181 Clinical Trials for Various Conditions
A phase II trial of a reduced intensity conditioned (RIC) allogeneic hematopoietic cell transplant (HCT) with post-transplant cyclophosphamide (PTCy) for idiopathic severe aplastic anemia (SAA), paroxysmal nocturnal hemoglobinuria (PNH), acquired pure red cell aplasia (aPRCA), or acquired amegakaryocytic thrombocytopenia (aAT) utilizing population pharmacokinetic (popPK)-guided individual dosing of pre-transplant conditioning and differential dosing of low dose total body irradiation based on age, presence of myelodysplasia and/or clonal hematopoiesis.
This study is a prospective, single center phase II clinical trial in which patients with Severe Aplastic Anemia (SAA) ) will receive a haploidentical transplantation. The purpose of this study is to learn more about newer methods of transplanting blood forming cells donated by a family member that is not fully matched to the patient. This includes studying the effects of the chemotherapy, radiation, the transplanted cell product and additional white blood cell (lymphocyte) infusions on the patient's body, disease and overall survival. The primary objective is to assess the rate of engraftment at 30 days and overall survival (OS) and event free survival (EFS) at 1 year post-hematopoietic cell transplantation (HCT). Primary Objectives * To estimate the rate of engraftment at 30 days after TCR αβ+ T-cell-depleted graft infusion in patients receiving a single dose of post graft infusion cyclophosphamide. * To estimate the overall survival and event free survival at 1-year post transplantation. Secondary Objectives * To calculate the incidence of acute and chronic GVHD after HCT. * To calculate the rate of secondary graft rejection at 1-year post transplantation * To calculate the cumulative incidence of viral reactivation (CMV, EBV and adenovirus). * To describe the immune reconstitution after TCR αβ+ T-cell-depleted graft infusion at 1 month, 3 months, 6 months, 9 months, and 1 year. Exploratory Objectives * To longitudinally assess the phenotype and epigenetic profile of T-cells in SAA patients receiving HCT for SAA. * To assess the phenotype and epigenetic profile of T-cells in DLI administered to SAA patients post HCT. * To longitudinally assess CD8 T cell differentiation status in SAA patients using an epigenetic atlas of human CD8 T cell differentiation. * To examine the effector functions and proliferative capacity of CD8 T cells isolated from SAA patients before and after DLI. * Quantify donor derived Treg cells at different time points in patients received HCT. * Determine Treg activation status at different stages after HCT. * Are specific features of the DLI product associated with particular immune repertoire profiles post-transplant? * How does the diversity and functional profile of the DLI product alter the response to pathogens in the recipient? * Do baseline features of the recipient's innate and adaptive immune cells correlate with post-transplant immune repertoires and response profiles?
This study is a prospective, multicenter phase II study with patients receiving haploidentical transplantation for Severe Aplastic Anemia (SAA). The primary objective is to assess overall survival (OS) at 1 year post-hematopoietic stem cell transplantation (HSCT).
Our primary objective is to determine if it is feasible for previously untreated severe aplastic anemia (SAA) patients to be transplanted using non-myeloablative conditioning and post transplantation cyclophosphamide.
Severe aplastic anemia is a rare and serious form of bone marrow failure related to an immune-mediated mechanism that results in severe pancytopenia and high risk for infections and bleeding. Patients with matched sibling donors for transplantation have a 80-90% chance of survival; however, a response rate with just immunosuppression for those patients lacking suitable HLA-matched related siblings is only 60%. With immunosuppression, only 1/3 of patients are cured, 1/3 are dependent on long term immunosuppression, and the other 1/3 relapse or develop a clonal disorder. Recent studies have shown that using a haploidentical donor for transplantation has good response rates and significantly lower rates of acute and chronic GVHD.
Our primary objective is to determine if it is feasible for SAA patients to be transplanted using non-myeloablative conditioning and post transplantation cyclophosphamide with partially HLA-mismatched donors.
Patients with severe, refractory aplastic anemia have a severe, life threatening disease in their bone marrow. Refractory disease means that disease has come back or not responded after receiving one or more immunosuppressive treatments. High dose chemotherapy followed by bone marrow transplantation (BMT) has been used to treat blood diseases like aplastic anemia but complications from Graft vs Host disease (GVHD) and graft failure have limited the survival for those patients. Another study done here at Johns Hopkins has shown that in patients with other diseases (blood cancers) some immunosuppressive drugs given after the BMT has decreased how often patients had complications of GVHD and engraftment failure. This research is being done to find if this approach will help patients with aplastic anemia who have failed other treatments will have better outcomes.
Background: * Moderate aplastic anemia is a blood disease which may require frequent blood and platelet transfusions. Sometimes patients with this disease can be treated with immunosuppressive drugs. Not all patients respond and not all patients are suitable for this treatment. * Thrombopoietin (TPO) is a protein made by the body. The bone marrow needs TPO to produce platelets. TPO may also be able to stimulate bone marrow stem cells to produce red cells and white cells. However, TPO cannot be given by mouth. This has led researchers to develop the drug eltrombopag, which acts in the same way and can be given by mouth. Eltrombopag has been shown to safely increase platelet numbers in healthy volunteers and in patients with other chronic blood diseases, including severe aplastic anemia. Researchers are interested in looking at whether eltrombopag can be given to people with moderate aplastic anemia and significantly low blood cell counts. Objectives: - To evaluate the safety and effectiveness of eltrombopag in people with moderate aplastic anemia or patients with bone marrow failure and unilineage cytopenia who need treatment for significantly low blood cell counts. Eligibility: - People at least 2 years of age who have moderate aplastic anemia or bone marrow failure and unilineage cytopenia,and significantly low blood cell counts. Design: * Patients will be screened with a physical examination, medical history, blood tests, a bone marrow biopsy, and an eye exam. * Patients will receive eltrombopag by mouth once a day. * Patients will have weekly blood tests to monitor the effectiveness of the treatment and adjust the dose in response to possible side effects. * Patients may continue to take eltrombopag if their platelet count or hemoglobin increases, their requirement for platelet or blood transfusion decreases after 16 to 20 weeks of treatment, and there have been no serious side effects. Access to the drug will continue until the study is closed. Patients will be asked to return for a follow-up visit 6 months after the last dose of medication.
Background: * Stem cell transplants from related donors (allogenic stem cell transplants) can be used to treat individuals with certain kinds of severe blood diseases or cancers, such as severe anemia. Allogenic stem cell transplants encourage the growth of new bone marrow to replace that of the recipient. Because stem cell transplants can have serious complications, researchers are interested in developing new approaches to stem cell transplants that will reduce the likelihood of these complications. * By reducing the number of white blood cells included in the blood taken during the stem cell collection process, and replacing them with a smaller amount of white blood cells collected prior to stem cell donation, the stem cell transplant may be less likely to cause severe complications for the recipient. Researchers are investigating whether altering the stem cell transplant donation procedure in this manner will improve the likelihood of a successful stem cell transplant with fewer complications. Objectives: - To evaluate a new method of stem cell transplantation that may reduce the possibly of severe side effects or transplant rejection in the recipient. Eligibility: * Recipient: Individuals between 4 and 80 years of age who have been diagnosed with a blood disease that can be treated with allogenic stem cell transplants. * Donor: Individuals between 4 and 80 years of age who are related to the recipient and are eligible to donate blood. OR unrelated donors found through the National Marrow Donor Program. Design: * All participants will be screened with a physical examination and medical history. * DONORS: * Donors will undergo an initial apheresis procedure to donate white blood cells. * After the initial donation, donors will receive injections of filgrastim to release bone marrow cells into the blood. * After 5 days of filgrastim injections, donors will have apheresis again to donate stem cells that are present in the blood. * RECIPIENTS: * Recipients will provide an initial donation of white blood cells to be used for research purposes only. * From 7 days before the stem cell transplant, participants will be admitted to the inpatient unit of the National Institutes of Health Clinical Center and will receive regular doses of cyclophosphamide, fludarabine, and anti-thymocyte globulin to suppress their immune system and prepare for the transplant. * After the initial chemotherapy, participants will receive the donated white blood cells and stem cells as a single infusion. * After the stem cell and white blood cell transplant, participants will have regular doses of cyclosporine and methotrexate to prevent rejection of the donor cells. Participants will have three doses of methotrexate within the week after the transplant, but will continue to take cyclosporine for up to 4 months after the transplant. * Participants will remain in inpatient care for up to 1 month after the transplant, and will be followed with regular visits for up to 3 years with periodic visits thereafter to evaluate the success of the transplant and any side effects.
Primary Objectives: 1. To determine the feasibility and toxicity of employing purine-analog based conditioning for allogeneic donor stem cell transplantation in patients with severe aplastic anemia (AA). 2. To determine the engraftment kinetics and degree of chimerism that can be achieved with this strategy.
This clinical trial is studying how well giving cyclophosphamide together with anti-thymocyte globulin followed by methotrexate and cyclosporine works in preventing chronic graft-vs-host disease (GVHD) in patients with severe aplastic anemia undergoing donor bone marrow transplant. Giving low doses of chemotherapy, such as cyclophosphamide, before a donor bone marrow transplant helps stop the growth of abnormal cells. It also stops the patient's immune system from rejecting the donor's stem cells. The donated stem cells may replace the patient's immune system and help destroy any remaining abnormal cells. Sometimes the transplanted cells from a donor can also make an immune response against the body's normal cells. Giving anti-thymocyte globulin before and methotrexate and cyclosporine after transplant may stop this from happening
The purpose of this study is to evaluate the safety of the drug oxandrolone (a type of androgen steroid) in patients with Fanconi anemia (FA), and to determine if this drug can help in the treatment of bone marrow failure in these patients. Androgen steroids are male hormones that can stimulate the production of red blood cells (the cells which carry oxygen in the blood) and platelets (cells that help blood clot).
This study will test whether the immune-suppressing drug rituximab can increase blood counts and reduce the need for transfusions in patients with moderate aplastic anemia, pure red cell aplasia, or Diamond Blackfan anemia. These are rare and serious blood disorders in which the immune system turns against bone marrow cells, causing the bone marrow to stop producing red blood cells in patients with pure red cell aplasia and Diamond Blackfan anemia, and red blood cells, white blood cells and platelets in patients with aplastic anemia. Rituximab is a laboratory-made monoclonal antibody that recognizes and destroys white blood cells called lymphocytes that are responsible for destroying bone marrow cells in these diseases. The drug is currently approved by the Food and Drug Administration for treating patients with B-cell non-Hodgkin lymphoma, a disease of white blood cells.
Severe aplastic anemia (SAA) is a life-threatening bone marrow failure disorder characterized by pancytopenia and a hypocellular bone marrow. Allogeneic bone marrow transplantation and immunosuppressive treatment with anti-thymocyte globulin (ATG) and cyclosporine (CsA) have dramatically changed the natural course of this illness, with 5 year survival of 75% in patients undergoing either treatment. Since most patients are not suitable candidates for hematopoietic stem cell transplantation (HSCT) due to advanced age or lack of a histocompatible sibling, efforts at NHLBI have focused on improving immunosuppression treatment in order to improve response rates, survival, and to decrease relapse. In our experience of 122 patients treated at NHLBI with the combination of ATG and cyclosporine, one quarter to one third did not respond; about 50% of responders relapsed; and 5 year survival was correlated with the robustness in blood cell count improvement at 3 months (reticulocyte or platelet count greater than or equal to 50,000 /uL). Why some patients do not respond initially while others relapse is unclear. Autoreactive T cells may be resistant to the effect of ATG/CsA (nonresponders), while in others residual autoreactive T cells expand post-treatment leading to hematopoietic stem cell destruction and recurrent pancytopenia (relapse). Therefore, novel immunosuppressive regimens to increase response rates and hematologic recovery at 3 months and to decrease relapse rates are needed. An ongoing NHLBI trial, which is close to completing accrual, has added mycophenolate mofetil (MMF) for a total of 18 months to standard ATG + CsA in an attempt to reduce the relapse rate after cyclosporine is discontinued. Preliminary results have been disappointing, with no marked reduction in relapse among patients who received MMF. Sirolimus (rapamycin, Rapamune , RAPA) is a novel immunosuppressive agent, which acts synergistically with cyclosporine by blocking T cell activation through CsA-resistant pathways. The potentiation of the combination of CsA-RAPA has been established in vitro and in the clinical setting, mainly in islet cell and solid organ transplantation. The significant increase in response rate seen with the addition of CsA to ATG indicated that an inhibitory effect on T lymphocytes is important in blocking autoreactive T cells in aplastic anemia. The combination of CsA-RAPA may further block activated autoreactive T cells and therefore lead to improved response rates (and survival) and decreased relapse rates. This prospective randomized phase II study will investigate two different immunosuppressive regimens in patients with severe aplastic anemia who have not received prior immunosuppressive therapy. One arm will receive ATG + CsA in addition to sirolimus for 6 months, and the second arm will receive standard ATG + CsA for 6 months followed by a slow taper of CsA with a 25% dose reduction every 3 months for the subsequent 18 months. This trial will determine the effectiveness of sirolimus in patients with aplastic anemia as well as the role of a cyclosporine taper in preventing relapses. Primary endpoint will be no longer meeting criteria for severe aplastic anemia while secondary endpoints are relapse, robustness of hematologic recovery at 3 months, survival, clonal evolution to PNH, myelodysplasia and acute leukemia. 10/11/2005. The Sirolimus (Rapamune) arm of the trial was stopped for lack of efficacy. The study will continue as a single arm study to establish if slow taper of CsA prevents relapse rates after initial standard treatment with ATG followed by CsA for six months.
This study will collect samples of blood, stool, bone marrow, or other tissues from patients with hepatitis-associated aplastic anemia to investigate a possible association between exposure to viruses and the development of aplastic anemia in these patients. Cells from the samples obtained may be grown in the laboratory for future studies. Patients samples may be used to: * Study abnormalities that occur in hepatitis-associated aplastic anemia; * Test for various viruses; * Test immune function; * Measure factors related to the patients disease or diseases they may be at risk for; * Evaluate the effectiveness of current therapies, refine treatment approaches, and identify potential new therapies; * Identify possible measures for disease prevention; * Identify possible genetic factors associated with hepatitis-associated aplastic anemia. Patients 2 years of age and older with severe aplastic anemia that developed within 6 months of an episode of hepatitis may be eligible for this study. Participants will complete questionnaires and provide tissue samples as described below. Questionnaires All patients (or another respondent for the patient) will fill out a questionnaire including demographic information (age, gender, race, ethnic group, education level, state of residence), current symptoms, medications, medical history, and history of possible exposures to toxins or viruses. A second questionnaire, which includes questions related to mental health, sexual behavior, alcohol and drug use, is optional for participants age 21 and older. These questionnaires are designed to uncover features of hepatitis-associated aplastic anemia and possibly reveal a common cause of the disease. Sample Collections * Blood- will be collected at the time of the patient s initial evaluation or upon enrollment into the study and possibly periodically during the study. Blood will be drawn through a needle in an arm vein. * Bone marrow- may be collected as part of the patient s standard medical care or specifically for research purposes of this study. For this procedure, the skin over the hipbone and the outer surface of the bone itself are numbed with an injection of a local anesthesia. Then, a larger needle is inserted into the hipbone and marrow is drawn into a syringe. Marrow cells are suctioned two to six times during the 15-minute procedure. * Stool- will be provided by the patient. Liver- tissue may be biopsied as part of the patient s general medical care or for NIH patients, as part of their enrollment in a treatment protocol.
OBJECTIVES: I. Determine the effect of supplementation with donor T-cell depleted, CD34+ peripheral blood stem cells on durable engraftment and incidence of graft-versus-host disease in patients with aplastic anemia undergoing allogeneic bone marrow transplantation.
This study will examine the safety and effectiveness of a new drug combination for treating patients with severe aplastic anemia. Patients with aplastic anemia produce too few blood cells, causing fatigue, easy bruising and bleeding, and susceptibility to infections. In many cases, the very low blood counts result from an autoimmune process-that is, the patient's own immune system suppresses production of blood cells by the bone marrow. Although immune-suppressing drugs, such as cyclosporine, can restore normal cell counts, many patients have disease relapses. These patients require long-term therapy with cyclosporine, which can cause harmful side effects. This study will examine whether a lower dose of cyclosporine given together with mycophenolate mofetil (MMF) can maintain blood counts as effectively as full-dose cyclosporine treatment, and whether MMF alone can reduce the chances of future relapses. Patients 4 years of age and older with severe aplastic anemia who have relapsed after immune suppressing therapy may be eligible for this study. Participants will be randomly assigned to receive either standard cyclosporine therapy or experimental therapy with cyclosporine and MMF. Patients receiving standard cyclosporine therapy will receive a full dose of the drug for at least 3 months. Those taking both cyclosporine and MMF will take MMF plus half-dose cyclosporine for 3 months and continue MMF for an additional 6 months. Both drugs are taken twice a day by mouth. All patients will have about 120 milliliters (4 ounces) of blood drawn at the beginning of the study to evaluate immune system activity and bone marrow function, and to look for genetic material of certain viruses. Bone marrow aspirations and biopsies will be done at the beginning of the study, and at 6 and 12 months. For these tests, the area of the hip is anesthetized and a special needle is used to draw bone marrow from the hipbone. The patient's local doctor will be asked to do blood tests for chemistries, liver function and cyclosporine levels weekly for the first month and then every other week. Patients will return to NIH for evaluations 3, 6 and 12 months after treatment and then once a year. About 100 ml (7 tablespoons) of blood will be drawn at each visit.
OBJECTIVES: I. Compare outcome, including graft failure, graft versus host disease, and survival of HLA-identical sibling bone marrow transplants for aplastic anemia using cyclophosphamide with or without antithymocyte globulin as a conditioning regimen.
OBJECTIVES: I. Evaluate the efficacy of related, HLA-identical bone marrow transplantation following cyclophosphamide (CTX) and antithymocyte globulin in patients with aplastic anemia. II. Evaluate the efficacy of related, HLA-nonidentical bone marrow transplantation following CTX and total-body irradiation/total-lymphoid irradiation in patients with aplastic anemia.
RATIONALE: Bone marrow and peripheral stem cell transplantation may be able to replace immune cells that were destroyed by chemotherapy or radiation therapy used to kill cancer cells. PURPOSE: Phase II trial to study the effectiveness of T-cell depleted bone marrow and G-CSF stimulated peripheral stem cell transplantation in treating patients with leukemia, lymphoblastic lymphoma, myelodysplastic syndrome, or aplastic anemia.
This study will test the safety and effectiveness of a combination of three drugs in treating severe aplastic anemia and preventing its recurrence. Two drugs used in this trial ATG and cyclosporine are standard combination therapy for aplastic anemia. This study will try to improve this therapy in three ways: 1) by altering the drug regimen to allow the drugs to work better; 2) by reducing the risk of kidney damage; and 3) by adding a third drug mycophenolate mofetil to try to prevent disease relapse. Patients with severe aplastic anemia who do not have a suitable bone marrow donor or who decline bone marrow transplantation may participate in this study. Patients will have a skin test for ATG allergy, chest X-ray, blood test, and bone marrow aspiration before treatment begins. ATG will then be started, infused through a vein continuously for 4 days. Ten days after ATG is stopped, cyclosporine treatment will begin, taken twice a day by mouth in either liquid or capsule form and will continue for 6 months. Also, in the first 2 weeks of treatment, patients will be given a full dose of corticosteroid (prednisone) to prevent serum sickness that could develop as a side effect of ATG therapy. The dosage will be decreased after that. Mycophenolate will be started at the same time as ATG, in two daily doses by mouth, and will continue for 18 months. Patients will be hospitalized at the beginning of the study. During this time, blood will be drawn at 3-week intervals and a bone marrow examination will be repeated 3 months after treatment has begun. Additional tests, including X-rays may be required. After hospital discharge, patients will be followed on an outpatient basis at 3-month intervals. The patients own physician will perform blood tests weekly and kidney and liver function tests every 2 weeks during cyclosporine therapy. Transfusions may be required initially.
This trial, sponsored by Amgen, Inc., which produces the recombinant methionyl human stem cell factor (r-metHuSCF), also involves two other institutions. The primary objective is determination of the safety of administering multiple doses of r-metHuSCF in the setting of acquired aplastic anemia and evaluation of the effect of r-metHuSCF on peripheral blood counts. Potential effects of r-metHuSCF on frequency of need for red cell or platelet transfusions and on bone marrow morphology/cellularity will also be evaluated.
The purpose of this study is to find out whether upfront emapalumab treatment can help in sAA (Aplastic Anemia) treatment planning and increase the effectiveness of standard treatment options. Funding Source- FDA OOPD
RATIONALE: Gathering information about how often methemoglobinemia occurs in young patients receiving dapsone for hematologic cancer or aplastic anemia may help doctors learn more about the disease and plan the best treatment. PURPOSE: This research study is looking at methemoglobinemia in young patients with hematologic cancer or aplastic anemia treated with dapsone.
A single arm dose optimization study in which all patients are given a fixed dose of Cytoxan (4 x 50 mg/kg) plus ATG (3 x 30 mg/kg) and the TBI dose starting at 3 x 200 cGy is escalated or de-escalated dependent upon engraftment and toxicity.
This Phase II open-label interventional clinical trial aims to evaluate the efficacy of romiplostim, in patients with severe aplastic anemia (SAA), both treatment naïve and relapsed/refractory, in inducing trilineage hematopoiesis in children and young adults.
The main goal of this study was to investigate the effectiveness and safety of eltrombopag (ETB) when compared to other treatments in Japanese aplastic anemia (AA) patients using data from the Medical Data Vision (MDV) hospital-based database.
This phase II trial tests how well a ruxolitinib-based graft versus host disease (GVHD) prevention (prophylaxis) regimen works before, during, and after bone marrow/stem cell transplantation (hematopoietic cell transplantation \[HCT\]) in patients with acquired aplastic anemia. Acquired aplastic anemia (AA) is a condition in which the bone marrow is unable to produce blood cells. Affected patients typically present with infections due to abnormally low number of neutrophils, bleeding due to low platelet count, and/or fatigue due to a lower-than-normal number of red blood cells (anemia). Its incidence varies with age, occurring most frequently in patients aged 2-5 years, 20-25 years, and 55 years and older. Treatment of AA includes either immunosuppressive therapy (IST) or bone marrow/stem cell transplantation (HCT) with first-line therapy in younger adults often being HCT, while adults over 40 still frequently trial IST first due to the morbidity and mortality concerns with HCT. GVHD is a common complication after donor stem cell transplantation, resulting from donor immune cells recognizing recipients' cells and attacking them. Ruxolitinib, a drug in a class of oral medications called JAK inhibitors has been approved for the treatment of acute and chronic GVHD. It has also been shown to decrease GVHD when used in the prevention setting in patients with myelofibrosis. The current study aims to assess whether adding ruxolitinib to a standard GVHD prevention regimen may reduce the risk of Grade II-IV acute and chronic GVHD after bone marrow/stem cell transplantation in older patients with acquired aplastic anemia.
BMT CTN 2207 will investigate the use of marrow transplantation for treatment of severe aplastic anemia that has not previously been treated.
This phase I trial evaluates the safety and feasibility of using a reduced-intensity regimen of cyclophosphamide, pentostatin, and anti-thymocyte globulin prior to a CD4+ T-cell depleted haploidentical hematopoietic cell transplant (haploHCT) for the treatment of patients with severe aplastic anemia that does not respond to treatment (refractory) or that has come back (recurrent). Cyclophosphamide is in a class of medications called alkylating agents. It works by damaging the cell's deoxyribonucleic acid. It may also lower the body's immune response. Pentostatin blocks a protein needed for cell growth. Anti-thymocyte globulin is an immunosuppressive drug can destroy immune cells known as T-cells. HaploHCT transfers blood-forming stem cells from a healthy partially-matched donor to a patient. Administering a regimen of cyclophosphamide, pentostatin, and anti-thymocyte globulin before haploHCT may help make room for the new, healthy cells and may reduce the risk of graft versus host disease.