sensitivity and 78% specificity as response predictor (area under the curve, 0.749; 95% CI, 0.622 to 0.875).

CONCLUSION

Data from CBC and RET-He can identify patients with IDA, determine need for and responsiveness to intravenous iron, and reduce time for therapeutic decisions. Limitations of this study are uncontrolled design, its single-site and retrospective nature, and that it requires prospective validation.

Ferumoxytol for the treatment of iron deficiency and iron-deficiency anemia of pregnancy

Introduction:

A litany of recent evidence supports the morbidity of intra-natal iron-deficiency anemia and its prodrome, iron deficiency. Oral iron administered during second and third trimesters does not get to the developing fetus if the mother is iron deficient. This is especially concerning as the rapidly developing fetal brain is in particular need of iron sufficiency. Intra-natal iron deficiency is associated with autism, schizophrenia and abnormal brain structure. The obstetrical literature reports an unacceptably high incidence of gastrointestinal adverse events with oral iron. The time iron honored standard in the United States for intravenous iron replenishment in gravidas is iron sucrose. While safe and effective, four to seven visits are required to accomplish what newer formulations can achieve with one.

Methods:

Ferumoxytol is a superparamagnetic iron oxide linked to polyglucose sorbitol carboxymethylether-binding elemental iron tightly allowing administration of complete replacement doses in 15–30 min. Herein, we report the results of 131 consecutive, non-selected, iron-deficient second- and third-trimester pregnant women who received either 510 mg of intravenous (IV) ferumoxytol twice or 1020 mg once.

Results:

Hemoglobin and iron parameter increments were highly statistically significant. No adverse events were reported. We report how a single infusion is safe and effective as the same dose over two visits, saving an unnecessary visit and IV placement, while reducing cost.

Conclusion:

Ferumoxytol represents an efficacious and safe method of administration of IV iron which improves convenience for patients and practitioners, and is cost saving due to fewer visits.

Plain language summary

One or two infusions of intravenous iron for iron deficiency or iron-deficiency anemia of pregnancy simplifies care

This study was conducted to highlight the inconvenience of multiple doses of IV iron and how administering the same dose in one or two infusions simplifies care. We report how a single infusion is as safe and effective as the same dose over two visits, saving an unnecessary visit and IV placement, while reducing cost. This study supports a growing body of evidence, to date, unreported, with ferumoxytol in pregnancy, reporting improved convenience and decreased costs with higher doses of IV iron in one or two visits.

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.

Intravenous iron: a framework for changing the management of iron deficiency

For decades intravenous iron was considered dangerous. Newer formulations with carbohydrate cores binding elemental iron more tightly allow complete iron replacement within 15-60 min in one visit. Meta-analyses and prospective comparisons of different formulations support equivalent safety to placebo with less toxicity than oral iron. Of the available formulations, the preponderance of published evidence supports equal safety and efficacy. In this Viewpoint, we report evidence supporting repositioning of intravenous iron to the frontline in multiple disorders with iron deficiency, which include heart failure, chronic kidney disease, inflammatory bowel disease, patient blood management in the perioperative period, and obstetrics and gynaecology. We have also highlighted neonatal evidence supporting the inadequacy of oral iron in late pregnancy, a critical period of iron need for normal foetal brain development. Physicians should consider prioritising the use of intravenous iron rather than oral iron as a treatment for iron deficiency in some of these clinical scenarios.

Prevalence of iron deficiency in first trimester, nonanemic pregnant women

Despite a high frequency of iron deficiency in pregnancy, the United States Preventative Services Task Force (USPSTF) stated: "there is inconclusive evidence routine supplementation for iron deficiency anemia improves maternal or infant clinical health outcomes." In contradistinction, high-quality epidemiologic studies report long lasting deficits in infants diagnosed with iron deficiency in the first 6 months of life compared with infants who were not, with specific deficits in cognition, memory, executive function and electrophysiology documented up to 19 years of age. Infants are not routinely screened for iron deficiency. United Kingdom guidelines differ and recommend screening high-risk infants who are preterm, of diabetic, underweight, obese, or vegetarian mothers, those born to anemic or iron deficient mothers, of smokers, those with inflammatory bowel disease or abnormal uterine bleeding, and from pregnancies in which the intergravid period is <6 months. Iron parameters are not routinely drawn unless anemia is present and in some cases only if microcytic. In that iron deficiency precedes the development of anemia, and waiting for its development misses a large number of overtly iron deficient gravidas. Iron parameters were measured in 102 consecutive, nonselected, nonanemic, first trimester women presenting to their obstetricians. Using standard cutoffs of percent transferrin saturation and/or serum ferritin, 42% were observed to be iron deficient. Given the lack of harm of testing for iron deficiency, it appears prudent to err on the side of caution and screen all presenting pregnant mothers until properly powered outcome data become available. The current recommendations of the USPSTF may need to be revisited.

Perinatal Iron Deficiency: Implications for Mothers and Infants

Iron deficiency, with or without anemia, is common in pregnant women. In fact, nearly 30% of reproductive-age women are anemic worldwide, and anemia in pregnancy has an estimated global prevalence of 38%. Severe anemia can substantially increase the risk of maternal mortality, and can adversely affect fetal development. In this review, we examine the available data regarding epidemiology and consequences of iron deficiency in mothers and infants, current treatment strategies, and make recommendations for screening and treatment of iron deficiency anemia in gravidas and neonates.

Commentary: Iron deficiency of pregnancy - a new approach involving intravenous iron

Iron deficiency anemia of pregnancy is common, especially in South Asia, and is associated with adverse maternal and fetal outcomes including increased incidences of maternal mortality, preterm labor and low birth weight. Screening for anemia alone is not sufficient to diagnose iron deficiency. Iron deficiency in neonates is associated with a statistically significant increment in cognitive and behavioral abnormalities which persist after iron repletion. Oral iron is the frontline standard but is associated with an unacceptably high incidence of gastrointestinal adverse events leading to poor adherence. Prospective evidence reports an incidence of neonatal iron deficiency up to 45% even with oral iron supplementation. New evidence reports oral iron ingestion increases serum hepcidin leading to decreased absorption suggesting further decreasing efficacy. Published evidence reports that intravenous iron is safe and effective in the second and third trimesters of pregnancy. Intravenous iron is the preferred route when there is oral iron intolerance or in those situations where oral iron is ineffective or harmful. Intravenous iron is also preferred if the anemia is severe (< 8 g/dL) in the second trimester or at any time in the third trimester when there is little expectation that adequate quantities of iron will be delivered to the fetus as iron requirements increase in each trimester. Guidelines for maternal and neonatal screening and treatment lack consistency and differ between the United States and Europe. New formulations of intravenous iron with complex carbohydrate cores that bind elemental iron more tightly mitigating the release of large quantities of labile free iron allow the administration of complete replacement doses in 15-60 min. The preponderance of published evidence suggests that intravenous iron is underutilized in pregnancy and guidelines suggesting there is insufficient evidence to recommend the routine screening and treatment of iron deficiency in gravidas should be revisited. The major recommendation from this commentary is that in low-income countries, a trial or demonstration project to test the efficacy, safety, cost and feasibility of the administration of intravenous iron to anemic and/or iron-deficient women be undertaken.

A Prospective Randomised Controlled Trial of a Single Intravenous Infusion of Ferric Carboxymaltose vs Single Intravenous Iron Polymaltose or Daily Oral Ferrous Sulphate in the Treatment of Iron Deficiency Anaemia in Pregnancy

Iron deficiency anaemia (IDA) is the most common nutritional deficiency affecting pregnant women worldwide. This study aims to compare the efficacy and safety of a newly available intravenous (IV) iron preparation, ferric carboxymaltose (FCM), against IV iron polymaltose (IPM), and standard oral iron (ferrous sulphate) for the treatment of IDA in pregnancy. This is an open-labelled prospective randomised controlled trial (RCT) with intention-to-treat analysis conducted at a primary health care facility with a single tertiary referral centre in Launceston. Tasmania, Australia. A 3-arm randomised controlled trial was conducted comparing a single IV infusion of 1000mg of FCM (n = 83 patients) over 15 minutes against a single IV infusion of 1000mg of IPM (n = 82) over 2 hours against 325mg daily oral ferrous sulphate (n = 81) until delivery, for the treatment of IDA in pregnancy. A total of 246 consecutive pregnant women were recruited between September 2013 and July 2014. The median age was 28 years, with a median and mean gestation of 27 weeks. The median serum ferritin was 9µg/L, with a mean of 13µg/L. The mean haemoglobin (Hb) was 114g/L. The primary outcome was the change in ferritin and Hb levels at 4 weeks after intervention. Secondary outcomes included ferritin and Hb improvements at predelivery, safety, tolerability, quality of life (QoL), cost utility, and fetal outcomes. The mean Hb level differences between the baseline intervention time point and 4 weeks thereafter were significantly higher in the FCM versus the oral group by 4.35g/L (95% CI: 1.64-7.05; P = 0.0006) and in the IPM vs the oral group by 4.08g/L (95% CI: 1.57-6.60; P = 0.0005), but not different between the FCM and IPM groups (0.26g/L; 95% CI: -2.59 to 3.11; P = 0.9740). The mean ferritin level differences were significantly higher at 4 weeks in the FCM vs oral iron group by 166µg/L (95% CI: 138-194; P < 0.0001) and in the IPM vs oral iron group by 145µg/L (95% CI: 109-1180, P < 0.0001), but not between the 2 IV groups (21.5µg/L; 95% CI: -23.9 to 66.9; P = 0.4989). Administration of IV FCM during pregnancy was safe and better tolerated than IV IPM or oral iron. Compliance to oral iron was the lowest amongst treatment groups with one-third of the patients missing doses of daily iron tablets. Significant improvement in overall QoL scores was observed in both IV iron supplement groups by achieving normal ferritin following effective and prompt repletion of iron stores, compared to the oral iron group (P = 0.04, 95% CI: 21.3, 1.8). The overall cost utility of IV FCM and IV IPM appear to be similar to oral iron. There were no differences in the fetal outcomes between the 3 trial arms. In conclusion, this study demonstrates that a single IV iron infusion is an effective and safe option for treatment of IDA during pregnancy. FCM was more convenient than other treatments. Rapid parenteral iron repletion can improve iron stores, Hb levels and QoL in pregnant women, with ongoing benefits until delivery. Integration of IV iron for IDA in pregnancy can potentially improve pregnancy outcomes for the mother. Update of guidelines to integrate the use of new IV iron preparations in pregnancy is warranted.