Reversal of cardiac iron loading and dysfunction in thalassemic mice by curcuminoids.

Non-transferrin bound iron (NTBI) is found in plasma of ß-thalassemia patients and causes oxidative tissue damage. Cardiac siderosis and complications are the secondary cause of death in ß-thalassemia major patients. Desferrioxamine (DFO), deferiprone (DFP) and deferasirox (DFX) are promising chelators used to get negative iron balance and improve life quality. DFP has been shown to remove myocardial iron effectively. Curcuminoids (CUR) can chelate plasma NTBI, inhibit lipid peroxidation and alleviate cardiac autonomic imbalance. Effects of CUR on cardiac iron deposition and function were investigated in iron-loaded mice. Wild type ((mu)ß(+/+) WT) and heterozygous ß-knockout ((mu)ß(th-3/+) BKO) mice (C57BL/6) were fed with ferrocene-supplemented diet (Fe diet) and coincidently intervened with CUR and DFP for 2 months. Concentrations of plasma NTBI and malondialdehyde (MDA) were measured using HPLC techniques. Heart iron concentration was determined based on atomic absorption spectrophotometry and Perl's staining methods. Short-term electrocardiogram (ECG) was recorded with AD Instruments Power Lab, and heart rate variability (HRV) was evaluated using MATLAB 7.0 program. Fe diet increased levels of NTBI and MDA in plasma, nonheme iron and iron deposit in heart tissue significantly, and depressed the HRV, which the levels were higher in the BKO mice than the WT mice. CUR and DFP treatments lowered plasma NTBI as well as MDA concentrations (p <0.05), heart iron accumulation effectively, and also improved the HRV in the treated mice. The results imply that CUR would be effective in decreasing plasma NTBI and myocardial iron, alleviating lipid peroxidation and improving cardiac function in iron-loaded thalassemic mice.

Adiposity in women and children from transition countries predicts decreased iron absorption, iron deficiency and a reduced response to iron fortification.

BACKGROUND: Overweight is increasing in transition countries, while iron deficiency remains common. In industrialized countries, greater adiposity increases risk of iron deficiency. Higher hepcidin levels in obesity may reduce dietary iron absorption. Therefore, we investigated the association between body mass index (BMI) and iron absorption, iron status and the response to iron fortification in populations from three transition countries (Thailand, Morocco and India). METHODS: In Thai women (n=92), we examined the relationship between BMI and iron absorption from a reference meal containing approximately 4 mg of isotopically labeled fortification iron. We analyzed data from baseline (n=1688) and intervention (n=727) studies in children in Morocco and India to look for associations between BMI Z-scores and baseline hemoglobin, serum ferritin and transferrin receptor, whole blood zinc protoporphyrin and body iron stores, and changes in these measures after provision of iron. RESULTS: In the Thai women, 20% were iron deficient and 22% were overweight. Independent of iron status, a higher BMI Z-score was associated with decreased iron absorption (P=0.030). In the Indian and Moroccan children, 42% were iron deficient and 6.3% were overweight. A higher BMI Z-score predicted poorer iron status at baseline (P<0.001) and less improvement in iron status during the interventions (P<0.001). CONCLUSIONS: Adiposity in young women predicts lower iron absorption, and pediatric adiposity predicts iron deficiency and a reduced response to iron fortification. These data suggest the current surge in overweight in transition countries may impair efforts to control iron deficiency in these target groups. Interactions of the 'double burden' of malnutrition during the nutrition transition may have adverse consequences.

Risk of zinc, iodine and other micronutrient deficiencies among school children in North East Thailand.

INTRODUCTION: Micronutrient deficiencies during childhood can contribute to impairments in growth, immune competence, and mental and physical development, and the coexistence of several such deficiencies can adversely affect the efficacy of single micronutrient interventions. OBJECTIVE: To assess the prevalence of zinc and iodine deficiency and their interrelationships with vitamin A deficiency and anemia and associations with socio-economic status, hemoglobin type, and anthropometry in a cross-sectional study. SETTING: A total of 10 primary schools in North East Thailand. METHODS: Non-fasting venipuncture blood samples and casual urine samples were collected from 567 children aged 6-13 years. Anthropometric measures and serum zinc, albumin, C-reactive protein and urinary iodine, are reported here and integrated with published data on vitamin A, anemia, and socio-economic status. RESULTS: Of the children, 57% had low serum zinc and 83% had urinary iodine levels below the 100 microg/l cutoff. Suboptimal serum zinc and urinary iodine concentrations may result from low intakes of zinc and iodized salt. Significant risk factors for low serum zinc were serum retinol <1.05 micromol/l and being male. Those for urinary iodine <100 microg/l were height-for-age score>median and being female. For serum retinol <1.05 micromol/l, risk factors were low hemoglobin, low serum zinc, and <9 years, and for low hemoglobin indicative of anemia risk factors were <9 years, AE hemoglobinopathy, and serum retinol <1.05 micromol/l. Of the children, 60% were at risk of two or more coexisting micronutrient deficiencies, most commonly suboptimal urinary iodine and low serum zinc. CONCLUSION: The findings emphasize the need for multimicronutrient interventions in North East Thailand.