Transfusion-dependent Thalassemia
Conditions
Keywords
Transfusion Dependent Thalassemia, Hydroxyurea, Thalidomide
Brief summary
The goal of this clinical trial is to find out the efficacy of combined Hydroxyurea and thalidomide transfusion dependent thalassemia patients. The main objectives are to compare the level of Hb, Transfusion interval, serum ferritin level before & after treatment between single and combination of thalidomide and HU. Researcher will compare the effectiveness of combined hydroxyurea and thalidomide and hydroxyurea and thalidomide alone. Participants will be divided in three groups: Group I: will take combination of HU and Thalidomide. Group II: Will take HU alone and Group III: Will take Thalidomide alone and outcome will be recorded.
Detailed description
Thalassemia is a monogenic hematological disorder caused as a result of defect in synthesis of globin chains of hemoglobin. It causes ineffective erythropoiesis & lysis of red blood cells due to relative excess of unaffected globin chain. Annually about 50,000 children with a severe form of thalassemia (β-thalassemia major and HbE β-thalassemia) born globally among which 26,000 patients are regular blood transfusion dependent. About 70-75% patients are found in southeast asia & eastern mediterranean region. Hematopoietic stem cell transplant (HSCT) is the only curative treatment option for homozygous thalassemia patients. Unfortunately its application is limited due to scarcity of HLA-matched donor, high cost , lack of specialized dedicated centers and risk of transplant related morbidity and mortality. Regular blood transfusion is an essential life saving supportive care to maintain growth and development in children with severe β-thalassemia. However, Long term blood transfusion causes iron overload with cardiac, hepatic and endocrine coomplications , spread transfusion transmitted infections and formation of antibody. These limitations have compelled researchers to search for novel therapeutic modalities. In recent years, induction of Fetal Hemoglobin (HbF) production pharmacologically is an promising treatment options for hemoglobinopathies. Different HbF inducing agents like Hydroxyurea (HU), Butyrate derivatives, Azacitidine, Decitabine, Tricostatin-A are shown to be effective in decreasing clinical severity and complications of TDT. HU induces a 2-9 fold increase in γ-globin gene and being used for decades in thalassemia treatment. But its utility is limited due to its mild and ill sustained therapeutic effect in HbF synthesis. Thalidomide, an immunomodulatory drug also shown to produce significant and persistent rise in Hb in few small studies and several case reports. It induces Gamma Globin gene expression by increasing reactive oxygen species-mediated p38 mitogen-activated protein kinase (MAPK) signaling and histone H4 acetylation. Recent studies with combination of HU and Thalidomide have shown promising results in treatment of Thalassemia patients. However, most of those studies are retrospective or single arm nonrandomized trials & The study population includes both adult and children age group. So the effectiveness of combination therapy of Thalidomide and HU needs to be established in children through randomized trials. So the goal of our study to evaluate the effectiveness of combination of Thalidomide and HU in comaprison to Thalisomide or HU alone in children with TDT through a three arm quasi randomized trial.
Interventions
Patients will get only Thalidomide
Patients will get only Hydroxyurea
Combination Of Thalidomide \& Hydroxyurea
Sponsors
Study design
Eligibility
Inclusion criteria
* Patients diagnosed as transfusion dependent thalassemia * Age ranged from 3-18 years * Blood transfusion more than 1 year. * no bleeding disorder
Exclusion criteria
* Active systemic co-morbidity, * Past personal or family history of thrombophilia, * Recent fracture or recent major surgery * Use of drugs that might affect Hb levels 15 days before enrollment
Design outcomes
Primary
| Measure | Time frame | Description |
|---|---|---|
| Change in Hb Level | 12 weeks after treatment initiation | Change in Hb gm/dl after 3 month |
| Change in Blood transfusion frequency | 12 weeks after treatment initiation | Change in Blood transfusion frequency after 3 month |
| Change in HbF | 12 weeks after treatment initiation | Change in Hb F after 3 month |
Secondary
| Measure | Time frame | Description |
|---|---|---|
| Adverse effect | 12 weeks from treatment initiation | Adverse effect of drugs |
| Change in Serum Ferritin level | 12 weeks after treatment initiation | Change in serum ferritin level after 3 months |
| Change in SGPT level | 12 weeks from treatment initiation | Change of serum ferritin after 3 months |
| Change in serum bilirubin level | 12 weeks after initiation of treatment | Change of Serum Bilirubin level after 3 months |
| Change of Serum Creatinine level | 12 weeks after treatment initiation | Change of Serum Creatinine after 3 months |
| Change of Serum LDH level | 12 weeks from treatment initiation | Change of LDH level after 3 months |
Countries
Bangladesh