783 Clinical Trials for Various Conditions
To learn more about social and financial factors that may influence outcomes of TCT treatment at MD Anderson.
This study will investigate the safety and effectiveness of a modified donor stem cell transplantation procedure for treating advanced mycosis fungoides (MF), a lymphoma primarily affecting the skin, and Sezary syndrome (SS), a leukemic form of the disease. Donated stem cells (cells produced by the bone marrow that mature into the different blood components white cells, red cells and platelets) can cure patients with certain leukemias and lymphomas and multiple myeloma. These cells generate a completely new, functioning bone marrow. In addition, immune cells from the donor grow and generate a new immune system to help fight infections. The new immune cells also attack any residual tumor cells left in the body after intensive chemotherapy. However, stem cell transplantation carries a significant risk of death, because it requires completely suppressing the immune system with high-dose chemotherapy and radiation. In addition, lymphocytes from the donor may cause what is called graft vs. host disease (GvHD), in which these cells see the patient s cells as foreign and mount an immune response to destroy them. To try to reduce these risks, patients in this study will be given low-dose chemotherapy and no radiation, a regimen that is easier for the body to tolerate and involves a shorter period of complete immune suppression. In addition, a monoclonal antibody called Campath-1H will be given to target lymphocytes, including those that have become cancerous. Patients with advanced MF or SS who are between 18 and 70 years of age and have a matched family donor 18 years of age or older may be eligible for this study. Candidates will have a medical history, physical examination and blood tests, lung and heart function tests, X-rays of the chest, eye examination, and bone marrow sampling (withdrawal through a needle of about a tablespoon of marrow from the hip bone), and small skin biopsy (surgical removal of a piece of tissue for microscopic examination) or needle biopsy of the tumor. Stem cells will be collected from both the patient and donor. To do this, the hormone G-CSF will be injected under the skin for several days to push stem cells out of the bone marrow into the bloodstream. Then, the stem cells will be collected by apheresis. In this procedure the blood is drawn through a needle placed in one arm and pumped into a machine where the required cells are separated out and removed. The rest of the blood is returned through a needle in the other arm. Before the transplant, a central venous line (large plastic tube) is placed into a major vein. This tube can stay in the body and be used the entire treatment period to deliver the donated stem cells, give medications, transfuse blood, if needed, and withdraw blood samples. Several days before the transplant procedure, patients will start a conditioning regimen of low-dose chemotherapy with Campath 1H, fludarabine, and, if necessary, cyclophosphamide. When the conditioning therapy is completed, the stem cells will be infused over a period of up to 4 hours. To help prevent rejection of donor cells and GvHD, cyclosporine and mycophenolate mofetil will be given by mouth or by vein for about 3 months starting 4 days before the transplantation. The anticipated hospital stay is 3 to 4 days, when the first 3 doses of Campath will be monitored for drug side effects. The rest of the procedures, including the transplant, can be done on an outpatient basis. Follow-up visits for the first 3 months after the transplant will be scheduled once or twice a week for a physical examination, blood tests and symptoms check. Then, visits will be scheduled at 6, 12, 18, 24, 30, 36, and 48 months post-transplant. Visits for the first 3 years will include blood tests, skin biopsies, and bone marrow biopsies.
IDION is currently seeking FDA approval for this device- the IDION iTempShield. It is a skin-safe, FDA complaint and non-invasive device that can read and monitor skin temperature. Having continuous temperature monitoring using the IDION iTempShield may provide early detection of a fever for patients with febrile neutropenia. Febrile neutropenic fever is common in patients receiving chemotherapy and can often indicate infection. The main potential benefit potenially experienced from participating in this study would be the early detection of fever. There is a potential benefit that infection will be detected earlier in subjects wearing the IDION iTempShield.
The purpose of this study is to estimate overall survival (OS) for participants treated with abatacept versus those not treated with abatacept prior to hematopoietic stem cell transplantation (HSCT). Participants were included if their donors were unrelated and had 1-allele mismatched human leukocyte antigen (HLA) status.
This phase II trial studies how well autologous stem cell transplant works in treating patients with favorable or intermediate risk, minimal residual disease (MRD)-negative, acute myeloid leukemia. Giving chemotherapy before a peripheral blood stem cell transplant helps kill any cancer cells that are in the body. After treatment, stem cells are collected from the patient's blood and stored. Higher dose chemotherapy is then given to prepare the bone marrow for the stem cell transplant. The stem cells are then returned to the patient to replace the blood-forming cells that were destroyed by the chemotherapy.
This study is testing a combination of chemo-immuno therapy called RBM. RBM consists of combination of drugs: rituximab, bendamustine, and melphalan followed by reinfusion of the participants own stem cells which is called autologous stem cell transplant (ASCT). Compared to the standard BEAM regimen, this RBM regimen may or may not be less effective in lymphoma, but will likely have fewer side effects.
The study is a Phase II clinical trial. Patients will receive intensity modulated total body irradiation (TBI) at a dose of 3 Gy with standard fludarabine/ i.v. cyclophosphamide conditioning prior to human leukocyte antigen (HLA)-haploidentical hematopoietic stem cell transplant (HSCT). The primary objective of the study is to determine the engraftment at Day +60 following HLA-haploidentical hematopoietic stem cell transplant protocol using immunosuppressive agents and low-dose total body irradiation (TBI) for conditioning and post-transplant cyclophosphamide in patients with sickle cell disease.
The purpose of this study is to evaluate the toxicity and the effectiveness of high dose chemotherapy with HPC transplant Multiple Sclerosis that has failed at least two lines of therapy
This pilot clinical trial studies induction therapy followed by iobenguane I 131 and chemotherapy in treating patients with newly diagnosed high-risk neuroblastoma undergoing stem cell transplant, radiation therapy, and maintenance therapy with isotretinoin. Radioisotope therapy, such as iobenguane I 131, releases radiation that kills tumor cells. Drugs used in chemotherapy, such as carboplatin, etoposide phosphate, busulfan, and melphalan, work in different ways to stop the growth of tumor cells, either by killing the cells or by stopping them from dividing. A peripheral stem cell transplant may be able to replace blood-forming cells that are destroyed by iobenguane I 131 and chemotherapy. Giving radioisotope therapy, chemotherapy, and peripheral stem cell transplant may kill more tumor cells.
Standard therapy for multiple myeloma (MM) usually includes an autologous bone marrow stem cell transplant - a procedure where the patient is treated with high dose chemotherapy and then their own (autologous) stem cells are transplanted back into their body. Patients with multiple myeloma and high risk genes, always relapse after an autologous transplant and often die within two years from the time of their transplant. A different type of transplant allogeneic) using donor cells, may work better for high-risk Multiple Myeloma, because the donor cells may help kill the lymphoid cancer cells. This study will investigate if a matched donor stem cell transplant using a newer, reduced toxicity, chemotherapy (Flu-Bu4) is a feasible option for patients with high risk, Multiple Myeloma.
The purpose of this study is to learn about possible changes in brain anatomy and in thinking abilities, such as memory skills, in patients with cancer who receive treatment with chemotherapy alone or in combination with total body radiation before undergoing stem cell transplantation.
The purpose of this research study is to: (1) determine if the combination of low dose total body irradiation, low dose cyclophosphamide and the addition of fludarabine, and a serum to suppress the immune system can allow selected stem cells to take and grow; (2) determine if selected stem cells from the blood or marrow can take and not cause graft-versus-host disease (GvHD), and; (3) evaluate the side effects of the combination of low dose radiation and chemotherapy drugs used for these transplants.
Relapsed disease is the most common cause of death in children with hematological malignancies. Patients who fail high-intensity conventional chemotherapeutic regimens or relapse after stem cell transplantation have a poor prognosis. Toxicity from multiple therapies and elevated leukemic/tumor burden usually make these patients ineligible for the aggressive chemotherapy regimens required for conventional stem cell transplantation. Alternative options are needed. One type of treatment being explored is called haploidentical transplant. Conventional blood or bone marrow stem cell transplant involves destroying the patient's diseased marrow with radiation or chemotherapy. Healthy marrow from a donor is then infused into the patient where it migrates to the bone marrow space to begin generating new blood cells. The best type of donor is a sibling or unrelated donor with an identical immune system (HLA "match"). However, most patients do not have a matched sibling available and/or are unable to identify an acceptable unrelated donor through the registries in a timely manner. In addition, the aggressive treatment required to prepare the body for these types of transplants can be too toxic for these highly pretreated patients. Therefore doctors are investigating haploidentical transplant using stem cells from HLA partially matched family member donors. Although haploidentical transplant has proven curative in many patients, this procedure has been hindered by significant complications, primarily regimen-related toxicity including graft versus host disease (GVHD), and infection due to delayed immune reconstitution. These can, in part, be due to certain white blood cells in the graft called T cells. GVHD happens when the donor T cells recognize the patient's (the host) body tissues are different and attack these cells. Although too many T cells increase the possibility of GVHD, too few may cause the recipient's immune system to reconstitute slowly or the graft to fail to grow, leaving the patient at high-risk for infection. However, the presence of T cells in the graft may offer a positive effect called graft versus malignancy or GVM. With GVM, the donor T cells recognize the patient's malignant cells as diseased and, in turn, attack these diseased cells. For these reasons, a primary focus for researchers is to engineer the graft to provide a T cell depleted product to reduce the risk of GVHD, yet provide a sufficient number of cells to facilitate immune reconstitution, graft integrity and GVM. In this study, patients were given a haploidentical graft engineered to with specific T cell parameter values using the CliniMACS system. A reduced intensity, preparative regimen was used to reduce regimen-related toxicity and mortality. The primary goal of this study is to evaluate overall survival in those who receive this study treatment.
This study will examine a new approach to treating patients with severe systemic lupus erythematosus (SLE) that involves collecting stem cells (cells produced by the bone marrow that develop into blood cells) from the patient, completely shutting down the patient's immune system, and then giving back the patient's stem cells. SLE is a chronic, inflammatory disorder of the immune system that can affect many organs. It is called an autoimmune disease because the patient's lymphocytes (white blood cells that normally protect against invading organisms), go out of control and attack the body's own tissues. Patients between 15 and 40 years of age with severe SLE affecting a major organ that is resistant to standard treatment may be eligible for this study. Candidates are screened with a medical history and physical examination, blood and urine tests, skin tuberculin test, and radiology studies to evaluate the extent of disease. They have endocrinology, nutrition, dental, and social work consultations, ultrasound or MUGA (multi-gated acquisition scan) scan heart imaging, electrocardiogram and lung function tests, bone marrow biopsy, and lymph node aspirate. Depending on which organs are affected, patients may have additional tests, such as lumbar puncture (spinal tap), kidney or lung biopsy, MRI (magnetic resonance imaging) of the brain and spinal cord, and PET (positron emission tomography) scan. They also complete quality of life questionnaires and have disability functional testing and neurocognitive (thinking) assessments. Participants have a central venous line (plastic tube) inserted into a neck or chest vein for administering stem cells and medicines and for drawing blood. They undergo seven apheresis procedures during the course of the study to collect stem cells for transplant and for research. For apheresis, whole blood is collected through a needle in an arm vein and directed to a cell-separating machine where the white cells are extracted and the rest of the blood is returned to the patient through the same needle. Patients are primed with three medications (methylprednisolone, rituximab, and cyclophosphamide) through the central line to help control the disease. In addition, a medication called G-CSF (growth colony stimulating factor) is injected under the skin for several days to boost production of stem cells. After enough stem cells have been collected for transplantation (infusion through the central line), patients are admitted to the hospital for an 8-day conditioning regimen followed by transplantation. The conditioning treatment consists of rituximab, fludarabine, and cyclophosphamide to eliminate all the white blood cells from the blood and bone marrow. The stem cells are then infused and the patient is closely monitored by a team of physicians and nurses. When the stem cells have engrafted, the bone marrow has recovered, and the patient feels well enough - usually 2 to 3 weeks after transplant - the patient is discharged from the hospital. Prednisone tapering begins as soon as feasibly possible, but no later then 28 days after transplant. Patients return to the National Institutes of Health (NIH) Clinical Center for frequent follow-up visits during the first 2 to 3 months following transplant. The time between visits is then extended to once every 3 months the first year, then every 6 months the second year, and then at least yearly for 5 years after the transplant. These visits include a physical examination, blood and urine tests, lumbar puncture (if there is central nervous system involvement), other appropriate biopsies and tests as needed to monitor the patient's health, short apheresis procedures to collect blood for research purposes, and quality of life questionnaires. Some select procedures will be optional. Bone marrow biopsies and lymph node aspirates are done at beginning and at 6, 12, and 24 months after transplant. PET scans are done at 1, 6, 12, and 24 months. ...
Systemic Sclerosis is a disease that may be caused by the immune system reacting against skin and certain organs. It is possible, that by changing the immune system we can modify the progression of this disease. Stem cells are created in the bone marrow. They mature into different types of blood cells that are needed including red blood cells, white blood cells, and platelets. In this study, we will stimulate the bone marrow to make extra stem cells. Next we will collect the stem cells, select specific cells, and store them. We will then give high dose chemotherapy that will destroy the patients immune system. We will then give back the selected stem cells we collected. We believe that these selected stem cells may be able to "re-create" the immune system without the portion that causes Systemic Sclerosis. The purpose of this study is to try to discover if stem cell transplantation can help patients with Systemic Sclerosis. We will also try to learn what the side effects are of this treatment in patients with Systemic Sclerosis. We hope that this treatment will help to relieve the symptoms patients are experiencing, although we do not know if it will.
This study will investigate the safety and effectiveness of a modified stem cell transplant procedure for treating leukocyte adhesion deficiency (LAD). LAD is an inherited blood disorder of leukocytes (infection-fighting white blood cells) that leaves patients vulnerable to life-threatening infections. Transplantation of donated stem cells (cells produced by the bone marrow that mature into blood cells) can improve the immune system of patients with LAD. However, this procedure carries a significant risk of death, particularly in patients with active infection because it requires completely suppressing the immune system with high-dose chemotherapy and radiation. In addition, T-cells (a type of white blood cell) from the donor may cause what is called graft vs. host disease (GvHD), in which the donor cells recognize the patient's cells as foreign and mount an immune response to destroy them. To try to reduce these risks, the donor's T-cells will be removed from the rest of the stem cells to be transplanted. Patients with LAD who weigh at least 12 kg (26.4 LB), who do not have an active infection, and who have a family member that is a well-matched donor may be eligible for this study. Pregnant or breast feeding women may not participate. Candidates will have a medical history, physical examination and blood tests, lung and heart function tests, X-rays or computed tomography (CT) scans of the body, and dental and eye examinations. They will fill out questionnaires that measure emotional well being, quality of life and intelligence (the ability to learn and understand). Stem cells will be collected from both the patient and donor. To do this, the hormone G-CSF will be injected under the skin for several days to move stem cells from the bone marrow to the bloodstream. The stem cells will be collected by apheresis, where blood is drawn through a needle placed in one arm and pumped into a machine separating and removing the required cells. The rest of the blood is then returned through a needle in the other arm. Before the transplant, a central venous line (large plastic tube) is placed into a major vein. This tube can stay in the body and be used during the entire treatment period to deliver the donated stem cells, give medications, transfuse blood, if needed, and withdraw blood samples. Several days before the transplant procedure, patients will begin a conditioning regimen of low-dose chemotherapy with cyclophosphamide, fludarabine, and Campath 1H. When the conditioning therapy is completed, the stem cells will be infused. To help prevent rejection of donor cells, cyclosporine will be given by mouth or by vein starting 1 month after the transplant procedure. The average hospital stay for stem cell transplantation is 21 days. After discharge, patients will return for follow-up clinic visits weekly or twice weekly for 2 to 3 months. These visits will include a symptom check, physical examination, and blood tests. Subsequent visits will be scheduled at 4, 6, 9, and 12 months after the transplant, or more often if required, and then yearly
RATIONALE: Drugs used in chemotherapy use different ways to stop tumor cells from dividing so they stop growing or die. Radiation therapy uses high-energy x-rays to damage tumor cells. Peripheral stem cell transplantation may allow the doctor to give higher doses of chemotherapy and kill more tumor cells. It is not yet known if combination chemotherapy is more effective with or without radiation therapy and/or surgery in treating Ewing's sarcoma. PURPOSE: This randomized phase III trial is studying different combination chemotherapy regimens to see how well they work when given with or without peripheral stem cell transplantation, radiation therapy, and/or surgery in treating patients with Ewing's sarcoma.
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.
RATIONALE: Drugs used in chemotherapy work in different ways to stop cancer cells from dividing so they stop growing or die. Peripheral stem cell transplantation may allow doctors to give higher doses of chemotherapy drugs and kill more cancer cells. Biological therapies, such as interferon alfa, use different ways to stimulate the immune system and stop cancer cells from growing. Thalidomide may stop the growth of cancer cells by stopping blood flow to the tumor. Pamidronate may help to reduce the side effects of treatment for multiple myeloma. PURPOSE: This phase II trial is studying combination chemotherapy, peripheral stem cell transplantation, biological therapy, pamidronate, and thalidomide to see how well they work in treating patients with stage I, stage II, or stage III multiple myeloma.
This study will evaluate the effectiveness of combination chemotherapy with paclitaxel (Taxol) and cyclophosphamide (Cytoxan), followed by high-dose melphalan and etoposide for treating inflammatory breast cancer. Patients also receive infusions of their own previously collected progenitor cells (primitive cells that can make new cells to replace ones destroyed by chemotherapy). Patients 18 years of age or older with stage IIIB inflammatory breast cancer that has not metastasized (spread beyond the breast) may be eligible for this study. Candidates are screened with a medical history and physical examination, blood and urine tests, and chest x-ray. They have computed tomography (CT) of the head, chest, abdomen and pelvis as well as a bone scan to determine the extent of disease, and a nuclear medicine scan called MUGA to examine the heart's pumping ability. They may receive a rehabilitation medicine evaluation. Participants undergo the following tests and procedures: * Central venous line placement: Patients have a central venous line (plastic tube) placed into a major vein in the chest before beginning treatment. The line remains in the body throughout treatment and is used to give chemotherapy and other medications and to withdraw blood samples. The line is usually placed under local anesthesia in the radiology department or the operating room. * Chemotherapy: Patients receive two or more cycles of paclitaxel and cyclophosphamide. Paclitaxel is given intravenously (I.V., through a vein) for 72 hours using a portable pump. Cyclophosphamide is given daily for 3 days I.V. over 1 hour. The cycles may be 28 days apart. A drug called Mesna is given with this treatment to protect the bladder from irritation from cyclophosphamide. Patients who have not previously been treated with doxorubicin (Adriamycin) may receive a maximum of four cycles of doxorubicin and cyclophosphamide by vein on a single day during each cycle, with cycles 21 days apart. When all the paclitaxel/cyclophosphamide cycles are completed, patients receive melphalan and etoposide, both drugs I.V. over 1 to 8 hours for three consecutive days. * G-CSF treatment: After each paclitaxel/cyclophosphamide cycle and after the melphalan/etoposide treatment, patients are given a drug called G-CSF. G-CSF, injected under the skin, stimulates production of infection-fighting white blood cells. * Apheresis: This is a procedure to collect progenitor cells for later reinfusion. For this procedure, blood is collected through a catheter (plastic tube) placed in an arm vein. The blood is circulated through a cell-separating machine, where the white cells, including the progenitor cells, are extracted, and the red cells are returned to the patient through another catheter in the other arm. Apheresis is done after each of two cycles of paclitaxel/cyclophosphamide. * Progenitor cell transplant: Progenitor cells are reinfused after melphalan/etoposide treatment. * Glucose infusion: A salt solution with chemically modified glucose is infused I.V. over a period of from 12 to 48 hours, with subsequent donation of blood cells for blood and immune system studies. Patients have a maximum of two glucose infusions, separated by at least 3 months. * Tumor biopsy: Some patients have a biopsy of their tumor (removal of a small piece of tumor tissue for microscopic study) before starting chemotherapy. * Blood tests: Blood is drawn frequently to monitor safety and treatment response, and for research purposes. * Dental consultation: Some patients may have a dental consultation before the progenitor cell transplant.
This phase I/II trial studies the safety, side effects, and best dose of decitabine in combination with fludarabine, cytarabine, filgrastim, and idarubicin (FLAG-Ida) and total body irradiation (TBI) followed by a donor stem cell transplant in treating adult patients with cancers of blood-forming cells of the bone marrow (myeloid malignancies) that are at high risk of coming back after treatment (relapse). Cancers eligible for this trial are acute myeloid leukemia (AML), myelodysplastic syndrome (MDS), and chronic myelomonocytic leukemia (CMML). Decitabine is in a class of medications called hypomethylation agents. It works by helping the bone marrow produce normal blood cells and by killing abnormal cells in the bone marrow. The FLAG-Ida regimen consists of the following drugs: fludarabine, cytarabine, filgrastim, and idarubicin. These are chemotherapy drugs that work in different ways to stop the growth of cancer cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Filgrastim is in a class of medications called colony-stimulating factors. It works by helping the body make more neutrophils, a type of white blood cell. Radiation therapy uses high energy x-rays, particles, or radioactive seeds to kill cancer cells and shrink tumors. TBI is radiation therapy to the entire body. Giving chemotherapy and TBI before a donor peripheral blood stem cell (PBSC) transplant helps kill cancer cells in the body and helps make room in the patient's bone marrow for new blood-forming cells (stem cells) to grow. When the healthy stem cells from a donor are infused into a patient, they may help the patient's bone marrow make more healthy cells and platelets. Giving decitabine in combination with FLAG-Ida and TBI before donor PBSC transplant may work better than FLAG-Ida and TBI alone in treating adult patients with myeloid malignancies at high risk of relapse.
This phase II trial tests how well epcoritamab in combination with standard of care (SOC) platinum-based chemotherapy (rituximab, ifosfamide, carboplatin, etoposide \[RICE\], rituximab, cytarabine, dexamethasone, oxaliplatin or carboplatin RDHAP/X\] or gemcitabine and oxaliplatin \[Gem/Ox\]) and autologous hematopoietic cell transplant (HCT) works in treating patients with large B-cell lymphoma (LBCL) that has come back after a period of improvement (relapsed) or that has not responded to previous treatment (refractory). Epcoritamab, a type of bispecific T-cell engager, binds to a protein called CD3, which is found on T cells (a type of white blood cell). It also binds to a protein called CD20, which is found on B cells (another type of white blood cell) and some lymphoma cells. This may help the immune system kill cancer cells. Carboplatin is in a class of medications known as platinum-containing compounds. It works in a way similar to the anticancer drug cisplatin, but may be better tolerated than cisplatin. Carboplatin works by killing, stopping or slowing the growth of cancer cells. Oxaliplatin is in a class of medications called platinum-containing antineoplastic agents. It damages the cell's deoxyribonucleic acid (DNA) and may kill cancer cells. Rituximab is a monoclonal antibody. It binds to a protein called CD20, which is found on B cells and some types of cancer cells. This may help the immune system kill cancer cells. Chemotherapy drugs, such as ifosfamide, etoposide phosphate, cytarabine, and gemcitabine, work in different ways to stop the growth of cancer cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Dexamethasone is in a class of medications called corticosteroids. It is used to reduce inflammation and lower the body's immune response to help lessen the side effects of chemotherapy drugs. An autologous HCT is a procedure in which blood-forming stem cells (cells from which all blood cells develop) are removed, stored, and later given back to the same person. Giving epcoritamab in combination with SOC platinum-based chemotherapy, such as RICE, RDHAP/X and Gem/Ox, and autologous HCT may kill more cancer cells in patients with relapsed or refractory LBCL.
This early phase I trial tests the safety and side effects of allogeneic CMV-specific CD19-CAR T cells plus CMV-MVA vaccine and how well it works in treating patients with high-risk acute lymphoblastic leukemia after a matched related donor (allogeneic) hematopoietic stem cell transplant (alloHSCT). Chimeric antigen receptor (CAR) T-cell therapy is a type of treatment in which T cells (a type of immune system cell) are changed in the laboratory so they will attack cancer cells. T cells are taken from a patient's blood, in this study, the T cells are cytomegalovirus (CMV) specific. Then the gene for a special receptor that binds to a certain protein, CD19, on the patient's cancer cells is added to the CMV-specific T cells in the laboratory. The special receptor is called a CAR. Large numbers of the CAR T cells are grown in the laboratory and given to the patient by infusion for treatment of certain cancers. Vaccines made from three CMV tumor associated antigens, may help the body build an effective immune response to kill cancer cells. Giving allogeneic CMV-specific CD19-CAR T cells plus CMV-MVA vaccine after matched related alloHSCT may be safe, tolerable, and/or effective in treating patients with high-risk acute lymphoblastic leukemia.
The investigators will conduct a pilot feasibility and efficacy trial of a newly developed family health communication tool (called Let's Get REAL) in increasing youth involvement in real-time stem cell transplant and cellular therapy decisions (SCTCT). The investigators will pilot the intervention among 24 youth and their parents, stratified by youth age (stratum 1, 8-12 years of age and stratum 2, 13-17 years of age).
This is a prospective, longitudinal, non-therapeutic study which includes routine assessment for long-term effects, as per FDA guidelines after receipt of an allogeneic HCT or autologous genetically modified cellular products for hemoglobin disorders. Primary objective: - To provide long term follow up, for individuals with hemoglobin disorders undergoing allogeneic hematopoietic stem cell transplantation (HCT) or receipt of an autologous genetically modified cellular product to treat their hemoglobinopathy. For individuals receiving a genetically modified cellular product, this long term follow up study is in accordance with the guidelines provided by the Food and Drug Administration (FDA).
This phase III trial tests how well the addition of dinutuximab to Induction chemotherapy along with standard of care surgical resection of the primary tumor, radiation, stem cell transplantation, and immunotherapy works for treating children with newly diagnosed high-risk neuroblastoma. Dinutuximab is a monoclonal antibody that binds to a molecule called GD2, which is found on the surface of neuroblastoma cells, but is not present on many healthy or normal cells in the body. When dinutuximab binds to the neuroblastoma cells, it helps signal the immune system to kill the tumor cells. This helps the cells of the immune system kill the cancer cells, this is a type of immunotherapy. When chemotherapy and immunotherapy are given together, during the same treatment cycle, it is called chemoimmunotherapy. This clinical trial randomly assigns patients to receive either standard chemotherapy and surgery or chemoimmunotherapy (chemotherapy plus dinutuximab) and surgery during Induction therapy. Chemotherapy drugs administered during Induction include, cyclophosphamide, topotecan, cisplatin, etoposide, vincristine, and doxorubicin. These drugs work in different ways to stop the growth of cancer cells, either by killing the cells, by stopping them from dividing or by stopping them from spreading. Upon completion of 5 cycles of Induction therapy, a disease evaluation is completed to determine how well the treatment worked. If the tumor responds to therapy, patients receive a tandem transplantation with stem cell rescue. If the tumor has little improvement or worsens, patients receive chemoimmunotherapy on Extended Induction. During Extended Induction, dinutuximab is given with irinotecan, temozolomide. Patients with a good response to therapy move on to Consolidation therapy, when very high doses of chemotherapy are given at two separate points to kill any remaining cancer cells. Following, transplant, radiation therapy is given to the site where the cancer originated (primary site) and to any other areas that are still active at the end of Induction. The final stage of therapy is Post-Consolidation. During Post-Consolidation, dinutuximab is given with isotretinoin, with the goal of maintaining the response achieved with the previous therapy. Adding dinutuximab to Induction chemotherapy along with standard of care surgical resection of the primary tumor, radiation, stem cell transplantation, and immunotherapy may be better at treating children with newly diagnosed high-risk neuroblastoma.
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.
This phase I trial studies the safety and side effects of cytomegalovirus (CMV) specific CD19-chimeric antigen receptor (CAR) T-cells along with the CMV-modified vaccinia Ankara (MVA) triplex vaccine following a stem cell transplant in treating patients with high grade B-cell non-Hodgkin lymphoma. CAR T-cells are a type of treatment in which a patient's T-cells (a type of immune system cell) are changed in the laboratory so they will attack cancer cells. T-cells are taken from a patient's blood. Then the gene for a special receptor that binds to a certain protein on the patient's cancer cells is added in the laboratory. The special receptor is called a chimeric antigen receptor (CAR). Large numbers of the CAR T-cells are grown in the laboratory and given to the patient by infusion. Vaccines such as CMV-MVA triplex are made from gene-modified viruses and may help the body build an effective immune response to kill cancer cells. Giving CMV-specific CD19-CAR T-cells plus the CMV-MVA triplex vaccine following a stem cell transplant may help prevent the cancer from coming back.
This phase I trial studies the side effects and best dose of loncastuximab tesirine in combination with carmustine, etoposide, cytarabine, and melphalan (BEAM) chemotherapy regimen in treating patients with diffuse large B-cell lymphoma that has come back (recurrent) or has not responded to treatment (refractory). Loncastuximab tesirine is a monoclonal antibody that may interfere with the ability of cancer cells to grow and spread. Chemotherapy drugs, such as carmustine, etoposide, cytarabine, and melphalan, work in different ways to stop the growth of cancer cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Giving chemotherapy with loncastuximab tesirine may kill more cancer cells.
This phase II trials studies the effect of treosulfan-based versus clofarabine-based conditioning regimens before donor hematopoietic stem cell transplant in treating patients with myelodysplastic syndromes or acute myeloid leukemia. Chemotherapy drugs, such as treosulfan, fludarabine, and clofarabine, work in different ways to stop the growth of cancer cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Giving chemotherapy and total-body irradiation before a donor hematopoietic stem cell transplant helps kill cancer cells in the body and helps make room in the patient's bone marrow for new blood-forming cells (stem cells) to grow. When the healthy stem cells from a donor are infused into a patient, they may help the patient's bone marrow make more healthy cells and platelets and may help destroy any remaining cancer cells. This study may help doctors determine whether treosulfan-based or clofarabine-based conditioning regimen works better before donor hematopoietic stem cell transplant in treating patients with myelodysplastic syndromes or acute myeloid leukemia.