Production of Iron-Enriched Leaf Vegetables by Soaking Roots in Ammonium Ferric Citrate Solution: pH and Iron Concentration on the Foliar Iron Content.

The distribution and behavior of certain of trace elements in sea water is greatly affected by both physical, chemical and hydrometeorological conditions that are showed in the scientific works of prof. Yu.A. Fedorov with coauthors (1999-2015). Due to the shallow waters last factor is one of the dominant, during the different wind situation changes significantly the dynamics of water masses and interaction in the system “water – suspended matter – bottom sediments”.Therefore, the study of the behavior of the total iron in the water of the sea at different wind situation is relevant. The content of dissolved iron forms migration in The Sea of Azov water (open area) varies from 0.017 to 0.21 mg /dm3 (mean 0.053 mg /dm3) and in Taganrog Bay from 0.035 to 0.58 mg /dm3 (mean 0.11 mg /dm3) and it is not depending on weather conditions.The reduction in the overall iron concentration in the direction of the Taganrog Bay → The Sea of Azov (open area) is observed on average more than twice. The dissolved iron content exceeding TLV levels and their frequency of occurrence in the estuary, respectively, were higher compared with The Sea of Azov (open area).There is an increase in the overall iron concentration in the water of the Azov Sea on average 1.5 times during the storm conditions, due to the destruction of the structure of the upper layer and resuspension of bottom sediments, intensifying the transition of iron compounds in the solution.

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Evidence for a copper-dependent iron transport system in the marine, magnetotactic bacterium strain MV-1

Microbiology ◽

10.1099/mic.0.27233-0 ◽

2004 ◽

Vol 150 (9) ◽

pp. 2931-2945 ◽

Cited By ~ 59

Author(s):

Bradley L. Dubbels ◽

Alan A. DiSpirito ◽

John D. Morton ◽

Jeremy D. Semrau ◽

J. N. E. Neto ◽

...

Keyword(s):

Iron Content ◽

Iron Uptake ◽

Iron Transport ◽

Dna Analysis ◽

Iron Concentration ◽

Protein A ◽

Uptake System ◽

Iron Uptake System ◽

Cellular Iron ◽

Solid Media

Cells of the magnetotactic marine vibrio, strain MV-1, produce magnetite-containing magnetosomes when grown anaerobically or microaerobically. Stable, spontaneous, non-magnetotactic mutants were regularly observed when cells of MV-1 were cultured on solid media incubated under anaerobic or microaerobic conditions. Randomly amplified polymorphic DNA analysis showed that these mutants are not all genetically identical. Cellular iron content of one non-magnetotactic mutant strain, designated MV-1nm1, grown anaerobically, was ∼20- to 80-fold less than the iron content of wild-type (wt) MV-1 for the same iron concentrations, indicating that MV-1nm1 is deficient in some form of iron uptake. Comparative protein profiles of the two strains showed that MV-1nm1 did not produce several proteins produced by wt MV-1. To understand the potential roles of these proteins in iron transport better, one of these proteins was purified and characterized. This protein, a homodimer with an apparent subunit mass of about 19 kDa, was an iron-regulated, periplasmic protein (p19). Two potential ‘copper-handling’ motifs (MXM/MX2M) are present in the amino acid sequence of p19, and the native protein binds copper in a 1 : 1 ratio. The structural gene for p19, chpA (copper handling protein) and two other putative genes upstream of chpA were cloned and sequenced. These putative genes encode a protein similar to the iron permease, Ftr1, from the yeast Saccharomyces cerevisiae, and a ferredoxin-like protein of unknown function. A periplasmic, copper-containing, iron(II) oxidase was also purified from wt MV-1 and MV-1nm1. This enzyme, like p19, was regulated by media iron concentration and contained four copper atoms per molecule of enzyme. It is hypothesized that ChpA, the iron permease and the iron(II) oxidase might have analogous functions for the three components of the S. cerevisiae copper-dependent high-affinity iron uptake system (Ctr1, Ftr1 and Fet3, respectively), and that strain MV-1 may have a similar iron uptake system. However, iron(II) oxidase purified from both wt MV-1 and MV-1nm1 displayed comparable iron oxidase activities using O2 as the electron acceptor, indicating that ChpA does not supply the multi-copper iron(II) oxidase with copper.

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Effects of iron overload and hepatitis C virus positivity in determining progression of liver fibrosis in thalassemia following bone marrow transplantation

Blood ◽

10.1182/blood.v100.1.17 ◽

2002 ◽

Vol 100 (1) ◽

pp. 17-21 ◽

Cited By ~ 193

Author(s):

Emanuele Angelucci ◽

Pietro Muretto ◽

Antonio Nicolucci ◽

Donatella Baronciani ◽

Buket Erer ◽

...

Keyword(s):

Liver Fibrosis ◽

Iron Overload ◽

Iron Content ◽

Hazard Rate ◽

Iron Concentration ◽

Dry Weight ◽

Interquartile Range ◽

Hepatic Iron ◽

Fibrosis Progression

Abstract To identify the role of iron overload in the natural history of liver fibrosis, we reviewed serial hepatic biopsy specimens taken annually from patients cured of thalassemia major by bone marrow transplantation. The patients underwent transplantation between 1983 and 1989 and did not receive any chelation or antiviral therapy. Two hundred eleven patients (mean age, 8.7 ± 4 years) were evaluated for a median follow-up of 64 months (interquartile range, 43-98 months) by a median number of 5 (interquartile range, 3-6) biopsy samples per patient. Hepatic iron concentration was stratified by tertiles (lower, 0.5-5.6 mg/g; medium, 5.7-12.7 mg/g; upper, 12.8-40.6 mg/g dry weight). Forty-six (22%) patients showed signs of liver fibrosis progression; the median time to progression was 51 months (interquartile range, 36-83 months). In a multivariate Cox proportional hazard model, the risk for fibrosis progression correlated to medium hepatic iron content (hazard rate, 1.9; 95% confidence interval [CI], 0.74-5.0), high hepatic iron content (hazard rate, 8.7; 95% CI, 3.6-21.0) and hepatitis C virus (HCV) infection (hazard rate, 3.1; 95% CI, 1.5-6.5). A striking increase in the risk for progression was found in the presence of both risk factors. None of the HCV-negative patients with hepatic iron content lower than 16 mg/g dry weight showed fibrosis progression, whereas all the HCV-positive patients with hepatic iron concentration greater than 22 mg/g dry weight had fibrosis progression in a minimum follow-up of 4 years. Thus, iron overload and HCV infection are independent risk factors for liver fibrosis progression, and their concomitant presence results in a striking increase in risk.

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Magnetic Ressonance Imaging (MRI) in the Evaluation of Iron Overload in Patients with Beta Thalassaemia. The Brazilian National Program Preliminary Results.

Blood ◽

10.1182/blood.v106.11.3825.3825 ◽

2005 ◽

Vol 106 (11) ◽

pp. 3825-3825

Author(s):

Nelson Hamerschlak ◽

Laercio Rosemberg ◽

Alexandre Parma ◽

Fernanda F. Assir ◽

Frederico R. Moreira ◽

...

Keyword(s):

Iron Overload ◽

Ventricular Function ◽

Iron Content ◽

Chelation Therapy ◽

Iron Concentration ◽

Iron Chelation ◽

Inverse Correlation ◽

Liver Iron ◽

Liver Iron Content ◽

Cooperative Program

Abstract Magnetic Ressonance Imaging (MRI) using T2 star (T2*) tecnique appears to be a very useful method for monitoring iron overload and iron chelation therapy in thalassaemia. In Brazil, we have around 400 thalassaemic major patients all over the country. They were treated with hipertransfusion protocols and desferroxamine and/or deferiprone chelation. We developed a cooperative program with the Brazilian Thalassaemic Patients Association (ABRASTA) in order to developT2* tecnique in Brazil to submit brazilian patients to an annual iron overload monitoring process with MRI.. We performed the magnetic ressonance T2* using GE equipment (GE, Milwaukee USA), with validation to chemical estimation of iron in patients undergoing liver biopsy. Until now, 60 patients were scanned, median age=23,2 (12–54); gender: 18 male (30%) and 42 female (70%). The median ferritin levels were 2030 ng/ml (Q1=1466; Q3=3296). As other authors described before, there was a curvilinear inverse correlation between iron concentration by biopsy, liver T2*(r=0,92) and also there were a correlation with ferritin levels. We also correlated myocardial iron measured by T2* with ventricular function.. As miocardial iron increased, there was a progressive decline in ejection fraction and no significant correlation was found between miocardial T2* and the ferritin levels. Liver iron content can be predicted by ferritin levels. On the other hand, cardiac disfunction is the most important cause of mortality among thalassaemic patients. Since Miocardio iron content cannot be predicted from serum ferritin or liver iron, and ventricular function can only detect those with advance disease, intensification and combination of chelation therapy, guided by T2* MRI tecnique should reduce mortality from the reversible cardiomyopathy among thalassaemic patients.

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Ineffective Erythropoiesis in β-Thalassemia Is Characterized by Increased Iron Absorption Mediated by down Regulation of Hepcidin and up Regulation of Ferroportin.

Blood ◽

10.1182/blood.v108.11.1543.1543 ◽

2006 ◽

Vol 108 (11) ◽

pp. 1543-1543 ◽

Cited By ~ 1

Author(s):

Sara Gardenghi ◽

Maria Marongiu ◽

Pedro Ramos ◽

Ella Guy ◽

Laura Breda ◽

...

Keyword(s):

Iron Overload ◽

Iron Content ◽

Iron Absorption ◽

Hematological Parameters ◽

Iron Concentration ◽

Dry Weight ◽

Heme Iron ◽

Ineffective Erythropoiesis ◽

Transfusion Therapy ◽

Expression Levels

Abstract Progressive iron overload occurs in β-thalassemia as a result of increased gastrointestinal absorption. Our goal is to investigate the relationship between ineffective erythropoiesis (IE), iron-related genes and organ iron distribution in mice that exhibit levels of anemia consistent with thalassemia intermedia (th3/+) and major (th3/th3), as we described previously. The th3/th3 mice die in 8 weeks due to severe anemia but can be rescued by transfusion therapy. We analyzed up to 90 animals at 2, 5 and 12 months, as appropriate. We monitored various hematological parameters, tissue iron content and quantitative-PCR levels of Hamp, Fpn1, Smad4, Cebpa, Hfe, Tfr1 and other genes involved in iron metabolism in liver, spleen, kidney, heart and duodenum. At 2 months, th3/th3 mice had the highest total body iron content and highest degree of IE. The total iron was 53.6±21.0, 406.1±156.1, 657.7±40.3 μg in the spleen, and 107.5±35.7, 208.5±24.9 and 1298.7±427.5 μg in the liver of +/+, th3/+ and th3/th3, respectively (n≥5 per genotype). However, if the organ size was not taken in account, the iron concentration in the spleen of th3/+ was higher, in average, than that of th3/th3 mice (3.8±1.5 and 2.9±0.5 μg/mg), while in the liver was the opposite (0.6±0.1 and 5.1±2.0 μg/mg of dry weight, P<0.001). Heme and non-heme iron analyses provided similar results. Surprisingly, the distribution of iron within organs also differed. In th3/+ mice, the hepatic iron was almost exclusively located in Kupffer cells, whereas in th3/th3 mice in parenchymal cells. Our data suggest that Hamp is responsible for the increased iron absorption, being reduced to 20% and 70% in 2 month-old th3/+ and th3/th3 mice compared to +/+ animals (P<0.001). Hfe was reduced by 50% (P<0.05) in the liver of the animals that expressed low Hamp levels, indicating that Hfe could be directly responsible for Hamp regulation or share the same regulatory pathway. Low levels of Smad4 and Cebpa were observed only in the liver of mice with the lowest Hamp expression (P<0.05), indicating that these proteins might contribute to further decreased Hamp synthesis. In addition, while Tfr1 in th3/+ mice was 40% lower in the liver, it was up-regulated (400%) in th3/th3 mice (P<0.001), which may explain why iron is increased more in the liver of th3/th3 mice. In 5 and 12 month-old th3/+ mice, the surprising observation was the normal expression level of Hamp. However, in the duodenum, the Fpn1 RNA and protein levels were augmented (300%, P<0.001). In transfused th3/+ and th3/th3 animals, Hamp, Hfe, Cbpa and Smad4 expression levels were normalized or increased, while Tfr1 was down-regulated in both groups, which may explain the increased splenic iron deposition in these animals. Our data suggest that IE, together with the relative expression levels of Hamp and Tfr1, is largely responsible for the organ iron overload observed in young thalassemic mice. However, in older mice, it is the increase of Fpn1 levels in the duodenum that sustains iron accumulation, thus revealing a fundamental role of this iron transporter in the genesis of iron overload in β-thalassemia.

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Comparing the Value of Serum Ferritin, Transfusion History and Magnetic Resonance Imaging for the Prediction of Iron Overload In MDS and AML Patients Undergoing Allogeneic Stem Cell Transplantation.

Blood ◽

10.1182/blood.v116.21.3493.3493 ◽

2010 ◽

Vol 116 (21) ◽

pp. 3493-3493

Author(s):

Martin Wermke ◽

Jan Moritz Middeke ◽

Nona Shayegi ◽

Verena Plodeck ◽

Michael Laniado ◽

...

Keyword(s):

Iron Overload ◽

Serum Ferritin ◽

Iron Content ◽

Iron Concentration ◽

Transferrin Saturation ◽

Resonance Imaging ◽

Liver Iron Concentration ◽

Liver Iron ◽

Liver Iron Content ◽

Transfusion History

Abstract Abstract 3493 An increased risk for GvHD, infections and liver toxicity after transplant has been attributed to iron overload (defined by serum ferritin) of MDS and AML patients prior to allogeneic hematopoietic stem cell transplantation (allo-HSCT). Nevertheless, the reason for this observation is not very well defined. Consequently, there is a debate whether to use iron chelators in these patients prior to allo-HSCT. In fact, serum ferritin levels and transfusion history are commonly used to guide iron depletion strategies. Both parameters may inadequately reflect body iron stores in MDS and AML patients prior to allo-HSCT. Recently, quantitative magnetic resonance imaging (MRI) was introduced as a tool for direct measurement of liver iron. We therefore aimed at evaluating the accurateness of different strategies for determining iron overload in MDS and AML patients prior to allo-HSCT. Serologic parameters of iron overload (ferritin, iron, transferrin, transferrin saturation, soluble transferrin receptor) and transfusion history were obtained prospectively in MDS or AML patients prior to allo-SCT. In parallel, liver iron content was measured by MRI according to the method described by Gandon (Lancet 2004) and Rose (Eur J Haematol 2006), respectively. A total of 20 AML and 9 MDS patients (median age 59 years, range: 23–74 years) undergoing allo-HSCT have been evaluated so far. The median ferritin concentration was 2237 μg/l (range 572–6594 μg/l) and patients had received a median of 20 transfusions (range 6–127) before transplantation. Serum ferritin was not significantly correlated with transfusion burden (t = 0.207, p = 0.119) but as expected with the concentration of C-reactive protein (t = 0.385, p = 0.003). Median liver iron concentration measured by MRI was 150 μmol/g (range 40–300 μmol/g, normal: < 36 μmol/g). A weak but significant correlation was found between liver iron concentration and ferritin (t = 0.354; p = 0.008). The strength of the correlation was diminished by the influence of 5 outliers with high ferritin concentrations but rather low liver iron content (Figure 1). The same applied to transfusion history which was also only weakly associated with liver iron content (t = 0.365; p = 0.007). Levels of transferrin, transferrin saturation, total iron and soluble transferrin receptor did not predict for liver iron concentration. Our data suggest that serum ferritin or transfusion history cannot be regarded as robust surrogates for the actual iron overload in MDS or AML patients. Therefore we advocate caution when using one of these parameters as the only trigger for chelation therapy or as a risk-factor to predict outcome after allo-HSCT. Figure 1. Correlation of Liver iron content with Ferritin. Figure 1. Correlation of Liver iron content with Ferritin. Disclosures: No relevant conflicts of interest to declare.

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In-Accuracy Of Bone Density Measurements By DXA In Patients With Hemoglobinopathies and Iron Overload

Blood ◽

10.1182/blood.v122.21.966.966 ◽

2013 ◽

Vol 122 (21) ◽

pp. 966-966

Author(s):

Haven M. Allard ◽

Marcela G. Weyhmiller ◽

Ashutosh Lal ◽

Ellen B. Fung

Keyword(s):

Lumbar Spine ◽

Iron Content ◽

Iron Concentration ◽

Lumbar Vertebrae ◽

Healthy Controls ◽

Z Score ◽

Liver Iron Concentration ◽

Liver Iron ◽

Liver Iron Content ◽

Z Scores

Abstract Introduction When monitoring bone health in patients with hemoglobinapathies, it is unknown if iron in surrounding tissues can lead to inaccuracies in the 2-dimensional assessment by Dual Energy X-ray Absorptiometry (DXA). Objective The aims of this study were: 1) to determine if the accuracy of lumbar spine assessment by DXA is affected by high liver iron concentration in patients with Sickle Cell Disease (SCD) or Thalassemia (Thal), 2) to test the effect of high tissue iron on vertebral Z-scores using phantoms, 3) to explore the ability to account for potential high-iron content effects when performing DXA examinations. Methods This study consisted of a retrospective chart review of data collected by the Children’s Hospital & Research Center Oakland, Bone Density Clinic and Iron Measurement Program. Data from both DXA and Super Conducting Quantum Interference Device (SQUID) examinations collected between 2002 and 2013 from were abstracted. Only those patients with a diagnosis of SCD or Thal, who had a DXA and SQUID measurement within the same year were divided into an iron overload group (liver iron concentration (LIC) >3,000 µg Fe/g wet) and low iron (LIC <500 µg Fe/g wet) group. These patients were compared with healthy controls of which only 13 had both DXA and SQUID tests, 34 had DXA only. The 34 healthy controls without a SQUID test were included because it was assumed, based on their health screen that their liver-iron content would not interfere with DXA. In order to explore aim 1, a lumbar spine scan, by DXA, of each subject was re-analyzed to compare the derived areal bone mineral density (aBMD) Z-scores of lumbar vertebrae that are covered by the liver (presumed L1 or L1/L2) with the Z-scores of the lumbar vertebrae not covered by the liver (L3/L4). To explore aim 2, phantoms were designed to mimic the geometry of iron loaded tissues in order to explore the contribution of iron in specific tissues on the accuracy of DXA assessments. Phantoms were constructed using KNOX® brand gelatin and iron(II) sulfate heptahydrate and had concentrations ranging from 3,000 to 7,000 ug Fe/g gelatin. The iron-loaded phantoms were positioned obtusely overlying L1/L2 of the DXA daily quality control phantom to mimic the position of the liver. All data were analyzed by STATA ver.9.2 and were considered significant with a p<0.05. Results Data from 102 total visits abstracted from 88 subjects [19 SCD (13 F), 24 Thal (12 F), age: 30.1 ± 11.9 years, mean ± SD], and 45 healthy controls (24 F, age: 25.4 ± 11.0 yrs) were analyzed. The SCD and Thal group had an average LIC by SQUID of 4651 ± 2079 µg Fe/g wet tissue and serum ferritin of 5408±2706 ng/mL; while the healthy controls, with both a DXA and a SQUID (n=17), had an average LIC of 251±144. Average aBMD Z-score of the lumbar spine L1-L4 in the Thal group was -2.0 ± 1.1 , the SCD was -2.0 ± 1.6 and the healthy controls: -0.3 ± 0.9. However, when individual vertebrae are analyzed separately, a significant difference was observed between the lumbar spine L1 BMD Z-scores compared to the combined means of L3/L4 Z-scores in the iron loaded population (Table 1). The discrepancy was even greater in subjects with LIC >5000 ug/g wet tissue. These findings were reproduced using heavily iron loaded phantoms. Conclusions Initial results for this study show that there is a relationship between liver iron content and lumbar spine aBMD Z-scores when evaluated by DXA. The BMD Z-score for L1 appears to be more significantly affected by the liver iron content then L2, which was unanticipated. When evaluating patients with liver iron content >3,000 ug/g wet tissue, it is important to consider the effects of iron contribution from the liver on the DXA spine scans and delete L1 and/or L2 from the total Z-score prior to making an interpretation. Failing to do so may under diagnose low bone mass in this at risk patient population. Disclosures: No relevant conflicts of interest to declare.

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Combination of Tmprss6-ASO and the Iron Chelator Deferiprone Improves Erythropoiesis and Reduces Iron Overload in a Mouse Model of Beta-Thalassemia

Blood ◽

10.1182/blood.v124.21.4024.4024 ◽

2014 ◽

Vol 124 (21) ◽

pp. 4024-4024

Author(s):

Carla Casu ◽

Mariam Aghajan ◽

Rea Oikonomidau ◽

Shuling Guo ◽

Brett P. Monia ◽

...

Keyword(s):

Iron Content ◽

Research Funding ◽

Serum Iron ◽

Iron Absorption ◽

Iron Concentration ◽

Iron Chelation ◽

Iron Chelator ◽

Liver Iron ◽

Hepcidin Expression ◽

Liver Iron Content

Abstract Patients affected by non-transfusion dependent thalassemia (NTDT) do not require chronic blood transfusion for survival. However, transfusion-independence in such patients is not without side effects. Ineffective erythropoiesis (IE), the hallmark of disease, leads to a variety of serious clinical morbidities. In NTDT the master regulator of iron homeostasis, hepcidin, is chronically repressed. Consequently, patients absorb abnormally high levels of iron, which eventually requires iron chelation to prevent the clinical sequelaes associated with iron overload. It has been shown that in mice affected by NTDT (Hbbth3/+), a second-generation antisense oligonucleotide (Tmprss6-ASO) can reduce expression of transmembrane serine protease Tmprss6, the major suppressor of hepcidin expression. This leads to reduction of hemichrome formation in erythroid cells, amelioration of IE and splenomegaly, and increased hemoglobin levels (Guo et al, JCI, 2013). Now we propose the use of Tmprss6-ASO in combination with iron chelators for the treatment of NTDT using Hbbth3/+ mice as a preclinical model. Our hypothesis is that use of chelators will benefit from the positive effect of Tmprss6-ASO on erythropoiesis and iron absorption, further ameliorating organ iron content. To this end, Hbbth3/+ animals were treated with Tmprss6-ASO at 100 mg/kg/week for 6 weeks with or without the iron chelator deferiprone (DFP) at a dose of 1.25 mg/ml. Additional animals were treated with DFP alone. We fed the animals with a commercial or physiological diet, containing 200 or 35 ppm of iron, respectively. We did not observe major differences in the treated animals fed the commercial or physiological iron diet and, for this reason, the data were combined for simplicity. Administration of DFP alone was successful in decreasing organ iron content. Compared to untreated Hbbth3/+ animals, we observed a reduction of 30% and 33% in the liver and spleen, respectively, and no change in the kidney. However, erythropoiesis was not improved (looking at IE, splenomegaly, RBC production and total Hb levels). This was associated with increased serum iron levels (+25%). In Tmprss6-ASO treated Hbbth3/+ animals, we observed an improvement in liver iron content (36% reduction), amelioration of IE, and increased RBC and Hb synthesis (~2 g/dL). Compared to treatment with Tmprss6-ASO alone, combination of DFP with Tmprss6-ASO achieved the same level of suppression of Tmprss6 in the liver (~90%) and reduction of serum iron parameters. This was associated with improvement of IE, decreased reticulocyte counts and splenomegaly, and increased RBC and Hb synthesis (~2 g/dL). While we observed that both Tmprss6-ASO and DFP separately reduced liver iron content to the same extent (~30-36%), combination treatment further reduced iron concentrations in the liver and kidney (69% and 19%, respectively), with no changes in the spleen. Additional analyses are in progress to evaluate the amount of hepcidin in serum as well as expression of erythroferrone, the erythroid regulator of hepcidin. Our first conclusion is that administration of an iron chelator alone is not sufficient to improve erythropoiesis despite that organ iron content is reduced. We speculate that when iron is removed from the liver, hepcidin expression becomes more susceptible to the suppressive effect of IE rather than the enhancing effect of reduced liver organ iron concentration. In addition, the combined effect of iron mobilized from organs and unchanged (or even augmented) iron absorption leads to increased serum iron concentration. As we have shown previously, amelioration of IE in this model requires decreased erythroid iron intake and hemichrome formation. Therefore, iron chelation alone is likely insufficient to improve erythropoiesis. Additional experiments are in progress to further elucidate this mechanism. Our second conclusion is that use of Tmprss6-ASO together with DFP combines the best effects of these two drugs, in particular on erythropoiesis and organ iron content. In animals that received the combined treatment, kidney and liver iron concentrations were further decreased compared to the single treatments. This indicates that Tmprss6-ASO might be extremely helpful in the treatment of NTDT and it could further improve iron related-chelation therapies. Disclosures Casu: Merganser Biotech LLC: Employment; Isis Pharmaceuticals, Inc.: Employment. Aghajan:Isis Pharmaceuticals, Inc.: Employment. Guo:Isis Pharmaceuticals, Inc.: Employment. Monia:Isis Pharmaceuticals, Inc.: Employment. Rivella:bayer: Consultancy, Research Funding; isis Pharmaceuticals, Inc.: Consultancy, Research Funding; merganser Biotech LLC: Consultancy, Research Funding, Stock options , Stock options Other.

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On ammonium ferric citrate as sensitiser for carbon printing

The Imaging Science Journal ◽

10.1179/136821910x12850731586346 ◽

2010 ◽

Vol 58 (6) ◽

pp. 301-307

Author(s):

H Bjørnga˚rd ◽

H Kobayashi

Keyword(s):

Ferric Citrate ◽

Ammonium Ferric Citrate

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The iron content in organs of free ranging European bison from the Białowieża herd / Zawartość żelaza w tkankach żubra ze stada białowieskiego

Annals of Animal Science ◽

10.2478/aoas-2013-0015 ◽

2013 ◽

Vol 13 (2) ◽

pp. 357-364 ◽

Cited By ~ 1

Author(s):

Tadeusz Kośla ◽

Michał Skibniewski ◽

Ewa Skibniewska ◽

Grażyna Urbańska-Słomka

Keyword(s):

Iron Content ◽

Dry Matter ◽

Iron Status ◽

Iron Concentration ◽

European Bison ◽

Fresh Tissue ◽

Significant Difference ◽

Males And Females ◽

Free Ranging ◽

Białowieża Primeval Forest

Abstract The aim of the study was to determine iron status in chosen organs of the European bison free ranging in Białowieża Primeval Forest. The material for analyses was obtained from animals eliminated during annual selection. Segments of liver, kidney, muscle, rib, and hoof were collected. Animals were divided depending on gender (males and females) and age (calves up to 1 year and animals older than 2 years). Mean iron concentration in liver was 263.59 mg ∙ kg-1 fresh tissue. The iron content was significantly higher in the group of animals older than 2 years (P≤0.05). The average content of iron in kidneys amounted to 156.70 mg ∙ kg-1 fresh tissue. The average iron content in muscles amounted to 79.95 mg ∙ kg-1 fresh tissue. Similarly to the liver samples a statistically significant difference (P≤0.05) was demonstrated depending on age. The average iron content in ribs and in the horn of the hoof wall of all European bison amounted to 38.90 mg ∙ kg-1 fresh tissue and 47.87 mg ∙ kg-1 dry matter, respectively. No statistically significant differences in the iron content were observed depending on gender.

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