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    Baby Food Pouches, Baby-Led Weaning, and Iron Status in New Zealand Infants: An Observational Study.
    (MDPI (Basel, Switzerland), 2024-05-15) McLean NH; Haszard JJ; Daniels L; Taylor RW; Wheeler BJ; Conlon CA; Beck KL; von Hurst PR; Te Morenga LA; McArthur J; Paul R; Katiforis I; Brown KJ; Gash MC; Rowan MM; Casale M; Cox AM; Jones EA; Jupiterwala RM; Bruckner B; Fleming L; Heath A-LM; Chen Y; Tran PV; Felt BT
    Iron deficiency in infants can impact development, and there are concerns that the use of baby food pouches and baby-led weaning may impair iron status. First Foods New Zealand (FFNZ) was an observational study of 625 New Zealand infants aged 6.9 to 10.1 months. Feeding methods were defined based on parental reports of infant feeding at "around 6 months of age": "frequent" baby food pouch use (five+ times per week) and "full baby-led weaning" (the infant primarily self-feeds). Iron status was assessed using a venepuncture blood sample. The estimated prevalence of suboptimal iron status was 23%, but neither feeding method significantly predicted body iron concentrations nor the odds of iron sufficiency after controlling for potential confounding factors including infant formula intake. Adjusted ORs for iron sufficiency were 1.50 (95% CI: 0.67-3.39) for frequent pouch users compared to non-pouch users and 0.91 (95% CI: 0.45-1.87) for baby-led weaning compared to traditional spoon-feeding. Contrary to concerns, there was no evidence that baby food pouch use or baby-led weaning, as currently practiced in New Zealand, were associated with poorer iron status in this age group. However, notable levels of suboptimal iron status, regardless of the feeding method, emphasise the ongoing need for paying attention to infant iron nutrition.
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    A contemporary understanding of iron metabolism in active premenopausal females
    (Frontiers Media S.A, 2022) Badenhorst CE; Forsyth AK; Govus AD
    Iron metabolism research in the past decade has identified menstrual blood loss as a key contributor to the prevalence of iron deficiency in premenopausal females. The reproductive hormones estrogen and progesterone influence iron regulation and contribute to variations in iron parameters throughout the menstrual cycle. Despite the high prevalence of iron deficiency in premenopausal females, scant research has investigated female-specific causes and treatments for iron deficiency. In this review, we provide a comprehensive discussion of factors that influence iron status in active premenopausal females, with a focus on the menstrual cycle. We also outline several practical guidelines for monitoring, diagnosing, and treating iron deficiency in premenopausal females. Finally, we highlight several areas for further research to enhance the understanding of iron metabolism in this at-risk population.
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    Influence of an energy deficient and low carbohydrate acute dietary manipulation on iron regulation in young females
    (Wiley Periodicals LLC on behalf of The Physiological Society and the American Physiological Society, 2022-07) Hayashi N; Ishibashi A; Iwata A; Yatsutani H; Badenhorst C; Goto K
    Hepcidin is a liver-derived hormone that regulates iron metabolism. Recent studies suggest that an energy-deficient diet or low carbohydrate (CHO) availability may increase hepcidin in the absence of inflammation. The purpose of the present study was to examine the impact of either an energy-deficient diet or an ED diet with low CHO intake during three consecutive days on hepcidin responses, hematological variables, and energy metabolism in young Japanese women. Twenty-two young females were divided into two different groups, either an energy-deficient with low CHO intake group (ED + LCHO; 2.0 ± 0.3 g/kg/day CHO, 39%CHO, 1123 kcal/day) or an energy deficient with moderate CHO intake group (ED; 3.4 ± 0.3 g/kg/day CHO, 63%CHO, 1162 kcal/day). During the three consecutive days of the dietary intervention program, participants consumed only the prescribed diet and maintained their habitual physical activity levels. Body composition, substrate oxidation, iron metabolism, and inflammation were evaluated pre- and post-intervention. Serum iron and ferritin levels were significantly elevated following the intervention (p < 0.001, p = 0.003, respectively). Plasma interleukin-6 (IL-6) levels did not change following the intervention. Serum hepcidin levels significantly increased after the intervention (p = 0.002). Relative change in hepcidin levels was significantly higher in the ED + LCHO (264.3 ± 87.2%) than in the ED group (68.9 ± 22.1%, p = 0.048). Three consecutive days of an energy-deficient diet increased fasting hepcidin levels. Moreover, elevated hepcidin levels were further augmented when an energy-deficient diet was combined with a lower CHO intake.