Combine iron Chelation therapy ameliorates decline of iron on iron loaded Zebrafish embryo
التاريخ
2017-03-27المؤلف
Ibrahim, MustafaYounes, Nadin Nagy
Baji, Missbah Hanif
Shraim, Amjad Mahmoud Ahmad
Nasrellah, Gheyath
البيانات الوصفية
عرض كامل للتسجيلةالملخص
Thalassemia is the most common genetically inherited blood disorder in the world arisen
from defect in hemoglobin production, resulting in ineffective erythropoiesis and rapid destruction
of RBC in the periphery that leads to severe anemia. While transfusion therapy corrects the anemia,
it gives rise to secondary iron overload. Finally, recurrent blood exposure can induce
alloimmunization to erythrocytes antigens, leading to difficulty in finding compatible blood.
Current iron chelation therapy using Desferal® (DFO) is challenging due to its short vascular
half-life, frequency of injections, toxicity and expense. To address these issues new iron
chelating agents and improved iron chelation therapy we propose using combination of iron
chelators.
To test the utility of different chelators, in vivo studies performed on iron loaded zebrafish
embryos (100 μM Fe3+; ferric ammonium citrate (FAC); 3dpf -6dpf). Iron chelation studies utilized
either single or combinational treatment with Deferiprone (L1) or DFO for 7dpf-10dpf on zebrafish
iron loaded model. The efficacy of treatment was assessed by total iron with ICP-MS, clinical
chemistry analyzer spectrophotometry and with Perl's iron stain microscopy. Iron treatment alone
resulted in a significant increase in total iron, histochemical iron staining, also resulted in an
increase in stainable iron. Treatment with iron chelators either L1 or DFO alone demonstrated
modestly decreased total iron and iron staining. Importantly, combination therapy (L1+ DFO),
resulted in an additive effect in FAC-driven iron levels after 96 hours treatment. As expected,
iron chelators (e.g., 100 μM DFO or L1) reduced the level of iron.
These studies confirm that cellular iron utilization requires one chelator to have the properties
to enter cells, chelate intracellular iron and subsequently that go to another chelator with higher
affinity to iron binding. The development of improved combination iron chelation therapy using nigh
and low molecular weight biocompatible iron chelators may provide better therapeutic value (less
toxic and less frequent administration) in developing nations. These biocompatible iron chelators
can improve shelf life of blood products to minimize oxidative damage due to iron-mediated
oxidation. Consequent to this, iron mediated pathology to patients diminished resulting in less
cost to already strained public health
budgets in many poor countries.
معرّف المصادر الموحد
http://onlinelibrary.wiley.com/doi/10.1111/bjh.14613/fullالمجموعات
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