Michael K. Georgieff

Perinatal iron deficiency decreases cytochrome c oxidase (CytOx) activity in selected regions of neonatal rat brain.

Intrauterine growth retardation and diabetes mellitus during human gestation result in significant losses of fetal and neonatal brain iron. Brain iron deficiency is associated with impaired cognitive processes including memory and attention. The regional distribution of iron staining and cytochrome c oxidase (CytOx) activity have not been mapped in the iron-sufficient or -deficient neonatal rat. CytOx is the iron-containing terminal enzyme in oxidative phosphorylation; its activity reflects neuronal metabolism. We hypothesized that neonatal brain iron deficiency differentially decreases iron and CytOx activity in brain regions, with more pronounced losses in structures involved in recognition memory. Pregnant Sprague Dawley rats were fed either an iron-deficient or -fortified diet from gestational d 1 until postnatal d 10. Iron staining and CytOx activity of 20 brain structures were mapped histochemically in 25 rats from each group. Brain iron staining was reduced from 75% to 100% and CytOx staining was decreased from 0% to 42% in the iron-deficient group (p < 0.001). Areas with significantly reduced CytOx activity (p < 0.001) included all measured subareas of the hippocampus (CA1: 42%, CA3ab: 34%, CA3c: 33%, and dentate gyrus: 32%), the piriform cortex (17%), the medial dorsal thalamic nucleus (28%), and the cingulate cortex (41%). In contrast, the anterior thalamic nucleus, the lateral amygdaloid nucleus, and the medial habenula, areas not involved in higher cognitive functions, did not have significantly reduced CytOx activity (0%, 10%, and 16%, respectively). We conclude that perinatal iron deficiency differentially reduces neuronal metabolic activity, specifically targeting areas of the brain involved in memory processing.

Abnormal iron distribution in infants of diabetic mothers: Spectrum and maternal antecedents

Because chronic hypoxemia causes a redistribution of iron from serum and storage pools into an expanding erythrocyte mass, and because infants of diabetic mothers are often hypoxemic in utero and have a high prevalence of polycythemia at birth, we studied iron distribution in 43 term infants of diabetic mothers. Twenty-four infants were at an appropriate size for gestational age; 19 were large for gestational age. At birth, 28 infants (65%) had abnormal serum iron profiles; eight had decreased ferritin concentrations only (stage 1), nine had decreased ferritin and increased total iron-binding capacity values (stage 2), and 11 had these serum findings plus elevated free erythrocyte protoporphyrin concentrations (stage 3). The hypoglycemic infants who were large for gestational age (n = 14) had a higher prevalence of abnormal iron profiles than euglycemic infants who were appropriate in size for gestational age (n = 20; 93% vs 50%; p = 0.009). Progressively abnormal iron profiles were associated with higher glycosylated fetal hemoglobin values, greater degrees of macrosomia, increased hemoglobin and erythropoietin concentrations, and increased erythrocyte/storage iron ratios. Erythropoietin concentrations were inversely linearly correlated with serum iron values (n = 32, r = -0.54; p = 0.003). The combined erythrocyte and storage iron pools were significantly lower in infants with abnormal iron values whose mothers were diabetic, particularly in infants of women with confirmed diabetic vasculopathy. We speculate that these findings are likely due to (1) increased fetal iron utilization during compensatory hemoglobin synthesis in response to chronic hypoxemia and (2) reduced iron transfer during late gestation complicated by diabetes.

Cord transferrin and ferritin values in newborn infants at risk for prenatal uteroplacental insufficiency and chronic hypoxia

We measured cord transferrin and ferritin levels in 50 newborn infants with fetal conditions associated with either uteroplacental vascular insufficiency or chronic hypoxia. Sixteen small for gestational age infants, 21 infants of mothers with preeclampsia, and 13 symptomatic infants of diabetic mothers had significantly higher transferrin levels and lower ferritin levels and calculated iron stores than did asymptomatic gestational age-matched control infants without these conditions. Cord ferritin levels and calculated iron stores were significantly lower in the infants of diabetic mothers than in any other group of infants. Cord transferrin levels were inversely correlated with ferritin levels (r = -0.59, P less than 0.001) and were unrelated to transthyretin levels and birth weight in the high-risk infants, but were positively correlated with ferritin levels (r = 0.50, P less than 0.001), transthyretin levels (r = 0.65, P less than 0.001), and birth weight (r = 0.75, P less than 0.001) in the control infants. We conclude that cord transferrin levels do not reflect protein-energy status in newborn infants with prenatal histories suggesting uteroplacental insufficiency or chronic hypoxia, and that when associated with decreased cord ferritin levels, indicate possible impaired iron stores in these infants.

The Effect of Prolonged Intrauterine Hyperinsulinemia on Iron Utilization in Fetal Sheep

ABSTRACT: Newborn infants of poorly controlled insulin-dependent diabetic mothers demonstrate a redistribution of iron from serum and tissue stores into red blood cells. These changes may be due to increases in iron utilization during augmented Hb synthesis, which compensates for chronic intrauterine hypoxemia induced by prolonged fetal hyperinsulinemia. We tested this hypothesis by measuring plasma iron, total iron-binding capacity, percent iron-binding capacity saturation (total iron-binding capacity saturation), Hb concentration, total red cell Hb, and total red cell iron in the arterial blood of 11 chronically instrumented fetal sheep after 7-12 d of infusion with 15 U/day of insulin (n = 5) or placebo (n = 6). The insulin-infused fetal sheep had higher mean ± SD plasma insulin concentrations (448 ± 507 versus 11 ± 8 mU/L; p < 0.001) and lower arterial oxygen saturations (38 ± 7 versus 54 ± 9%;p < 0.02). The insulin-infused group had a lower mean plasma iron concentration (20.8 ± 10.9 versus 42.1 ± 14.7 nM/L;p < 0.02) and total iron-binding capacity saturation (36 ± 20 versus 64 ± 22%; p < 0.02) and a higher total red cell Hb (45.4 ± 8.7 versus 32.6 ± 8.8 g; p < 0.02) and total red cell iron content (154 ± 29 versus 111 ± 29 mg; p < 0.02) when compared with the placebo group. Seven to 12 d of intrauterine hyperinsulinemia decreases serum iron and increases total red cell iron, most likely by stimulating increased Hb synthesis in response to low arterial oxygen saturation. Hyperinsulemia may play a major role in the altered iron metabolism in newborn infants of diabetic mothers.

The relationship between decreased iron stores, serum iron and neonatal hypoglycemia in large-for-date newborn infants

ABSTRACT. We assessed the relationship between neonatal hypoglycemia and newborn iron status in 15 hypoglycemic, large‐for‐date newborn infants, 12 of whom were infants of diabetic mothers. These infants had significantly lower mean serum iron concentrations, ferritin concentrations, percent iron‐binding saturation and calculated iron stores, and significantly higher mean transferrin concentrations, total iron‐binding capacity concentrations and mid‐arm circumference: head circumference ratios when compared with either 15 euglycemic large‐for‐date or 15 euglycemic appropriate‐for‐date control infants (p < 0.001 for all comparisons). All hypoglycemic infants had ferritin concentrations below the 5th percentile as compared to 3 % of controls (p < 0.001), and 67 % had transferrin concentrations above the 95th percentile (controls: 0 %; p < 0.001). Only the hypoglycemic infants demonstrated a significant negative linear correlation between ferritin and transferrin concentrations (r=−0.83; p < 0.001). Decreased serum iron concentrations were associated with size at birth (r=−0.60; p= 0.01) and with increased red cell iron (r=−0.60; p= 0.01), implying a redistribution of iron dependent on the degree of fetal hyperglycemia and hyperinsulinemia. Infants with increased red cell iron had more profound neonatal hypoglycemia. These results show a significant association between decreased iron stores and neonatal hypoglycemia in macrosomic newborn infants associated with a significant shift of iron into red blood cells.

The effect of in utero insulin exposure on tissue iron status in fetal rats

ABSTRACT: Newborn infants of diabetic mothers have serum biochemical signs of iron deficiency in cord blood directly related to elevations of cord erythropoietin and Hb concentrations. In sheep, chronic fetal hyperinsulinemia results in fetal hypoxemia, expansion of the red cell mass, and decreased iron concentrations, most likely due to increased iron utilization for Hb synthesis. To determine whether fetal insulin exposure also results in reduced tissue iron concentrations, we measured liver, skeletal muscle, small intestine, heart, and brain iron concentrations in newborn rat pups after s.c. fetal injection of insulin or diluent alone on d 19 of gestation. The fetuses of 11 pregnant rats were exteriorized, injected with 2 U neutral protamine Hagedorn insulin or diluent, replaced in utero, and delivered on d 22. To determine dose dependency, the fetuses of six pregnant rais were injected with 3 U of longer-acting protamine zinc insulin and delivered on d 21. At delivery, the insulin-treated groups had higher birth weights than the placebo-treated group, although plasma insulin concentrations were not different. The 2 U neutral protamine Hagedorn insulin-treated fetuses had significantly lower mean ± SEM liver iron concentrations than the control fetuses (910 ± 34 versus 1014 ± 43 μg/g dry tissue weight; p < 0.05), but had similar skeletal muscle iron concentrations. The 3 U protamine zinc insulin-treated fetuses had significantly lower liver and skeletal muscle iron concentrations compared to control and to 2 U neutral protamine Hagedorn insulin-treated fetuses (p < 0.05). No differences in small intestine, heart, or brain iron concentrations were seen among groups. We conclude that exposure of fetal rats to insulin during late gestation compromises liver and skeletal muscle iron content. Based upon these findings, we speculate that infants of poorly controlled diabetic mothers may be at risk for decreased tissue iron content.