Double blind, placebo controlled, multicenter randomized trial in pregnant women in the U.S. (N=300) to test the central hypothesis that IV iron in pregnant women with IDA (Hb\<11 g/dL and ferritin\<30 ng/mL) at 13 - 30 weeks will be effective, safe and cost-effective in reducing severe maternal morbidity-as measured by maternal anemia at delivery-and will also improve offspring neurodevelopment.
Iron-deficiency anemia (IDA) is a common, undertreated problem in pregnancy. According to data from the U.S. National Health and Nutrition Examination Survey (NHANES), 25% of pregnant women in the U.S. have iron deficiency, with rates of 7%, 24%, and 39% in the first, second, and third trimesters, respectively. The prevalence of IDA is estimated at 16.2% overall and up to 30% at delivery. Iron deficiency is associated with significant adverse maternal and fetal outcomes including blood transfusion, cesarean delivery, depression, preterm birth, and low birth weight. Moreover, iron-deficient mothers are at risk of delivering iron-deficient neonates who, despite iron repletion, remain at risk for delayed growth and development. While treatment with iron supplementation is recommended during pregnancy, questions remain about the optimal route of delivery. Oral iron therapy, the current standard, is often suboptimal: up to 70% of patients experience significant gastrointestinal side effects (nausea, constipation, diarrhea, indigestion, and metallic taste) that prevent adherence to treatment, resulting in persistent anemia. Intravenous (IV) iron is an attractive alternative because it mitigates the adherence and absorption challenges of oral iron. However, IV iron costs more, and there are historical concerns about adverse reactions. The American College of Obstetricians and Gynecologists (ACOG) recommends oral iron for the treatment of IDA in pregnancy, with IV iron reserved for the restricted group of patients. Our preliminary data show that this approach leads to 30% of patients with persistent IDA at delivery and an associated 3 to 6-fold increased risk of peripartum blood transfusion. ACOG's preferential recommendation of oral iron is based on paucity of data on the benefits and safety of IV iron, compared with oral iron, in pregnancy. Our published systematic review and meta-analysis showed that IV iron is associated with greater increase in maternal hemoglobin (Hb), but most of the primary trials were conducted in developing countries, included small sample sizes (50 - 252), and did not assess meaningful maternal and neonatal outcomes. The current Cochrane review noted that despite the high incidence and disease burden associated with IDA in pregnancy, there is paucity of quality trials assessing clinical maternal and neonatal effects of iron administration in women with anemia. The authors called for "large, good quality trials assessing clinical outcomes." The only large randomized trial of IV versus oral iron, conducted in India, showed no difference in a maternal composite outcome, but it is limited by use of iron sucrose which required five infusions, resulting in a wide range of iron doses (200 - 1600 mg). In addition, the primary composite outcome included some components not directly related to anemia. In contrast, our pilot trial of a single infusion of 1000 mg of IV low molecular weight iron dextran in pregnant women in the U.S. with moderate-to-severe IDA significantly reduced the rate of maternal anemia at delivery and showed promise for improving maternal morbidity by reducing rates of blood transfusion. This is the first definitive double blind, placebo controlled, multicenter randomized trial in pregnant women in the U.S. (N=300) to test the central hypothesis that IV iron in pregnant women with IDA (Hb\<11 g/dL and ferritin\<30 ng/mL) at 13 - 30 weeks will be effective, safe and cost-effective in reducing severe maternal morbidity-as measured by maternal anemia at delivery-and will also improve offspring neurodevelopment. A multidisciplinary team of investigators in the U.S., will pursue the following specific aims: Primary Aim: Evaluate the effectiveness and safety of IV iron, compared with oral iron, in reducing the rate of anemia at delivery in pregnant women with IDA. Secondary Aim 1: Estimate the cost-effectiveness of IV iron , compared with oral iron, in pregnant women with IDA as measured by incremental cost per Quality Adjusted Life-year (QALY). Secondary Aim 2: Assess the effect of IV iron, compared with oral iron, on offspring brain myelin content and neurodevelopment.
Participants assigned to the IV iron group will receive a single IV infusion of 1000 mg ferric derisomaltose (Monoferric, Pharmacosmos Therapeutics Inc., Morristown, NJ) in 250 mL given over 20 minutes.
325mg ferrous sulfate tablets (65 mg of elemental iron), 1 to 3 orally per day.
University of Alabama Medical Center
Birmingham, Alabama, United States
RECRUITINGGNP Research at Heme-on-Call
Miami, Florida, United States
RECRUITINGMichigan University Medical Center
Rate of maternal anemia (hgb<11mg/dL) at delivery
Hemoglobin \<11mg/dL on admission to inpatient obstetrics unit for labor and delivery
Time frame: Within 24 hours of admission to inpatient obstetrics unit for delivery of infant
Concentration of maternal hemoglobin at delivery
Hemoglobin on admission to inpatient obstetrics unit for labor and delivery
Time frame: Within 24 hours of admission to inpatient obstetrics unit for delivery of infant
Rate of maternal blood transfusion at delivery
Maternal blood transfusion from delivery to 7 days postpartum
Time frame: Delivery to 7 days postpartum
Concentration of maternal ferritin at delivery
Maternal ferritin on admission to inpatient obstetrics unit for labor and delivery
Time frame: Within 24 hours of admission to inpatient obstetrics unit for delivery of infant
Concentration of maternal hemoglobin postpartum day 1
Maternal hemoglobin on postpartum day 1
Time frame: On day after participant delivered her infant; postpartum day 1
Rate of cesarean delivery
Cesarean delivery for any indication in patients without prior cesarean deliveries
Time frame: Once at infant delivery
Rate of severe infusion adverse events
Safety and tolerability
Time frame: 2 days after intravenous iron or placebo infusion
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Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
TRIPLE
Enrollment
300
Ann Arbor, Michigan, United States
Washington University Medical Center
St Louis, Missouri, United States
RECRUITINGOregon Health and Sciences Uiversity Medical Center
Portland, Oregon, United States
RECRUITINGHasbro Children's Hospital
Providence, Rhode Island, United States
RECRUITINGWomen & Infants Hospital of Rhode Island
Providence, Rhode Island, United States
RECRUITINGUniversity of Utah Hospital
Salt Lake City, Utah, United States
RECRUITINGRate of mild medication adverse events
Safety and tolerability
Time frame: 4 weeks after initiation of oral iron or placebo
Edinburgh Perinatal Depression Scale score
Edinburgh Perinatal Depression Scale score. Minimum score 0, maximum score 30, higher scores indicate worse depressive symptoms.
Time frame: At randomization (baseline) and at 4-6 weeks postpartum
Maternal EuroQol Group Quality-of-Life Questionnaire score
Maternal EuroQol Group Quality-of-Life Questionnaire (EQ-5D-5L). Minimum score 11111 (full health), maximum score 55555 (worst health), higher scores indicate worse quality of life.
Time frame: At 6 weeks postpartum by phone or in person
Rate of Maternal infection
Any infection diagnosed from initiation of treatment until 6 weeks postpartum
Time frame: From initiation of treatment until 6 weeks postpartum
Rate of Composite Maternal Complications
Maternal mortality or any one of several maternal morbidities
Time frame: At 6 weeks postpartum
Gestational age at delivery
Gestational age at delivery
Time frame: At delivery
Rate of preterm birth at less then 37 weeks
Preterm birth; gestational age at delivery at less than 37 weeks (spontaneous or indicated)
Time frame: At delivery
Rate of Neonatal Intensive Care Unit Admission
Admission to the neonatal intensive care unit for any indication
Time frame: At birth through through 30 days from birth
Neonatal birth weight
Infant birth weight
Time frame: At birth
Concentration of umbilical artery pH
Concentration of umbilical artery pH from umbilical cord gases from infant umbilical cord segment at birth
Time frame: At birth
Concentration of umbilical artery bicarbonate
Concentration of umbilical artery bicarbonate from umbilical cord gases from infant umbilical cord segment at birth
Time frame: At birth
Concentration of umbilical artery base excess
Concentration of base excess from umbilical cord gases from infant umbilical cord segment at birth
Time frame: At birth
Concentration of umbilical artery lactate
Concentration of umbilical artery lactate from umbilical cord gases from infant umbilical cord segment at birth
Time frame: At birth
Concentration of neonatal hemoglobin
Concentration of neonatal hemoglobin from umbilical cord blood at birth or first neonatal complete blood count
Time frame: At birth
Concentration of neonatal ferritin
Concentration of neonatal ferritin from umbilical cord blood at birth or first neonatal blood draw
Time frame: At birth
Neonatal Apgar scores
Apgar scores at 1 and 5 minutes of life. Minimum score 0, maximum score 10, higher scores indicate better well being.
Time frame: At 1 minute and 5 minutes of life
Rate of composite neonatal complication
Neonatal mortality or any one of several neonatal morbidities
Time frame: Through 30 days from birth
Concentration of child brain myelin
Concentration of infant brain myelin from magnetic resonance imaging
Time frame: At an average of 6 months and 36 months
Child Mullen Scale of Early Learning Score
Mullen Scale of Early Learning Score as percentile. Minimum score 1, maximum score 99, higher scores indicate better neurodevelopment.
Time frame: At an average of 6 months and 36 months