Iron Supplementation in Suckling Piglets: An Ostensibly Easy Therapy of Neonatal Iron Deficiency Anemia

In pigs, iron deficiency anemia (IDA) is the most prevalent deficiency disorder during the early postnatal period, frequently developing into a serious illness. On the other hand, in humans, only low-birth-weight infants, including premature infants, are especially susceptible to developing IDA. In both human and pig neonates, the initial cause of IDA is low birth iron stores. In piglets this shortage of stored iron results mainly from genetic selection over the past few decades for large litter sizes and high birth weights. As a consequence, pregnant sows cannot provide a sufficient amount of iron to the increasing number of developing fetuses. Supplementation with iron is a common practice for the treatment of IDA in piglets. For decades, the preferred procedure for delivering iron supplements during early life stages has been through the intramuscular injection of a large amount of iron dextran. However, this relatively simple therapy, which in general, efficiently corrects IDA, may generate toxic effects, and by inducing hepcidin expression, may decrease bioavailability of supplemental iron. New iron supplements are considered herein with the aim to combine the improvement of hematological status, blunting of hepcidin expression, and minimizing the toxicity of the administered iron. We propose that iron-deficient piglets constitute a convenient animal model for performing pre-clinical studies with iron supplements.

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Iron Supplementation in Suckling Piglets: an Ostensibly Easy Therapy of Neonatal Iron Deficiency Anemia

10.20944/preprints201810.0189.v1 ◽

2018 ◽

Author(s):

Mateusz Szudzik ◽

Rafał R. Starzyński ◽

Aneta Jończy ◽

Rafał Mazgaj ◽

Małgorzata Lenartowicz ◽

...

Keyword(s):

Birth Weight ◽

Iron Deficiency ◽

Iron Deficiency Anemia ◽

Postnatal Period ◽

Deficiency Anemia ◽

High Birth Weight ◽

Low Birth Weight Infants ◽

Iron Supplements ◽

Hepcidin Expression ◽

Iron Deficient

In pigs, iron deficiency anemia (IDA) is the most prevalent deficiency disorder during the early postnatal period frequently developing into a critical illness. Meanwhile, in humans, only low-birth-weight infants, including premature infants are especially susceptible to developing IDA. In both human and pig neonates, the initial cause of IDA is low birth iron stores. In piglets this shortage of stored iron results mainly from genetic selection over the past few decades for large litter size and high birth weight. In consequence, pregnant sows cannot provide sufficient amount of iron to the increasing number of developing fetuses. Supplementation with iron is a common practice for the treatment of IDA in piglets. For decades, the preferred procedure for delivering iron supplements during early life stages has been through the intramuscular injection of large amount of iron dextran. However, this relatively simple therapy, which in general, efficiently corrects IDA, may generate toxic effects, and by inducing hepcidin expression, may decrease bioavailability of supplemental iron. New iron supplements are considered now with the aim to combine improvement of hematological status, blunting hepcidin expression, and minimizing toxicity of the administered iron. We propose that iron-deficient piglets constitute a convenient animal model for performing pre-clinical studies with iron supplements.

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Iron Supplements Reduce the Risk of Iron Deficiency Anemia in Marginally Low Birth Weight Infants

PEDIATRICS ◽

10.1542/peds.2009-3624 ◽

2010 ◽

Vol 126 (4) ◽

pp. e874-e883 ◽

Cited By ~ 62

Author(s):

S. Berglund ◽

B. Westrup ◽

M. Domellof

Keyword(s):

Birth Weight ◽

Iron Deficiency ◽

Low Birth Weight ◽

Iron Deficiency Anemia ◽

Deficiency Anemia ◽

Low Birth Weight Infants ◽

Iron Supplements

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Iron Supplements Reduce the Risk of Iron Deficiency Anemia in Marginally Low Birth Weight Infants

PEDIATRICS ◽

10.1542/peds.2009-3624d ◽

2010 ◽

Vol 127 (2) ◽

pp. peds.2009-3624d-peds.2009-3624d

Keyword(s):

Birth Weight ◽

Iron Deficiency ◽

Low Birth Weight ◽

Iron Deficiency Anemia ◽

Deficiency Anemia ◽

Low Birth Weight Infants ◽

Iron Supplements

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Iron supplementation in goitrous, iron-deficient children improves their response to oral iodized oil

Acta Endocrinologica ◽

10.1530/eje.0.1420217 ◽

2000 ◽

pp. 217-223 ◽

Cited By ~ 33

Author(s):

M Zimmermann ◽

P Adou ◽

T Torresani ◽

C Zeder ◽

R Hurrell

Keyword(s):

Iron Deficiency ◽

Iron Deficiency Anemia ◽

Iron Supplementation ◽

Thyroid Volume ◽

Oral Iron ◽

Deficiency Anemia ◽

Urinary Iodine Concentration ◽

Iodized Oil ◽

Iron Deficient ◽

Group 2

OBJECTIVE: In developing countries, many children are at high risk for both goiter and iron-deficiency anemia. Because iron deficiency may impair thyroid metabolism, the aim of this study was to determine if iron supplementation improves the response to oral iodine in goitrous, iron-deficient anemic children. DESIGN: A trial of oral iodized oil followed by oral iron supplementation in an area of endemic goiter in the western Ivory Coast. METHODS: Goitrous, iodine-deficient children (aged 6-12 years; n=109) were divided into two groups: Group 1 consisted of goitrous children who were not anemic; Group 2 consisted of goitrous children who were iron-deficient anemic. Both groups were given 200mg oral iodine as iodized oil. Thyroid gland volume using ultrasound, urinary iodine concentration (UI), serum thyroxine (T(4)) and whole blood TSH were measured at baseline, and at 1, 5, 10, 15 and 30 weeks post intervention. Beginning at 30 weeks, the anemic group was given 60mg oral iron as ferrous sulfate four times/week for 12 weeks. At 50 and 65 weeks after oral iodine (8 and 23 weeks after completing iron supplementation), UI, TSH, T(4) and thyroid volume were remeasured. RESULTS: The prevalence of goiter at 30 weeks after oral iodine in Groups 1 and 2 was 12% and 64% respectively. Mean percent change in thyroid volume compared with baseline at 30 weeks in Groups 1 and 2 was -45.1% and -21.8% respectively (P<0.001 between groups). After iron supplementation in Group 2, there was a further decrease in mean thyroid volume from baseline in the anemic children (-34.8% and -38.4% at 50 and 65 weeks) and goiter prevalence fell to 31% and 20% at 50 and 65 weeks. CONCLUSION: Iron supplementation may improve the efficacy of oral iodized oil in goitrous children with iron-deficiency anemia.

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Effects of Iron Deficiency Anemia and Its Rapid Correction on the Serum Metabolomic Profile of Rhesus Infants

Current Developments in Nutrition ◽

10.1093/cdn/nzaa054_142 ◽

2020 ◽

Vol 4 (Supplement_2) ◽

pp. 1070-1070

Author(s):

Brian Sandri ◽

Gabriele Lubach ◽

Eric Lock ◽

Michael Georgieff ◽

Pamela Kling ◽

...

Keyword(s):

Iron Deficiency ◽

Iron Deficiency Anemia ◽

Acid Production ◽

Iron Status ◽

Deficiency Anemia ◽

Iron Dextran ◽

Metabolomic Profile ◽

Intramuscular Injections ◽

Iron Deficient ◽

Rapid Correction

Abstract Objectives To determine whether rapid correction of iron deficiency using intramuscular iron dextran normalizes serum metabolomic changes in a nonhuman primate model of iron deficiency anemia (IDA). Methods Blood was collected from naturally iron-sufficient (IS; n = 10) and IDA (n = 12) male and female infant rhesus monkeys (Macaca mulatta) at 6 months of age. IDA infants were treated with intramuscular injections of iron dextran, 10 mg/weekly for 4–8 weeks. Iron status was reevaluated following treatment using hematological measurements and sera were metabolically profiled using HPLC/MS with isobaric standards for identification and quantification. Results Early-life iron deficiency anemia negatively affects many cellular metabolic processes, including energy production, electron transport, and oxidative degradation of toxins. Slow iron repletion with dietary supplementation restores iron deficient monkeys from a hematological perspective, but the serum metabolomic profile remains differed from monkeys that had been iron sufficient their entire life. Whether rapid iron restoration through intramuscular injections of iron dextran normalizes serum metabolomic profile is not known. A total of 654 metabolites were measured with differences in 53 metabolites identified between IS and IDA monkeys at 6 months (P 0.05). Pathway analyses provided evidence of altered liver function, hypometabolic state, differential essential fatty acid production, irregular inosine and guanosine metabolism, and atypical bile acid production in IDA infants. After treatment, iron-related hematological parameters had recovered, but the formerly IDA infants remained metabolically distinct from the IS infants, with 225 metabolites differentially expressed between the groups. Conclusions As with slow iron repletion, rapid iron repletion does not normalize the altered serum metabolomic profile in rhesus infants with IDA, suggesting the need for iron supplementation in the pre-anemic stage. Funding Sources National Institutes of Health.

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