Brain and Behavior Depending on Timing of Iron Deficiency in Human Infants

Iron Deficiency, Iron Deficiency Anemia

iron deficiency, iron deficiency anemia, infant, development, behavior

It is common in many populations that babies develop iron deficiency or iron deficiency anemia (that is, too few healthy red blood cells due to lack of iron). This is due to rapid growth in infancy combined with limited sources of iron in the infant diet. The amount of iron the baby receives across the placenta during pregnancy is another important factor. This study focuses on infants who are born with less than the usual amount of iron in their bodies. The purposes of the study are to assess effects of lower iron at birth on infant behavior and development and to determine if providing iron supplements to such infants beginning at 6 weeks fosters healthier development. Another part of the study will determine the effects of iron deficiency anemia at different times during infant development.

The project focuses on brain-behavior effects depending on the timing of iron deficiency (ID) and iron repletion in human infants. Iron deficiency (ID) is the world's most common single nutrient disorder, differentially affecting pregnant women and infants everywhere. The study promises to be the first systematic investigation of brain and behavior effects of prenatal dietary iron deficiency in human infants. The design will support comparisons of brain/behavior effects depending on the timing and duration of ID. The study will assess reversibility of effects, depending on timing of ID and its treatment, and examine maternal vs. fetal iron regulatory mechanisms in placenta and white blood cells. State-of-the-art neurophysiologic and behavioral measures will test specific hypotheses regarding effects of ID on sensory, motor, cognitive, affective-social and regulatory functions related to impaired myelination of sensory/motor systems and altered structure, neurotransmitter function and neurometabolism in targeted brain regions (basal ganglia and hippocampus). The study will be conducted in China, a rapidly developing country where ID often occurs among pregnant women and infants in the absence of generalized undernutrition. Cord blood hemoglobin (Hb) and ferritin concentrations will be measured in 1300 rural full-term infants, with iron status determined again at 9 and 18 mo. Brain-behavior assessments in the perinatal period will involve 359 infants (newborn cohort): 59 with low Hb (low birth iron group) will receive iron; 200 with marginal Hb or low cord ferritin (marginal birth iron group) will be randomly assigned at 6 wk, 50 to iron therapy and 150 to vitamins only; and 100 with normal cord Hb and ferritin levels (normal birth iron group) will receive vitamins only. The remaining 763 infants with cord blood testing will form the blood screen cohort. At 9 and 18 mo, the newborn cohort will be reassessed, along with IDA infants from the blood screen cohort - about 58 at 9 mo (early postnatal IDA) and 48 at 18 mo (late postnatal IDA). Approximately 39 marginal-birth-iron vitamins only-treated infants in the newborn cohort may also have IDA at 9 mo (combined ID). IDA infants will be treated with vitamins with iron. Differential effects and/or reversibility depending on timing of ID or treatment could inform health policy and practice worldwide. However, the effects of prenatal iron deficiency have received very little study in human infants due in large part to previous thinking, no longer accepted, that the infant was protected. Up to 75% of pregnant women worldwide are anemic, with about half due to ID. An estimated 20-25% of 6- to 24-mo-old infants have IDA, and more have ID without anemia. Thus, the public health implications of study findings could be profound. The project is expected to continue with a 5-year follow-up (Aug 2013-July 2017).

China