Excess iron: considerations related to development and early growth.
Study Goal
The researchers aimed to explore how micronutrients like copper interact with iron in erythropoiesis, though specific effects of copper were not the primary focus.
Results Summary
The abstract mentions that copper supports iron's function in erythropoiesis, but the specific interactions and effects of copper remain unknown.
Population
Not specified (general focus on early life exposures and developmental impacts).
Effective Dosage
Not mentioned
Duration
Not mentioned
Interactions
None mentioned
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
high iron status in early life | increase | oxidative stress | - | - | imparted by | #1 |
iron exposures | neutral | mood, emotion, cognition, and memory | children | - | associations between | #2 |
high iron conditions | increase | ineffective erythropoiesis and iron-loading anemia | - | - | might promote | #3 |
key micronutrients (e.g., vitamin A, copper, manganese, and zinc) | neutral | iron's function in erythropoiesis | - | - | support | #4 |
What effects might arise from early life exposures to high iron? This review considers the specific effects of high iron on the brain, stem cells, and the process of erythropoiesis and identifies gaps in our knowledge of what molecular damage may be incurred by oxidative stress that is imparted by high iron status in early life. Specific areas to enhance research on this topic include the following: longitudinal behavioral studies of children to test associations between iron exposures and mood, emotion, cognition, and memory; animal studies to determine epigenetic changes that reprogram brain development and metabolic changes in early life that could be followed through the life course; and the establishment of human epigenetic markers of iron exposures and oxidative stress that could be monitored for early origins of adult chronic diseases. In addition, efforts to understand how iron exposure influences stem cell biology could be enhanced by establishing platforms to collect biological specimens, including umbilical cord blood and amniotic fluid, to be made available to the research community. At the molecular level, there is a need to better understand stress erythropoiesis and changes in iron metabolism during pregnancy and development, especially with respect to regulatory control under high iron conditions that might promote ineffective erythropoiesis and iron-loading anemia. These investigations should focus not only on factors such as hepcidin and erythroferrone but should also include newly identified interactions between transferrin receptor-2 and the erythropoietin receptor. Finally, despite our understanding that several key micronutrients (e.g., vitamin A, copper, manganese, and zinc) support iron's function in erythropoiesis, how these nutrients interact remains, to our knowledge, unknown. It is necessary to consider many factors when formulating recommendations on iron supplementation.