THE DISTRIBUTION OF PARENTERAL IRON HAEMATINICS IN NONPREGNANT, PREGNANT AND LACTATING RATS

Many patients require parenteral iron therapy for optimal correction of anemia, including cancer patients who require erythropoietic drugs. Available parenteral iron therapy options include iron dextran, iron gluconate, and iron sucrose. The purpose of this study is to summarize our institution's experience with parenteral iron therapy over a 5-year period, with a focus on comparative safety profiles. All patients receiving parenteral iron therapy over this period were included in the analysis. Chi-squared test and Fisher's exact test were used to compare the adverse event rates of each product. A total of 121 patients received 444 infusions of parenteral iron over this period. Iron dextran was the most commonly used product (85 patients) and iron sucrose was the least used (2 patients). Iron gluconate was used by 34 patients. Overall adverse event rates per patient with iron dextran and iron gluconate were 16.5% and 5.8%, respectively (P = .024). Premedication with diphenhydramine and acetaminophen before infusions of iron dextran reduced adverse event rates per infusion from 12.3% to 4.4% (P = .054). Test doses of iron dextran were used 88% of the time for initial infusions of iron dextran. All adverse events for all parenteral iron products were mild or moderate. There were no serious adverse events and no anaphylaxis was observed. Our results suggest that, if test doses and premedications are used, iron dextran is an acceptable product to treat iron deficiency.

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The Use of FE59 and CR51 for Estimating Red Cell Production and Destruction: An Interpretive Review

Blood ◽

10.1182/blood.v18.2.236.236 ◽

1961 ◽

Vol 18 (2) ◽

pp. 236-250 ◽

Cited By ~ 19

Author(s):

FREDERICK STOHLMAN

Keyword(s):

Clinical Medicine ◽

Radiation Hazard ◽

Deficiency Anemia ◽

Cell Physiology ◽

Red Cell ◽

Total Radiation Dose ◽

Fundamental Understanding ◽

Parenteral Iron ◽

Experimental Use ◽

Donor Plasma

Abstract In surveying some of the limitations of studies with Cr51 and Fe59 my purpose has been not to deny their usefulness but to put them in perspective. These technics have made possible many extensions of the fundamental understanding of red cell physiology and iron metabolism. They will continue to be valuable experimental tools. It is hoped that if some of the limitations of isotope technics are considered, the non-experimental use of these isotopes will be confined to situations in which otherwise unavailable information of diagnostic or therapeutic importance can be obtained. Unfortunately isotope technics are used when more conventional means would be adequate or even preferable. An extreme example is the suggestion24 that repeated Fe59 turnover studies might be used to determine the total dose of parenteral iron (as Imferon or saccharated iron oxide) to be given in iron deficiency anemia, pointing out that in so doing the possibility of iatrogenic hemochromatosis could be avoided. The usual calculations for determining dose25 however are not only safer but more accurate. The use of Fe59 and Cr51 entails some risk, the main hazards being hepatitis, with the use of donor plasma or cells, and the possibility of untoward effects from radiation. An estimate of the risk of hepatitis can be gained from its incidence after transfusion. The radiation hazard is more difficult to assess. Leukemia has occurred after large doses of radiation but the extent of the radiation hazard is unknown from the much smaller doses of radiation employed in the usual isotopes studies. Certainly the risk is not such as to preclude the use of isotopes to obtain information essential for diagnosis. However, when such information can be obtained by other means or when results cannot be adequately interpreted, the use of isotopes in clinical medicine appears unwarranted. In considering the use of isotopes in the doubtful case, the dose of radiation to be delivered should not be thought of as an isolated event but rather as adding to a total radiation dose, which as shown by the British survey28 may be appreciable.

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Role of ferric carboxymaltose in the treatment of postpartum anemia in a tertiary care hospital in Andhra Pradesh

International Journal of Reproduction Contraception Obstetrics and Gynecology ◽

10.18203/2320-1770.ijrcog20213857 ◽

2021 ◽

Vol 10 (10) ◽

pp. 3889

Author(s):

Kirtan Krishna ◽

Achint Krishna ◽

Divya Teja G. N.

Keyword(s):

Iron Deficiency ◽

Patient Compliance ◽

Iron Deficiency Anemia ◽

Serum Ferritin ◽

Tertiary Care Hospital ◽

Tertiary Care ◽

Deficiency Anemia ◽

Ferric Carboxymaltose ◽

Care Hospital ◽

Parenteral Iron

Background: Postpartum iron deficiency anemia is common in India as a consequence of postpartum hemorrhage. Recent studies have evaluated the use of parenteral iron as a better tolerated treatment modality. Compared with oral iron supplements, parenteral iron is associated with a rapid rise in serum ferritin and hemoglobin and improved maternal fatigue scores in the postpartum period. Parenteral iron may be considered for the treatment of postpartum anemia. The objective of the study was to evaluate the efficacy, safety, and tolerability of intravenous ferric carboxymaltose, in women with postpartum anemia.Methods: A clinical observational study was undertaken in a tertiary care hospital, 50 women within six weeks of delivery with Hb ≥6 gm/dl and ≤10 gm/dl received 1000 mg/week, over 15 minutes or less, repeated weekly to a calculated replacement dose (maximum 2500 mg) . Hemoglobin and serum ferritin levels were recorded prior to treatment and on day 21 after completion of treatment.Results: Ferric carboxymaltose-treated subjects achieved a hemoglobin greater than 12 gm/dL in a short time period (21 days), achieve a hemoglobin rise of ≥3 gm/dL more quickly, and attain higher serum ferritin levels. It is also associated with better patient compliance, and shorter treatment period. Drug-related adverse events occurred less frequently with ferric carboxymaltose. The only noted disadvantage was that it is more expensive when compared to other iron preperations.Conclusions: Intravenous ferric carboxymaltose was safe and well tolerated with good efficacy and better patient compliance in the treatment of postpartum iron deficiency anemia.

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Effect of Oral Iron Treatment in Tmprss6 Knock-out Mouse Model

Blood ◽

10.1182/blood-2019-122416 ◽

2019 ◽

Vol 134 (Supplement_1) ◽

pp. 2235-2235

Author(s):

Elisa Brilli ◽

Michela Asperti ◽

Annalisa Castagna ◽

Claudio Cerchione ◽

Domenico Girelli ◽

...

Keyword(s):

Iron Deficiency ◽

Mouse Model ◽

Ferrous Sulfate ◽

Iron Status ◽

Iron Concentration ◽

Oral Iron ◽

Mrna Levels ◽

Advisory Committees ◽

Knock Out ◽

Parenteral Iron

Introduction: Iron Refractory Iron Deficiency Anemia (IRIDA) is an autosomal recessive iron metabolism disorder caused by mutations in Tmprss6 gene which encodes for Matriptase2 (MT2) that, by activating hemojuvelin (HJV), regulates the production of hepcidin, the master iron regulatory hormone. Altered MT2 cannot suppress hepatic BMP6/SMAD signaling in low iron condition, hence the resulting hepcidin excess blocks dietary iron absorption and cells release, leading to a form of iron deficiency that is typically refractory to oral iron supplementation. IRIDA is characterized by moderate/severe microcytic anemia (Hemoglobin 6-9 g/dL; MCV 45-65 fL); low transferrin saturation (<5%); impaired oral iron absorption and only a transient response to parenteral iron. Nonetheless, the current treatment is mainly based on parenteral iron therapy. A case study on a child with IRIDA showed for the first time the ability of Sucrosomial® Iron, to increase hemoglobin and MCV values over time (Capra et al., 2017). This oral iron formulation is an innovative preparation of ferric pyrophosphate, covered by a phospholipids plus sucrester matrix, with gastro-resistance properties, high bioavailability and tolerability due to alternative absorption pathways as endocytosis and M cells mediated route (Gomez-Ramirez et al., 2018). Moreover, Sucrosomial® Iron has been successfully used to treat iron deficiency in various clinical conditions, including inflammatory bowel diseases (Abbati et al., 2019). To confirm and characterize the ability of Sucrosomial® Iron to increase Hb in IRIDA disease we studied the response to Sucrosomial® Iron in a IRIDA mouse model (Mask) comparing the efficacy of Sucrosomial® Iron and Sulfate Iron at two different doses and in chronic treatment. Aim: to study Sucrosomial® Iron effect in IRIDA using the Tmprss6 knock-out mouse model Material and Methods: m/m homozygous mice (9-weeks old male mice, four mice per experimental group) were kept at iron balance diet and treated with 0.5 or 4 mg/Kg of Ferrous sulfate, Sucrosomial® Iron (patent n° PCT/IB2013/001659 owned by Alesco s.r.l, Italy), or vehicle by gavage for 35 days. Four 9-weeks old m/- male mice per experimental group were daily treated and Hb and Ht were monitored weekly. Mice were sacrificed at the end of treatments; blood, and different organs were collected for analysis. Total RNA was isolated from tissues using TRIzol Reagent (Ambion), cDNA was generated by Reverse transcription (Promega, Milan, Italy) and samples were analyzed for Hepcidin and Socs3 mRNA levels by qRT-PCR using PowerUp SYBR Green Master Mix (Life Technologies). Results: we analyzed the iron status of anemic homozygous Mask mice from 3 to 35 weeks of age by studying serological and tissue iron content. Interestingly only Sucrosomial® Iron (not Ferrous Sulfate), increased hemoglobin level from 11-12 to 13-14 g/dL in the first week with a tendency to increase until the fourth week, when it stabilized at 13 g/dL (Figure 1A-B). Serum iron concentration was higher in the Sucrosomial® Iron treated animals than in those treated with vehicle, while was lower in the Ferrous sulfate treated animals. Similar pattern was observed for spleen iron content that increased in mice treated with Sucrosomial® Iron but not in those receiving Ferrous sulfate. Liver iron concentration did not apparently varied after the treatments, but duodenal iron increased significantly only in the mice treated with the higher dose of Ferrous sulfate (Figure 1 C-F). Interestingly, we found that the mice treated with both doses of Ferrous sulfate, but not those treated with Sucrosomial® Iron, had a higher mRNA levels of hepcidin and of the inflammatory marker Socs3 (Figure 1 G-H). Conclusion: this study showed for the first time that Sucrosomial® Iron is able to increase hemoglobin level in a mouse model of IRIDA, probably due to its alternative absorption pathway. Sucrosomial® Iron could be used as effective iron supplement to improve iron status in IRIDA patients. Disclosures Girelli: La Jolla Pharmaceuticals: Membership on an entity's Board of Directors or advisory committees; Novartis: Consultancy; Vifor Pharma: Other: honoraria for lectures; Silence Therapeutics: Membership on an entity's Board of Directors or advisory committees.

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Anemia in Pregnancy & Parenteral Iron Therapy

Journal of Blood Disorders & Transfusion ◽

10.4172/2155-9864.1000171 ◽

2013 ◽

Vol 04 (06) ◽

Author(s):

Raul H

Keyword(s):

Iron Therapy ◽

Parenteral Iron ◽

Anemia In Pregnancy ◽

Parenteral Iron Therapy ◽

In Pregnancy

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Effect of Iron Therapy on Behavior Performance in Nonanemic, Iron-Deficient Infants

PEDIATRICS ◽

10.1542/peds.71.6.877 ◽

1983 ◽

Vol 71 (6) ◽

pp. 877-880 ◽

Cited By ~ 3

Author(s):

Frank A. Oski ◽

Alice S. Honig ◽

Brenda Helu ◽

Peter Howanitz

Keyword(s):

Iron Deficiency ◽

Mental Development ◽

Mean Cell Volume ◽

Ferritin Concentration ◽

Development Index ◽

Biochemical Alterations ◽

Mental Development Index ◽

Iron Deficient ◽

Serum Ferritin Concentration ◽

Parenteral Iron

In an effort to determine whether iron deficiency, in the absence of anemia (hemoglobin >11.0 g/dL), might produce alterations in behavioral development, four groups of nonanemic infants, 9 to 12 months of age, with varying degrees of iron deficiency were studied. Infants were classified as iron sufficient, iron depleted, or iron deficient based on measurements of serum ferritin concentration, erythrocyte protoporphyrin values, and the mean cell volume of erythrocytes. Subjects in each group were tested with the Bayley Mental Development Index, treated with parenteral iron, and retested seven days later. The administration of iron produced a significant increase in the Mental Development Index scores (+21.6 points) in the infants with iron deficiency but no significant change in the scores of infants with iron sufficiency (+6.2 points) or only iron depletion (+5.6 points). It is concluded that iron deficiency, even in the absence of anemia, results in biochemical alterations that impair behavior in infants.

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Parenteral Iron Therapy

Manual on Labour Room Protocols ◽

10.5005/jp/books/13097_12 ◽

2018 ◽

pp. 80-80

Author(s):

Shirish Daftary ◽

Munjal Pandya

Keyword(s):

Iron Therapy ◽

Parenteral Iron ◽

Parenteral Iron Therapy

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