Maternal Iron Status Influences Iron Transfer to the Fetus During the Third Trimester of Pregnancy

Overview

Journal Am J Clin Nutr

Publisher Elsevier

Specialty Nutritional Sciences

Date 2003 Mar 29

PMID 12663293

Citations 43

Authors

Kimberly O OBrien

Nelly Zavaleta

Steven A Abrams

Laura E Caulfield

Affiliations

Soon will be listed here.

Abstract

Background: The effect of maternal iron status on fetal iron deposition is uncertain.

Objective: We used a unique stable-isotope technique to assess iron transfer to the fetus in relation to maternal iron status.

Design: The study group comprised 41 Peruvian women. Of these women, 26 received daily prenatal supplements containing iron and folate (n = 11; Fe group) or iron, folate, and zinc (n = 15; Fe+Zn group) from week 10-24 of pregnancy to 1 mo postpartum. The remaining 15 women (control group) received iron supplementation only during the final month of pregnancy. During the third trimester of pregnancy (+/- SD: 32.9 +/- 1.4 wk gestation) oral 57Fe (10 mg) and intravenous 58Fe (0.6 mg) stable iron isotopes were administered to the women, and isotope enrichment and iron-status indicators were measured in cord blood at delivery.

Results: The net amount of 57Fe in the neonates' circulation (from maternal oral dosing) was significantly related to maternal iron absorption (P < 0.005) and inversely related to maternal iron status during the third trimester of pregnancy: serum ferritin (P < 0.0001), serum folate (P < 0.005), and serum transferrin receptors (P < 0.02). Significantly more 57Fe was transferred to the neonates in non-iron-supplemented women: 0.112 +/- 0.031 compared with 0.078 +/- 0.042 mg in the control group (n = 15) and the Fe and Fe+Zn groups (n = 24), respectively (P < 0.01). In contrast, 58Fe tracer in the neonates' circulation was not significantly related to maternal iron status.

Conclusion: The transfer of dietary iron to the fetus is regulated in response to maternal iron status at the level of the gut.

Citing Articles

A Large Proportion of the Neonatal Iron Pool Is Acquired from the Gestational Diet in a Murine Model.

Lueschow-Guijosa S, Michels K, Latta D, Bermick J J Nutr. 2024; 154(7):2065-2075.

PMID: 38797484 PMC: 11282491. DOI: 10.1016/j.tjnut.2024.05.021.

[Cross-sectional study of iron level during pregnancy at the Mohamed V Military Training Hospital, Rabat].

Karfo R, Mpawenimana S, Kabre E, Sakande J, Tellal S Pan Afr Med J. 2023; 45:139.

PMID: 37790157 PMC: 10543984. DOI: 10.11604/pamj.2023.45.139.37687.

Maternal diet quality and nutrient intakes across preconception and pregnancy are not consistent with Australian guidelines: Results from the pilot BABY1000 study.

Maneschi K, Geller T, Collins C, Gordon A, Grech A Food Sci Nutr. 2023; 11(7):4113-4123.

PMID: 37457169 PMC: 10345671. DOI: 10.1002/fsn3.3401.

Quantitating Iron Transport across the Mouse Placenta In Vivo using Nonradioactive Iron Isotopes.

Sangkhae V, Nemeth E J Vis Exp. 2022; (183).

PMID: 35635455 PMC: 9927870. DOI: 10.3791/63378.

Impact and interactions between risk factors on the iron status of at-risk neonates.

Brichta C, Godwin J, Norlin S, Kling P J Perinatol. 2022; 42(8):1103-1109.

PMID: 35132153 DOI: 10.1038/s41372-022-01318-4.