View clinical trials related to Anemia.
Filter by:Background: Fanconi anemia is a genetic disease. Some people with it have reduced blood cell counts. This means their bone marrow no longer works properly. These people may need blood transfusions for anemia (low red blood cells) or low platelet counts or bleeding. Researchers want to see if a new drug will help people with this disease. Objective: To find out if a new drug, eltrombopag, is effective in people with Fanconi anemia. To know how long the drug needs to be given to improve blood counts. Eligibility: People at least 6 years old with Fanconi anemia with reduced blood cell counts. Design: Participants will be screened with blood and urine tests. They will repeat this before starting to take the study drug. Participants will take eltrombopag pills by mouth once a day for 24 weeks. They will be monitored closely for side effects. Participants will have blood tests every 2 weeks while on eltrombopag. Participants will visit NIH 3 months and 6 months after starting eltrombopag. At these visits, participants will: Answer questions about their medical history, how they are feeling, and their quality of life Have a physical exam Have blood and urine tests Have a bone marrow sample taken by needle from the hip. The area will be numbed. If participants blood cell counts improve, they might join the extended access part of the study. They will continue taking eltrombopag for 3 years and sign a different consent. After 24 weeks of treatment, if there is no improvement in blood cell counts, participants will stop taking eltrombopag. They will return for an optional follow-up visit that repeats the study visits....
130 pregnant women with Iron deficiency anemia, in the 2nd trimester (microcytic hypochromic anemia, hemoglobin range from 9-10.5g/dl, serum ferritin less than 12 ng/ml), from the outpatient clinics in the Obstetrics and Gynecology Department, in Ain Shams University Hospital, Cairo, Egypt, will be enrolled and distributed into one of 2 groups by a computer generated random number table. Each of the 2 groups will receive 2 medication for 2 months with specific instruction to increase iron absorption. One group named L will receive powders of bovine lactoferrin and tablets of placebo form, the 2nd named F will receive ferrous sulphate tablet and placebo in powder form. Hemoglobin concentration, packed-cell volume (PCV) , mean cell volume (MCV), mean corpuscular hemoglobin (MCH), mean cell hemoglobin concentration (MCHC), Serum ferritin will be done at the start and the end of the treatment period.
The objective of the study is to assess the acceptability, feasibility, and barriers to Lucky Iron Fishâ„¢ (LIF) utilization among families with young children in a Latin American community with a high prevalence of iron deficiency and iron-deficiency anemia.
This is a Phase 2, multicenter, open-label study to evaluate the efficacy and safety of luspatercept in subjects with MPN-associated myelofibrosis and anemia with and without RBC-transfusion dependence. The study is divided into a Screening Period, a Treatment Period (consisting of a Primary Phase, a Day 169 Disease Response Assessment, and an Extension Phase), followed by a Posttreatment Follow-up Period.
The fibroblast growth factor-23-bone-kidney axis is part of newly discovered biological systems linking bone to other organ functions through a complex endocrine network that is integrated with the parathormone/vitamin D axis and which plays an equally important role in health and disease . Most of the known physiological function of fibroblast growth factor 23 to regulate mineral metabolism can be accounted for by actions of this hormone on the kidney.In a recent experimental study, fibroblast growth factor-23 was shown to cause pathological hypertrophy in rat cardiomyocytes by "calcineurin-nuclear factor of activated T cells" and treatment with fibroblast growth factor -blockers reduced left ventricular hypertrophy in experimental models of chronic renal failure.The current hypothesis is that, in healthy individuals, iron deficiency stimulates increased production of fibroblast growth factor23. At the same time, iron is thought to be the cofactor of enzymes taking part in the degradation of intact fibroblast growth factor-23 and thought to have a role in the excretion of degraded FGF-23 parts .Studies speculated that Angiotensin Converting Enzyme inhibitors may exert their anti-proteinuria effects at least in part by reducing serum fibroblast growth factor-23 levels although it is difficult from the results of this study to understand which comes first and brings about the other; decrease in proteinuria or fibroblast growth factor-23. Available evidence points to the deleterious effects of increased fibroblast growth factor-23 level in proteinuria, but the precise molecular mechanism still remains to be explored. An intricate and close association exists among parathormone, phosphorus, active vitamin D with FGF23, but the independent role of the latter on proteinuria is the least explored. Elaborately conducted studies that control effects of confounding factors adequately are needed to demonstrate the independent pathogenic role of FGF23.
Research has suggested that children with sufficient vitamin D levels undergoing hematopoietic stem cell transplant (HSCT) have improved outcomes, including lower incidences of infection and graft-versus-host disease (GVHD), as well as overall improved survival. However, supplementation in children undergoing HSCT has shown to be a challenge using standard or aggressive supplementation strategies. The primary objective of this study is to determine the safety and efficacy of a single, high dose oral vitamin D (Stoss Therapy) at the start of transplant followed by maintenance supplementation in children undergoing HSCT.
It has long been recognized that the positive effects of vaccination on childhood mortality cannot be solely attributed to a decline in the disease targeted by the vaccine. These so-called non-specific effects of vaccination have so far mostly been linked to mortality. However, it has been suggested that non-specific effects may also effect morbidity and nutritional status. This study aims to further explore the correlation between vaccination, susceptibility to infectious diseases (particularly malaria and bacterial infections), nutritional status and immunity. With this prospective cross sectional study among healthy individuals in rural west-Africa we aim to address several research questions at the same time. This study will assess the influence of (time-point of) vaccination on morbidity, mortality and immune status among healthy individuals in a rural sub-Saharan African setting. Secondly, to explore the prevalence of subclinical malaria, iron deficiency anemia, sickle cell anemia and thallasemia among a healthy rural sub-Saharan African population. And finally to assess normal hemocytometry values among a healthy rural sub-Saharan African population.
Iron deficiency anemia is the leading cause of anemia during pregnancy, which can still reach 10 to 20% of pregnant women in developed countries, with potentially serious consequences for the child. Systematic iron supplementation remains controversial. This study aims to identify in the first trimester of pregnancy clinical and biological predictive factors for the occurrence of iron deficiency anemia in the third trimester of pregnancy.
The global burden of maternal morbidity and mortality attributable to anemia is staggering, and this is especially true in low-resource settings. A recent review suggests 42% of pregnant women have anemia worldwide (1993-2005) with the vast majority of anemic women (90%) residing in Africa or Asia1; and in Asia, anemia was the second highest cause of maternal mortality2. Anemia was diagnosed in almost one third to one half of women presenting to the Shoklo Malaria Research Unit (SMRU) clinics on the Thai-Myanmar border for antenatal care (ANC) in a 2008 survey3, and anemia at first antenatal visit was associated with a two-fold increase in maternal mortality in this population4. Studies have also shown an association between anemia and small for gestational age infants, preterm delivery, infant and childhood anemia and developmental delays5. The anemia in pregnant women presenting to SMRU clinics is multifactorial, as hemoglobinopathies, Glucose-6-dehydrogenase (G6PD) deficiency, iron, folic acid and B12 deficiency, helminth infection, and malaria are all prevalent in this rural population. Though all of these pathologies can cause anemia, they require different and sometimes conflicting treatment and prevention strategies, interacting in a complex web of causes and effects. Iron supplementation is the mainstay of most anemia control programs, but some women with hemoglobinopathies suffer from potentially fatal iron overload6. Iron supplementation has also been associated with increased risk of malaria7. Some helminth infections are associated with increased rates of anemia and malaria, but others may be protective8. Malaria and G6PD deficiency have complex effects on one another, and some malaria treatments can cause acute and life-threatening hemolysis in G6PD deficient individuals9. Given the high prevalence and diverse causes of anemia in this population, and its potentially dire effects on maternal and infant health and survival, SMRU implemented increased clinical testing for pregnant women in 2012 to inform clinical care at the individual level. Further analysis of these data is urgently needed to improve care on a population scale. We propose to review existing data from ANC records to determine the causes and effects of anemia in this population, and use this information to improve treatment and prevention guidelines. Results would be integrated rapidly into local practice with the potential to have profound impacts on maternal and child health in this region.
Background: Severe aplastic anemia (SAA) and myelodysplastic syndrome (MDS) are bone marrow diseases. People with these diseases usually need a bone marrow transplant. Researchers are testing ways to make stem cell transplant safer and more effective. Objective: To test if treating people with SAA or MDS with a co-infusion of blood stem cells from a family member and cord blood stem cells from an unrelated donor is safe and effective. Eligibility: Recipients ages 4-60 with SAA or MDS Donors ages 4-75 Design: Recipients will be screened with: - Blood, lung, and heart tests - Bone marrow biopsy - CT scan Recipients will have an IV line placed into a vein in the neck. Starting 11 days before the transplant they will have several chemotherapy infusions and 1 30-minute radiation dose. Recipients will get the donor cells through the IV line. They will stay in the hospital 3-4 weeks. After discharge, they will have visits: - First 3-4 months: 1-2 times weekly - Then every 6 months for 5 years<TAB> Donors will be screened with: - Physical exam - Medical history - Blood tests Donors veins will be checked for suitability for stem cell collection. They may need an IV line to be placed in a thigh vein. Donors will get filgrastim injections daily for 5-7 days. On the last day, they will have apheresis: Blood drawn from one arm or leg runs through a machine and into the other arm or leg. This may be repeated 2 days or 2-4 weeks later.