14 Clinical Trials for Various Conditions
This study will provide follow-up evaluation and care of patients who have undergone allogeneic (donor) stem cell transplantation at the NIH Clinical Center. Patients are monitored for their response to treatment, disease relapse, and later-occurring effects of the transplant. Patients between 10 and 80 years of age who received a donor stem cell transplant at the NIH Clinical Center under an NHLBI protocol may be eligible for this study. Candidates must have had their first transplant at least 3 years before entering the current study. Participants are generally seen in the clinic every 12 months for some or all of the following procedures: * Periodic physical examinations, eye examinations, and blood and urine tests. * Bone marrow aspiration and biopsy: A sample of bone marrow is obtained for microscopic examination. The patient is given local anesthesia or conscious sedation. An area of the hipbone is numbed, a thin needle is inserted through the skin into the bone, and a small amount of marrow is withdrawn. * Tissue biopsy: A small piece of tissue or tumor is obtained for microscopic examination. Depending on the site of the biopsy, the tissue may be removed using a cookie cutter-like "punch" instrument, a needle, or a knife. The area is numbed and the tissue is removed with the appropriate tool. * Imaging tests to visualize organs, tissues, and cellular activity in specific tissues. For these tests, the patient lies on a table that slides into the scanner. They may include the following: 1. Nuclear scans use a sensitive camera to track a small amount of radioactive material (radioisotope) that is given to the patient by mouth or through a vein. The scan may show abnormal areas of tissue in the bones, liver, spleen, kidney, brain, thyroid, or spine. 2. Magnetic resonance imaging (MRI) uses a magnetic field and radio waves to examine small sections of body organs and tissues. 3. Computerized tomography (CT) uses x-rays and can be done from different angles to provide a 3-dimensional view of tissues and organs. 4. Positron emission tomography (PET) uses a fluid with a radioisotope attached to it to show cellular activity in specific tissues. The fluid is given through a vein and travels to the cells that are most active (like cancer cells), showing if there is an actively growing tumor. * Pulmonary (lung) function tests: The patient breathes into a machine that measures the volume of air the person can move into and out of the lungs. * Heart function tests may include the following: 1. Electrocardiogram (EKG) evaluates the electrical activity of the heart. Electrodes placed on the chest transmit information from the heart to a machine. 2. Echocardiogram (Echo) is an ultrasound test that uses sound waves to create an image of the heart and examine the function of the heart chambers and valves. 3. Multiple gated acquisition scan (MUGA) is a nuclear medicine test that uses a small amount of radioactive chemical injected into a vein. A special scanner creates an image of the heart for examining the beating motion of the muscle. Disease relapse or progression, or transplant-related problems may be treated with standard medical, radiation, or surgical therapy, or patients may be offered experimental therapy. ...
Bone marrow transplants (BMT) are one form of treatment for disorders of the blood, including leukemia. However, because the procedure is often associated with potentially life-threatening reactions, it is usually reserved for patients with serious illnesses under the age of 60 years old. One serious reaction complicating bone marrow transplants is referred to as graft-versus-host disease (GVHD). GVHD is a potentially fatal incompatibility reaction. The reaction is caused by antigens found on the cells of the patient that are not present on the cells of the donor. The antigens are recognized by transplanted white blood cells (lymphocytes). These lymphocytes begin attacking the recipient s cells and tissues and may lead to death. In order to avoid GVHD, researchers have developed a technique using peripheral blood instead of bone marrow that allows transplantation of stem cells and removal of lymphocytes. Stem cells are the cells responsible for returning blood cell production to normal. Lymphocytes are the white blood cells that can cause GVHD. The technique requires two steps. In the first step blood cells are collected from donors who have received doses of a growth factor. The growth factor (granulocyte colony stimulating factor) is designed to increase the production of donor stem cells. In the second step white blood cell lymphocytes are removed from the collected blood, leaving only the stem cells. The main goal of this study is to develop and improve the method of processing cells that are collected after stimulation with growth factor (G-CSF), by removing the white blood cell lymphocytes which can cause graft-versus-host disease (GVHD) while keeping the stem cells necessary for healthy blood cell building. In addition, researchers are interested in studying whether giving G-CSF has an effect on lymphocyte function, which may influence the immune reactions occurring in bone marrow transplantation.
This is a study designed to assess the safety of administration of up to 3 dose levels of eritoran in subjects undergoing or scheduled to undergo allogeneic bone marrow transplant (BMT). An allogeneic BMT is the transplantation of blood stem cells taken from the bone marrow or blood of another person.
This study will evaluate the safety and effectiveness of stem cell transplantation in which the donor s T cells (a type of lymphocyte, or white blood cell) have been removed and then added back. Certain patients with bone marrow malignancies undergo transplantation of donated stem cells (cells produced by the bone marrow that mature into the different blood components white cells, red cells and platelets) to generate new and normally functioning bone marrow. However, T-cells from the donor may see the patient s cells as foreign and mount an immune response to reject them, causing what is called graft-versus-host-disease (GVHD). Therefore, in this study, T-cells are removed from the donor cells to prevent this complication. Nevertheless, there are disadvantages of removing the T-cells, since they are important in fighting viral infections as well as any remaining malignant cells. The attack against the malignant cells is called a graft-versus-leukemia effect. Therefore, donor T cells are given to the patient (added back) later (45 and 100 days after the transplant) when they can provide needed immunity with less risk of causing GVHD. Patients between 10 and 55 years of age with chronic myelogenous leukemia, acute lymphoblastic leukemia, acute myelogenous leukemia, a myelodysplastic syndrome, myeloproliferative disorders, or chronic lymphocytic leukemia may be eligible for this study. Prospective participants and their donors are screened with a medical history and physical examination, blood tests (including a test to match for genetic compatibility), breathing tests, chest and sinus X-rays, and tests of heart function. They also undergo a bone marrow biopsy and aspiration. For this procedure, done under local anesthetic, about a tablespoon of bone marrow is withdrawn through a needle inserted into the hipbone. Participants may undergo apheresis to collect lymphocytes for research studies. This procedure involves collecting blood through a needle in the arm, similar to donating a unit of blood. The lymphocytes are then separated and removed by a cell separator machine, and the rest of the blood is returned through a needle in the other arm. Before treatment begins, patients have a central venous catheter (flexible plastic tube) placed in a vein. This line remains in place during the stem cell transfusion and recovery period for drawing and transfusing blood, giving medications, and infusing the donated cells. Preparation for the transfusion includes irradiation and chemotherapy. Patients undergo total body irradiation in 8 doses given in two 30-minute sessions a day for 4 days. Four days before the transfusion, they begin taking cyclophosphamide, and 9days before the procedure they start fludarabine. These are anti-cancer drugs that kill the cancer cells and prevent rejection of the donated cells. While the patient is receiving chemotherapy, the donor receives daily injections for 6 days of G-CSF, a drug that moves stem cells from the bone marrow into the blood stream. On days 1 and 2 after chemotherapy is completed, the stem cells are infused into the patient through the central line. Patients usually stay in the hospital about 20 to 30 days after the transplant to recover from treatment side effects, which may include fever, nausea, diarrhea and mouth pain, and receive blood transfusions, if needed. Treatment with cyclosporine, a drug that helps prevents both rejection of donated cells and GVHD, is started on day 44 one day before the first T-cell add-back. Patients return to the clinic for follow-up with various tests, treatments and examinations as required, with a minimum of visits at least once or twice a week for 2 to 4 months after the transplant; then at 4, 6, 9, and 12 months, and then yearly for at least 3 years.
This study will evaluate the safety and effectiveness of stem cell transplantation in which the donor's T cells (a type of lymphocyte, or white blood cell) are removed and then added back. Certain patients with bone marrow malignancies undergo transplantation of donated stem cells to generate new and normally functioning bone marrow. However, T-cells from the donor may see the patient's cells as foreign and mount an immune response to reject them, causing what is called "graft-versus-host-disease" (GVHD). Therefore, in this protocol, T-cells are removed from the donor cells to prevent this complication. However, because T-cells are important in fighting viral infections as well as any remaining malignant cells (called graft-versus-leukemia effect), the donor T-cells are given to the patient (added back) at a later time after the transplant when they can provide needed immunity with less risk of causing GVHD. Patients between 10 and 55 years of age with acute or chronic leukemia, myelodysplastic syndrome, or myeloproliferative syndrome may be eligible for this study. Prospective participants and their donors are screened with a medical history and physical examination, blood tests (including a test to match for genetic compatibility), breathing tests, chest and sinus x-rays, and tests of heart function. They also undergo a bone marrow biopsy and aspiration. For this procedure, done under local anesthetic, about a tablespoon of bone marrow is withdrawn through a needle inserted into the hipbone. They undergo apheresis to collect lymphocytes for research studies. This procedure involves collecting blood through a needle in the arm, similar to donating a unit of blood. The lymphocytes are then separated and removed by a cell separator machine, and the rest of the blood is returned through a needle in the other arm. Before treatment begins, patients have a central intravenous line (flexible plastic tube) placed in a vein in the chest. This line remains in place during the stem cell transplant and recovery period for drawing and transfusing blood, giving medications, and infusing the donated cells. Preparation for the transfusion includes high-dose radiation and chemotherapy. Patients undergo total body irradiation in 8 doses given in two 30-minute sessions a day for 4 days. Eight days before the transplant, they begin taking fludarabine, and 3 days before the procedure they start cyclophosphamide.
Bone marrow transplantation (BMT) is a risky procedure. If doctors could reduce the complications, BMT would be safer to use for a wider range of conditions. The purposes of this study are * to prevent graft rejection by increasing the amount of immunosuppression and by giving some lymphocytes from the donor before transplant; * to prevent graft-versus-host disease (GVHD) by transplanting T-cell depleted stem cells; * to improve the immune effect against residual leukemia by the add-back of donor lymphocytes before transplant and six or more weeks after transplant. Beyond the standard transplant protocol, study participants will undergo additional procedures. First, along with total body irradiation, patients will receive two drugs (a high dose of cyclophosphamide and fludarabine) to suppress immunity and prevent rejection of the transplant. Second, four days before the transplant, patients will be given donor lymphocytes that have been irradiated to make them incapable of causing GVHD. On the day of the transplant, patients will receive an infusion of T-cell depleted bone marrow stem cells. Finally, patients will receive two doses of add-back donor T-cells (45 and 100 days post transplant) and the immunosuppressive drug cyclosporine starting on day 44 until about six months after transplant. Study participants must be between the ages of 10 and 56 and have a family member who is a suitable stem cell donor match.
This study will investigate the safety and effectiveness of an experimental stem cell transplant procedure for treating mastocytosis-a disease of abnormal mast cell growth. Patients often feel faint, have skin problems, joint and bone pain, low blood counts and enlarged liver, spleen or lymph nodes. As yet, there is no cure for mastocytosis, and treatment is aimed at controlling symptoms. Stem cells are cells produced by the bone marrow that mature into the different blood components-white cells, red cells and platelets. Transplantation of allogeneic (donated) stem cells is a mainstay of therapy for some forms of leukemia. Patients first receive intensive chemotherapy and radiation to rid the body of cancer cells. This "conditioning" is followed by transplantation of donated stem cells to generate new, healthy bone marrow. In addition to producing the new bone marrow, the donated cells also fight any residual tumor cells that might have remained in the body. This is called a "graft-versus-tumor" effect. This study will examine whether a stem cell transplant from a healthy donor can similarly target and destroy mast cells in a "graft-versus-mast cell" effect. Also, to try to reduce the harmful side effects of chemotherapy and radiation, this study will use lower dose chemotherapy and no radiation. Patients with advanced mastocytosis between 10 and 80 years old may be eligible for this study. They will be tested for HLA type matching with a sibling and will undergo a medical history, physical examination and several tests to determine eligibility for the study. Participants will undergo apheresis to collect lymphocytes (a type of white blood cell) for immune function tests. In this procedure, blood is drawn through a needle in the arm, similar to donating a unit of blood. The lymphocytes are then separated and collected by a cell separator machine, and the rest of the blood is returned through a needle in the other arm. Patients will also have a central venous line (flexible plastic tube) placed in their upper chest leading to a vein. This line will remain in place throughout the transplant and recovery period and will be used to transfuse blood components, administer medicines, infuse the donated stem cells, and draw blood for tests. Patients will begin conditioning with cyclophosphamide, starting 7 days before the transplant, and fludarabine, starting 5 days before the transplant, to prevent rejection of the donated cells. From 1 to 3 days after the chemotherapy is completed, the stem cells will be transfused through the central venous line. Also, from 4 days before the transplantation until about 3 months after the procedure, patients will receive cyclosporine and mycophenolate mofetil-drugs that help prevent both rejection of the donated cells and attack by the donor cells on the patient's cells (called graft-versus-host disease). Patients will stay in the hospital about 20 to 30 days after the transplant. After discharge, they will continue to take antibiotics, cyclosporine and mycophenolate mofetil at home. If the mastocytosis progresses, cyclosporine and mycophenolate mofetil will be tapered over 4 weeks. If the mastocytosis persists, patients may receive additional transfusions of donor lymphocytes to help kill the mast cells. Patients' progress will be followed weekly or twice weekly for 3 months, then at 6, 12, 18, 24, 30, 36, 48 and 60 months after transplant, and then twice a year for various tests, treatments and examinations.
This study will investigate the safety and effectiveness of a new stem cell transplant procedure to treat acute or chronic leukemia, multiple myeloma, myelodysplastic syndrome, Hodgkin's and non-Hodgkin's lymphoma in HIV-infected patients. HIV-infected patients usually are not offered bone marrow transplant treatments because they are at increased risk of dying from the intense chemotherapy and radiation therapy used for the procedure. This study uses a modified procedure, transplanting stem cells instead of bone marrow, designed to be less dangerous for such patients. Patients will also undergo a procedure called gene transfer to try to halt progression of their HIV infection. The procedure in this study differs from standard bone marrow transplantation in three ways: Stem cells will be transplanted instead of bone marrow. (Stem cells, which are produced by the bone marrow, mature into the different blood components-white and red cells and platelets.) The stem cell donor will be given a drug that releases these cells from their bone marrow into the blood stream. The cells will then be collected from the donor by apheresis, a procedure in which whole blood is drawn, the stem cells separated and removed, and the rest of the blood returned to the donor.); The procedure will use lower doses of chemotherapy than the conventional method, and will not use radiation therapy; or A laboratory-manufactured gene designed to obstruct HIV reproduction will be inserted into the stem cells, rendering future cells that develop from resistance to the virus. Prospective patients will be tested for matching with an HIV-negative donor (family member) and will undergo a medical history, physical examination and several tests (e.g., breathing tests, X-rays, etc.) to determine eligibility for the study. Study participants will then undergo apheresis to collect white blood cells called lymphocytes. Stem cells will be collected from the donor. Half the donated cells will have the HIV-resistant gene inserted; the other half will have a "control" gene inserted. Additional stem cells collected a second day will not be manipulated. All the donor cells will be frozen until transplantation. Patients will be given drugs (cyclophosphamide, fludarabine and cyclosporin) to prevent the donated cells from being rejected and to prevent them from damaging the patient's organs. The thawed stem cells will then be infused through a vein. After 30, 60 and 100 days, bone marrow cells and circulating lymphocytes will be checked to see how many are of donor cell origin. If less than 100 percent are of donor origin, more lymphocytes will be transfused. Patients will have physical examinations and blood tests once or twice a week for 2 to 3 months with and then will be followed periodically for at least 5 years.
The are a variety of cancerous diseases of the blood and bone marrow that can be potentially cured by bone marrow transplantation (BMT). Diseases like leukemia, lymphoma, and multiple myeloma are among the conditions that can be treated with BMT. Some patients with these diseases can be treated with medical chemotherapy alone. However, patients who relapse following chemotherapy are usually not curable with additional chemotherapy treatments. The only option known to provide a potential cure if this occurs is BMT. Allogenic transplants are cells collected from relatives of the patient. The transplant requires additional high intensity chemotherapy and radiation in order to destroy cancerous cells. In the process, many normal bone marrow cells are also destroyed. This is the reason for transplanting stem cells. The stem cells help to build new functioning bone marrow, red cells, white cells, and platelets. In addition, the immune cells from the donor are implanted into the recipient s body and help to fight off infection and kill remaining cancerous cells. Unfortunately, the powerful doses of chemotherapy and radiation therapy associated with allogenic BMT have toxic side effects and often make BMTs too dangerous to attempt in many patients. In order to reduce the complications of BMT, and make it a safer available option for patients with cancers of the blood and bone marrow, researchers have developed a new approach to the BMT. In this study researchers plan to use stem cells collected from the blood stream of patient s relatives rather than from the bone marrow (blood progenitor/stem cell transplant). In addition, researchers plan to use low doses of chemotherapy and no radiation therapy to reduce side effects. The majority of the cancer killing effect will be the responsibility of the stem cell transplant rather than the chemotherapy.
Cancers of the blood, sometimes referred to as hematologic malignancies, are disorders of bone marrow cells that lead to the failure of the normal function of bone marrow and the uncontrolled growth of cancerous cells in the bone marrow. These cancerous cells can spill over into the bloodstream and affect other organs causing widespread symptoms. The disease is life threatening because it blocks the normal function of the marrow, which is to produce red cells (preventing anemia), white cells (preventing infection), and platelets (preventing progression). Bone marrow transplants are a potential form of therapy for patients with hematologic malignancies. However, BMT is a complicated procedure and can be associated with dangerous side effects. In this study researchers are attempting to find ways to reduce the complications of BMT, so that it would be possible to use it more safely and can be offered more patients. In order to do this, researchers are developing new techniques to make BMT safer. It requires making small changes to the standard procedure, which may improve the outcome. The experimental procedures researchers are evaluating are: 1. \<TAB\>T-cell depleted peripheral blood progenitor cell (PBPC) transplantation 2. \<TAB\> Cyclosporine given immediately after the transplant 3. \<TAB\>Add-back of donor lymphocytes Patients undergoing these experimental techniques must be monitored closely to see if any benefit or harmful effects will occur. Information gathered from this study can be used to develop further research studies and potential new therapies for hematologic malignancies.
Many patients with hematological malignancies potentially curable by bone marrow transplantation are not considered for transplantation because an HLA identical family or unrelated donor is unavailable. For these patients the only curative option is a transplant from a partially matched family donor. Such transplants are feasible but are less successful than matched sibling donor transplants. The main problems with mismatched transplants are graft rejection, graft-vs-host disease, and regimen-related mortality. This restricts the use of mismatched transplants to patients less than 45 years at high risk of dying from the hematological malignancy. This protocol evaluates a new preparative regimen designed to ensure stem cell engraftment by increased immunosuppression, followed by a G-CSF mobilized T cell depleted, stem cell rich, peripheral blood progenitor cell (PBPC) transplant from a mismatched related donor in patients with high risk hematological malignancies. This phase I study evaluates engraftment and GVHD following T cell depleted, HLA-mismatched PBPC transplants. Stopping rules will be used to make modifications to the protocol in the event of graft failure. The end points of the study are graft take, acute and chronic GVHD, leukemic relapse, transplant-related mortality, death and leukemia-free survival. Patients will be followed up for 5 years. It is planned to treat up to 35 patients aged between 10 and 45 years.
Diseases such as leukemia, lymphoma, and multiple myeloma fall into the category of blood cancers. Some of these conditions can now be cured by bone marrow transplantation (BMT). The ability of BMT to cure these conditions has been credited to the use of high doses of chemotherapy, radiation therapy, and the antileukemia effect of the transplant. Because the effectiveness of BMT relies on the use of high doses of chemotherapy and total body irradiation (TBI), it is a therapy associated with toxic side effects. These side effects are often deadly and have limited BMT for use in patients under the age of 55. In this study researchers plan to treat older patients between the ages of 55 to 75 years with blood cell transplants taken from donors who are genetically matched relatives of the patient. In order to decrease the toxic side effects associated with the transplant, researchers will not use chemoradiotherapy. Instead they plan to use intensive immunosuppressive therapy and allow the transplanted cells to take effect.
Bone marrow transplants (BMT) are one of the accepted therapies used to treat leukemia. However, BMT have risks of complications. One potentially life-threatening complication is known as graft-versus-host disease (GVHD). The GVHD is a reaction caused by an incompatibility between donor cells and recipient cells. Antigens found on the recipient s cells are recognized by the donor s transplanted white blood cell lymphocytes. These lymphocytes begin attacking the recipient s cells and tissues and may lead to death. One of the most effective ways to prevent this reaction is to remove the lymphocytes from the transplanted marrow. Unfortunately, without lymphocytes the recipient s immune system will be lowered and may result in a relapse of leukemia or an infection. Researchers have shown they can perform effective BMT by removing the lymphocytes prior to the transplant and then later adding the lymphocytes back. This technique can reduce the potential for GVHD and preserve the graft-versus-leukemia (GVL) effect of the transplant. In this study researchers plan to use peripheral blood with lymphocytes removed rather than bone marrow. In order to increase the number of progenitor cells, the cells responsible for correcting the leukemia, donors will receive doses of G-CSF prior to the transplant. G-CSF (granulocyte colony stimulating factor) is a growth factor that increases the production of progenitor cells in the donor s blood stream. The study will be broken into two parts. The first part of the study will attempt to determine if peripheral blood with lymphocytes removed can prevent GVHD while preserving the GVL effect of the transplant. In the second part of the study, patients that received the transplant will have the lymphocytes added-back on two separate occasions in order reduce the chances of relapse and infection. The study is designed to treat up to 55 patients ages 10 to 60 years and follow their progress for 5 years.
This study will investigate the safety and effectiveness of a new stem cell transplant procedure for treating chronic myelogenous leukemia (CML). Transplantation of donated stem cells (cells produced by the bone marrow that mature into the different blood components-white cells, red cells and platelets) is a very effective treatment for CML. However, despite its success in a large number of patients, there is still a significant risk of death from the procedure. In addition, it results in sterility and leaves patients at increased risk for other cancers and for eye cataracts. These complications result from the intensive chemotherapy and radiation patients receive before the transplant to rid the body of cancer cells. In this study, radiation will not be used and chemotherapy drugs will be given in lower doses to try to reduce the dangers of the procedure. Patients with CML will be tested for matching with a donor (family member) and will undergo a medical history, physical examination and several tests (e.g., breathing tests, X-rays, and others) to determine eligibility for the study. Participants will then undergo apheresis to collect lymphocytes (white blood cells important in the immune system). In apheresis, whole blood is drawn through a needle in the arm, similar to donating a unit of blood. The required component-in this case, lymphocytes-are separated and removed, and the rest of the blood is returned through a needle in the other arm. Each day starting five days before the transplant, the donor will be given an injection of G-CSF, a drug that releases stem cells from the bone marrow into the blood stream. The cells will be collected after the fifth injection and again after a sixth injection the following day. Meanwhile, patients will be given cyclophosphamide and fludarabine, and perhaps anti-thymocyte globulin, to prevent rejection of the donated cells. On the day of the transplant, patients will be given cyclosporin to prevent graft-versus-host-disease, a disease in which the donor cells react against the patient's cells. They may also be given lymphocytes after the transplant to boost the immune system and destroy leukemia cells. After 30, 60 and 100 days, bone marrow cells and circulating lymphocytes will be checked to see how many are of donor cell origin. If less than 100 percent are of donor origin, more lymphocytes will be transfused. Patients will have physical examinations and blood tests at least weekly for 3 months and then periodically for 5 years.