471 Clinical Trials for Various Conditions
This phase I trial studies the side effects and best dose of CD4+ and CD8+ HA-1 T cell receptor (TCR) (HA-1 T TCR) T cells in treating patients with acute leukemia that persists, has come back (recurrent) or does not respond to treatment (refractory) following donor stem cell transplant. T cell receptor is a special protein on T cells that helps them recognize proteins on other cells including leukemia. HA-1 is a protein that is present on the surface of some peoples' blood cells, including leukemia. HA-1 T cell immunotherapy enables genes to be added to the donor cells to make them recognize HA-1 markers on leukemia cells.
This phase I trial studies the side effects of huJCAR014 in treating patients with relapsed or refractory B-cell non-Hodgkin lymphoma or acute lymphoblastic leukemia. huJCAR014 CAR-T cells are made in the laboratory by genetically modifying a patient's T cells and may specifically kill cancer cells that have a molecule CD19 on their surfaces. In Stage 1, dose-finding studies will be conducted in 3 cohorts: 1. Aggressive B cell NHL 2. Low burden ALL 3. High burden ALL In Stage 2, studies may be conducted in one or more cohorts to collect further safety, PK, and efficacy information at the huJCAR014 dose level(s) selected in Stage 1 for the applicable cohort(s). There are two separate cohorts for stage 2: 1. Cohort 2A, CAR-naïve (n=10): patients who have never received CD19 CAR-T cell therapy. 2. Cohort 2B, CAR-exposed (n=27): patients who have previously failed CD19 CAR-T cell therapy.
The main purpose of this investigational research study is to determine how safe and tolerable the study drug volasertib is in combination with liposomal vincristine (Marqibo; an FDA-approved drug) in patients with relapsed/refractory acute lymphoblastic leukemia. While VSLI demonstrated an overall response rate of 35% in Acute Lymphoblastic Leukemia (ALL) patients that had failed to respond to or relapsed after chemotherapy, combining it with other agents may increase clinical benefit. Volasertib inhibits proteins involved in the cell cycle that are increased in ALL. When volasertib inhibits these proteins ALL cells die. In the laboratory, volasertib has been shown to increase activity of vincristine against ALL cells. Therefore, we think the combination of volasertib and VSLI will be more effective against your leukemia than either drug used alone. This study will try to find out what effects, good and/or bad, this drug combination has on the patient and their cancer, and to find a dose that may be used in future studies.
The purpose of this research study is to determine the acceptable upper limit dose of nivolumab in combination with dasatinib that may be given to patients with relapsed/refractory philadelphia chromosome positive acute lymphoblastic leukemia (Ph+ ALL). Nivolumab is currently Food and Drug Administration (FDA) approved for other cancers, but has not yet been investigated in Ph+ ALL. Dasatinib is currently FDA approved for the treatment of Ph+ ALL, but has not yet been investigated in combination with nivolumab for this disease. There is evidence that dasatinib not only blocks the Philadelphia chromosome or breakpoint cluster region-Abelson murine leukemia viral oncogene homolog 1 (BCR-ABL) mutation, but also increases the activity of cells in your immune system. Nivolumab increases T cells in your immune system, which allows your immune system to attack the cancer. We think the combination of these drugs will be more effective against your leukemia than either drug used alone.
This phase II clinical trial studies how well personalized natural killer (NK) cell therapy works after chemotherapy and umbilical cord blood transplant in treating patients with myelodysplastic syndrome, leukemia, lymphoma or multiple myeloma. This clinical trial will test cord blood (CB) selection for human leukocyte antigen (HLA)-C1/x recipients based on HLA-killer-cell immunoglobulin-like receptor (KIR) typing, and adoptive therapy with CB-derived NK cells for HLA-C2/C2 patients. Natural killer cells may kill tumor cells that remain in the body after chemotherapy treatment and lessen the risk of graft versus host disease after cord blood transplant.
This phase II trial studies how well sapanisertib works in treating patients with acute lymphoblastic leukemia that has returned after a period of improvement (relapsed) or has not responded to previous treatment (refractory). Sapanisertib may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth.
This phase II trial studies how well T cell depleted donor peripheral blood stem cell transplant works in preventing graft-versus-host disease in younger patients with high risk hematologic malignancies. Giving chemotherapy and total-body irradiation before a donor peripheral blood stem cell transplant helps stop the growth of cancer cells. It may also stop the patient's immune system from rejecting the donor's stem cells. When the healthy stem cells from a donor are infused into the patient they may help the patient's bone marrow make stem cells, red blood cells, white blood cells, and platelets. Sometimes the transplanted cells from a donor can make an immune response against the body's normal cells. Removing a subset of the T cells from the donor cells before transplant may stop this from happening.
RATIONALE: Studying a diagnostic biomarker test in blood samples from patients who have undergone a donor stem cell transplant for cancer may help doctors plan treatment. PURPOSE: This clinical trial is studying an immunologic diagnostic blood test to see how well it works in predicting side-effects in patients with hematologic cancer or other disorders who have undergone a donor stem cell transplant.
The investigators postulate that Pevonedistat will be effective in patients with relapsed/refractory acute lymphoblastic leukemia (ALL) when combined with a standard backbone ALL chemotherapy regimen.
This is a Phase I, multi-center, open-label, dose escalation, MTD study of liposomal annamycin in children and young adults with refractory or relapsed ALL or AML. Enrollment will occur in cohorts of approximately 3 subjects with 10 additional subjects enrolled at the MTD. The liposomal annamycin doses will be escalated in sequential cohorts. Six dose levels of liposomal annamycin are planned: 130, 160, 190, 230, 280, and 310 mg/m2/day.The primary objectives of this study are 1) to evaluate the safety and identify the maximum tolerated dose (MTD) of liposomal annamycin when given in 3 consecutive daily doses, starting at 130 mg/m2/day and ranging to as high as 310 mg/m2/day, or the MTD, whichever is lower, in children and young adults with refractory or relapsed acute lymphocytic leukemia (ALL) or acute myelogenous leukemia (AML), and 2) to evaluate the antileukemic activity of liposomal annamycin in children and young adults with refractory or relapsed ALL or AML. The secondary objective is to measure the pharmacokinetics of annamycin and its metabolite, annamycinol.
This is a Phase I, open-label, non-randomized, dose escalation study in adolescents and adults with relapsed/refractory acute myeloid leukemia, acute lymphoblastic leukemia, or mixed phenotype acute leukemia. Patients will receive continuous oral MRX-2843 in 28 day cycles at predefined dose cohorts.
This phase I trial studies the best dose and side effects of CD19/CD22 chimeric antigen receptor (CAR) T cells when given together with chemotherapy, and to see how well they work in treating children or young adults with CD19 positive B acute lymphoblastic leukemia that has come back or does not respond to treatment. A CAR is a genetically-engineered receptor made so that immune cells (T cells) can attack cancer cells by recognizing and responding to the CD19/CD22 proteins. These proteins are commonly found on B acute lymphoblastic leukemia. Drugs used in chemotherapy, such as fludarabine phosphate and cyclophosphamide, 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 CD19/CD22-CAR T cells and chemotherapy may work better in treating children or young adults with B acute lymphoblastic leukemia.
This phase I trial studies the side effects and best dose of CPI-613 (6,8-bis\[benzylthio\]octanoic acid) when given together with bendamustine hydrochloride and rituximab in treating patients with B-cell non-Hodgkin lymphoma that has come back or has not responded to treatment. Drugs used in chemotherapy, such as 6,8-bis(benzylthio)octanoic acid and bendamustine hydrochloride, 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. Monoclonal antibodies, such as rituximab, may find cancer cells and help kill them. Giving 6,8-bis(benzylthio)octanoic acid with bendamustine hydrochloride and rituximab may kill more cancer cells.
This phase I trial studies the side effects and best dose of CPI-613 when given together with bendamustine hydrochloride in treating patients with relapsed or refractory T-cell non-Hodgkin lymphoma or Hodgkin lymphoma. CPI-613 may kill cancer cells by turning off their mitochondria, which are used by cancer cells to produce energy and are the building blocks needed to make more cancer cells. By shutting off mitochondria, CPI-613 may deprive the cancer cells of energy and other supplies needed to survive and grow. Drugs used in chemotherapy, such as bendamustine hydrochloride, 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 CPI-613 with bendamustine hydrochloride may kill more cancer cells.
This phase I trial studies the side effects and the best dose of genetically modified T-cells after lymphodepleting chemotherapy in treating patients with acute myeloid leukemia or blastic plasmacytoid dendritic cell neoplasm that has returned after a period of improvement or has not responded to previous treatment. An immune cell is a type of blood cell that can recognize and kill abnormal cells in the body. The immune cell product will be made from patient or patient's donor (related or unrelated) blood cells. The immune cells are changed by inserting additional pieces of deoxyribonucleic acid (DNA) (genetic material) into the cell to make it recognize and kill cancer cells. Placing a modified gene into white blood cells may help the body build an immune response to kill cancer cells.
This phase II trial studies how well ibrutinib works in treating patients with B-cell acute lymphoblastic leukemia that has come back after treatment or has not responded to other treatment. Ibrutinib may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth.
This phase I trial studies the side effects and best dose of ibrutinib in treating B-cell non-Hodgkin lymphoma that has returned or does not respond to treatment in patients with human immunodeficiency virus (HIV) infection. Ibrutinib may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth. It is not yet known whether it is safe for patients with HIV infection to receive ibrutinib while also taking anti-HIV drugs.
This phase I trial studies the side effects and best dose of inotuzumab ozogamicin when given together with combination chemotherapy in treating patients with relapsed or refractory acute leukemia. Immunotoxins, such as inotuzumab ozogamicin, can find cancer cells that express cluster of differentiation (CD)22 and kill them without harming normal cells. Drugs used in chemotherapy, such as cyclophosphamide, vincristine sulfate, and prednisone, work in different ways to stop the growth of cancer cells, either by killing the cells or by stopping them from dividing. Giving inotuzumab ozogamicin together with combination chemotherapy may kill more cancer cells.
This phase I/II trial studies the side effects and best dose of laboratory treated T cells to see how well they work in treating patients with chronic lymphocytic leukemia, non-Hodgkin lymphoma, or acute lymphoblastic leukemia that have come back or have not responded to treatment. T cells that are treated in the laboratory before being given back to the patient may make the body build an immune response to kill cancer cells.
This study evaluates the value of bortezomib in combination with specified chemotherapies for the treatment of patients with relapsed or refractory acute lymphoblastic leukemia. Bortezomib may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth.
RATIONALE: Drugs used in chemotherapy, such as cytarabine and clofarabine, work in different ways to stop the growth of cancer cells, either by killing the cells or by stopping them from dividing. Giving more than one drug (combination chemotherapy) may kill more cancer cells. PURPOSE: This phase II trial is studying clofarabine when given together with cytarabine to see how well they work in treating patients with refractory or relapsed acute myeloid leukemia or acute lymphoblastic leukemia.
This phase I trial studies the side effects and the best dose of deglycosylated ricin A chain-conjugated anti-cluster of differentiation (CD)19/anti-CD22 immunotoxins when given together with cytarabine in treating patients with B-cell acute lymphoblastic leukemia that has come back after a period of improvement (relapsed) or does not respond to treatment (refractory). Immunotoxins, such as deglycosylated ricin A chain-conjugated anti-CD19/anti-CD22 immunotoxins, can find certain cancer cells and kill them without harming normal cells. Drugs used in chemotherapy, such as cytarabine, 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 deglycosylated ricin A chain-conjugated anti-CD19/anti-CD22 immunotoxins with cytarabine may kill more cancer cells.
This phase I/II trial is studying the side effects and best dose of entinostat when given together with imatinib mesylate and to see how well it works in treating patients with relapsed or refractory Philadelphia chromosome-positive acute lymphoblastic leukemia. Entinostat and imatinib mesylate may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth
This phase I/II trial studies the side effects and the best dose of veliparib when given together with bendamustine hydrochloride and rituximab and to see how well they work in treating patients with lymphoma, multiple myeloma, or solid tumors that have come back or have not responded to treatment. Veliparib may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth. Drugs used in chemotherapy, such as bendamustine hydrochloride, work in different ways to stop the growth of cancer cells, either by killing the cells or by stopping them from dividing. Monoclonal antibodies, such as rituximab, can block cancer growth in different ways. Some find cancer cells and help kill them or carry cancer-killing substances to them. Others interfere with the ability of cancer cells to grow and spread. Giving veliparib together with bendamustine hydrochloride and rituximab may kill more cancer cells.
This phase I trial studies the side effects and best dose of entinostat when given together with clofarabine in treating patients with newly diagnosed, relapsed, or refractory poor-risk acute lymphoblastic leukemia or bilineage/biphenotypic leukemia. Entinostat may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth. Drugs used in chemotherapy, such as clofarabine, work in different ways to stop the growth of cancer cells, either by killing the cells or by stopping them from dividing. Giving entinostat with clofarabine may kill more cancer cells.
This is a Pilot/Phase I, single arm, single center, open label study to determine the safety, efficacy and cellular kinetics of CART19 (CTL019) in chemotherapy resistant or refractory CD19+ leukemia and lymphoma subjects. The study consists of three Phases: 1) a Screening Phase, followed by 2) an Intervention/Treatment Phase consisting of apheresis, lymphodepleting chemotherapy (determined by the Investigator and based on subject's disease burden and histology, as well as on the prior chemotherapy history received), infusions of CTL019, tumor collection by bone marrow aspiration or lymph node biopsy (optional, depending on availability), and 3) a Follow-up Phase. The suitability of subjects' T cells for CTL019 manufacturing was determined at study entry. Subjects with adequate T cells were leukapheresed to obtain large numbers of peripheral blood mononuclear cells for CTL019 manufacturing. The T cells were purified from the peripheral blood mononuclear cells, transduced with TCR-ζ/4-1BB lentiviral vector, expanded in vitro and then frozen for future administration. The number of subjects who had inadequate T cell collections, expansion or manufacturing compared to the number of subjects who had T cells successfully manufactured is a primary measure of feasibility of this study. Unless contraindicated and medically not advisable based on previous chemotherapy, subjects were given conditioning chemotherapy prior to CTL019 infusion. The chemotherapy was completed 1 to 4 days before the planned infusion of the first dose of CTL019. Up to 20 evaluable subjects with CD19+ leukemia or lymphoma were planned to be dosed with CTL019. A single dose of CTL019 (consisting of approximately 5x10\^9 total cells, with a minimal acceptable dose for infusion of 1.5x10\^7 CTL019 cells) was to be given to subjects as fractions (10%, 30% and 60% of the total dose) on Day 0, 1 and 2. A second 100% dose of CTL019 was initially permitted to be given on Day 11 to 14 to subjects, providing they had adequate tolerance to the first dose and sufficient CTL019 was manufactured.
RATIONALE: Monoclonal antibodies, such as epratuzumab, can block cancer growth in different ways. Some block the ability of cancer cells to grow and spread. Others find cancer cells and help kill them or carry cancer-killing substances to them. Drugs used in chemotherapy, such as cytarabine and clofarabine, work in different ways to stop the growth of cancer cells, either by killing the cells or by stopping them from dividing. Giving epratuzumab together with cytarabine and clofarabine may kill more cancer cells. PURPOSE: This phase II trial is studying the side effects and how well giving epratuzumab together with cytarabine and clofarabine works in treating patients with relapsed or refractory acute lymphoblastic leukemia.
This is a phase I dose escalation study of DT2219ARL for the treatment of relapsed or refractory B-lineage leukemia and lymphoma. Patients will receive a single course of DT2219ARL as a 4 hour infusion on days 1, 3, 5, and 8. Weekly follow-up will continue through day 29, at which time a disease reassessment will be done. For patients in remission, follow-up will continue monthly until disease progression or start of a new treatment. Otherwise day 29 will be the final study visit if there is no ongoing toxicity. This phase I study will use Continual Reassessment Method (CRM) to establish a maximum tolerated dose (MTD) of DT2219ARL. Up to 3 dose levels will be tested with an additional dose level (-1) if dose level 1 proves too toxic. The goal of CRM is to identify the dose level which correspondences to a desired toxicity rate of 33% or less using grade 3 or 4 capillary leak syndrome and any grade 3 or greater toxicity attributed to DT2219ARL as the targeted toxicity (based on CTCAE version 4).
This phase II trial studies giving rituximab before and after a donor peripheral blood stem cell transplant in patients with B-cell lymphoma that does not respond to treatment (refractory) or has come back after a period of improvement (relapsed). Monoclonal antibodies, such as rituximab, can interfere with the ability of cancer cells to grow and spread. Giving rituximab before and after a donor peripheral blood stem cell transplant may help stop cancer from coming back and may help keep the patient's immune system from rejecting the donor's stem cells.
RATIONALE: Panobinostat may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth. PURPOSE: This phase II trial is studying the side effects of panobinostat and to see how well it works in treating patients with relapsed or refractory acute lymphoblastic leukemia or acute myeloid leukemia.