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Neoplasm Metastasis clinical trials

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NCT ID: NCT00001832 Completed - Melanoma Clinical Trials

Lymphocyte Re-infusion During Immune Suppression to Treat Metastatic Melanoma

Start date: August 1999
Phase: Phase 2
Study type: Interventional

This experiment will test the safety and effectiveness of a treatment for melanoma in which certain lymphocytes (a type of white blood cell) are taken from the patient, grown in the laboratory, and returned after the patient's immune system has been weakened with immune-suppressing drugs. Some patients will also receive interleukin-2 (IL-2), a drug that may enhance the activity of the re-infused lymphocytes. Patients with metastatic melanoma (melanoma whose tumor has spread) who have been treated unsuccessfully with gp100 vaccination may participate in this study. They will undergo apheresis or a tumor biopsy, or both, to collect lymphocytes. In apheresis, whole blood is drawn through a needle in the arm. A machine separates the blood components and removes the white cells. The rest of the blood is returned to the donor through a needle in the other arm. A biopsy is a surgical procedure to remove a small piece of tumor tissue. Several weeks before the lymphocytes are collected, patients will receive injections of growth colony stimulating factor (G-CSF) every day for five days. This drug stimulates white cell production, permitting as many cells as possible to be obtained during collection. The lymphocytes will then be grown in larger numbers in the laboratory. Seven days before the cells are re-infused, the patient is admitted to the hospital and a catheter (small tube) is placed in a large vein in the chest or neck. Two drugs, cyclophosphamide and fludarabine, are given through the tube. These drugs suppress the immune system so that it will not interfere with the work of the reinfused lymphocytes. The lymphocytes are then injected through the catheter over a 30-minute period. After the infusion, patients who receive IL-2 will be given the drug in a high dose over a 15-minute period every eight hours for up to five days. Patients whose condition does not permit high-dose IL-2, such as those with a heart condition or lung problem, may receive a low-dose regimen, with the drug given as a shot under the skin of the thigh or abdomen for five days followed by a 2-day break, continuing for a total of six weeks. These patients receive a higher dose the first week and then half that dose the next five weeks. Blood and tissue samples will be taken before and during the study to evaluate the size of the tumor and assess treatment. If, 3-5 weeks after therapy is completed, the patient's tumor has stabilized or shrunk, the entire treatment, except for chemotherapy, may be repeated two more times.

NCT ID: NCT00001705 Completed - Melanoma Clinical Trials

Immunization of Patients With Metastatic Melanoma Using the GP100 Peptide Preceded by an Endoplasmic Reticulum Insertion Signal Sequence

Start date: July 1998
Phase: Phase 2
Study type: Interventional

Patients with metastatic melanoma who are HLA-A201+ will be immunized with a modified peptide from the gp100 molecule that contains a signal sequence designed to improve peptide presentation by antigen presenting cells. This peptide called gp100:ES209-217 (210M) will be administered either alone or in combination with high or low dose IL-2. Patients will be evaluated for clinical response, as well as undergo studies of the immunologic response to the peptide immunization.

NCT ID: NCT00001685 Completed - Melanoma Clinical Trials

Immunization of HLA-A201 Patients With Metastatic Melanoma Using a Combination of Immunodominant Peptides From Three Melanoma Antigens, MART-1, GP100 and Tyrosinase

Start date: November 1997
Phase: Phase 2
Study type: Interventional

This is a study of a melanoma tumor antigen peptide vaccine. Peptides representing HLA-A201 restricted T cell epitopes of the melanoma antigens, MART-1, gp100 and tyrosinase will be administered emulsified in Incomplete Freund's Adjuvant, (IFA) to HLA-A201 patients with melanoma. The study is designed to evaluate the potential therapeutic role, immunologic effects and toxicity of repeated doses of this peptide vaccine administered subcutaneously. Immune reactivity to the peptide epitope will be monitored in all patients by analysis of melanoma-specific T cell precursors prior to and after immunization.

NCT ID: NCT00001683 Completed - Lymphoma Clinical Trials

A Phase I Study of Oral COL-3 (NSC-683551), a Matrix Metalloproteinase Inhibitor, in Patients With Refractory Metastatic Cancer

Start date: October 1997
Phase: Phase 1
Study type: Interventional

Matrix metalloproteinases (MMPs) are a class of membrane bound enzymes that are involved in the degradation of the extracellular matrix. MMP-2 and MMP-9 have been associated with the progression of cancer. It is hypothesized than an imbalance between MMPs and MMP inhibitors allows the destruction of the extracellular matrix and enhances the ability of the tumor cells to grow and metastasize. By inhibiting MMPs, it is thought that angiogenesis and metastasis can be inhibited. This is a phase I study of COL-3, an oral matrix metalloproteinase inhibitor, in patients with refractory metastatic cancer. COL-3 is a chemically modified tetracycline derivative. Patients must have clinically progressive disease documented within 1 month prior to entry to be eligible for treatment. Patients must have also failed therapy of proven efficacy for their disease and have an ECOG performance status of less or equal than 2. Patients must be willing to travel from their home to the NIH for follow-up visits. Patients with brain metastases or primary CNS malignancies are not eligible. Concurrent therapy for their cancer (i.e., radiation therapy, chemotherapy, etc.) will preclude participation. We will be defining the maximum tolerated dose, the toxicity profile, characterizing the pharmacokinetics, and evaluating the effect of COL-3 on several biological endpoints.

NCT ID: NCT00001587 Completed - Neoplasm Metastasis Clinical Trials

A Phase I Study of Isolated Hepatic Portal and Arterial Perfusion (IHP) With Escalating Dose Melphalan for Primary or Metastatic Unresectable Cancers of the Liver

Start date: September 1997
Phase: Phase 1
Study type: Interventional

Patients with unresectable primary or metastatic cancer confined to the liver will undergo a 1 hour hyperthermic isolated hepatic perfusion (IHP) via the portal vein and hepatic artery with escalating dose melphalan. Patients eligible for this protocol are those with non-colorectal histologies and those with colorectal cancer previously treated with intra-arterial FUDR. Hepatic and systemic toxicity, response to treatment, duration of response, and survival will be followed.

NCT ID: NCT00001576 Completed - Neoplasm Metastasis Clinical Trials

A Phase I Study of Isolated Hepatic Perfusion With Escalating Dose Melphalan Followed by Postoperative Hepatic Arterial Floxuridine and Leucovorin for Metastatic Unresectable Colorectal Cancers of the Liver

Start date: July 1997
Phase: Phase 1
Study type: Interventional

Patients with unresectable metastatic colorectal cancer confined to the liver will undergo a 1 hour hyperthermic isolated hepatic perfusion (IHP) with escalating dose melphalan. Postoperatively, patients will be treated with hepatic arterial infusion of floxuridine (FUDR), 0.2 mg/kg/day and leucovorin (LV), 15 mg/M2/day as a 2-week continuous infusion regimen. Hepatic and systemic toxicity, response to treatment, duration of response, and survival will be followed.

NCT ID: NCT00001570 Completed - Neoplasm Metastasis Clinical Trials

A Phase I Study of Continuous Intravenous Infusion of PSC 833 and Vinblastine in Patients With Metastatic Renal Cancer

Start date: February 1997
Phase: Phase 1
Study type: Interventional

Bolus PSC 833 is administered on Day 1 simultaneously with initiation of 24 hour continuous infusion of PSC 833, followed by another continuous infusion lasting an additional 6 days. To ensure the safety of a 7 day infusion of PSC 833, one patient is treated for 5 days and a second for 6 days, before the first cohort is enrolled. Vinblastine is administered in escalating doses on days 2-5. At least 3 patients are entered at each dose level. The MTD will be defined as the dose immediately below that at which 2 patients experience dose limiting toxicity. Treatment continues every 28 days.

NCT ID: NCT00001507 Completed - Neoplasm Metastasis Clinical Trials

Chemotherapy and Progenitor Cell Transplantation to Treat Inflammatory Breast Cancer

Start date: July 12, 1996
Phase: Phase 1
Study type: Interventional

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.

NCT ID: NCT00001493 Completed - Breast Neoplasms Clinical Trials

Antimetabolite Induction, High-Dose Alkylating Agent Consolidation and Retroviral Transduction of the MDR1 Gene Into Peripheral Blood Progenitor Cells Followed by Intensification Therapy With Sequential Paclitaxel and Doxorubicin for Stage 4 Breast Cancer

Start date: October 1995
Phase: Phase 2
Study type: Interventional

This study examines the feasibility of using gene therapy to prevent some of the toxicities of an intensive chemotherapy regimen in patients with metastatic breast cancer. Patients who do not wish to participate in the gene therapy procedures will be offered identical chemotherapy on a different protocol. Patients will be treated initially with chemotherapy which is active against breast cancer, but which has a low potential to hurt blood-forming cells. Then, the patient will receive high dose chemotherapy, during which time blood cells which are capable of rebuilding patients' bone marrows will be removed from the patients' bloodstream. We will use these blood cell collections to isolate peripheral blood progenitor cells (PBPCs), those cells which are thought to be the forbears of all other blood cells. A portion of the PBPCs will be exposed to a disabled virus which either carries genetic material referred to as the multidrug resistance gene (MDR1). The virus will transfer the MDR1 gene into a portion of the patient's PBPCs. The purpose of putting the MDR1 gene into the patients' PBPCs is to try to make these blood cells and their offspring resistant to the toxic effects of certain types of breast cancer chemotherapy. The MDR1 protein (Pgp) that is made from the MDR1 gene makes cells resistant to chemotherapy in laboratory systems by pumping the drug out of cells before the drug is able to kill the cell. Another portion of the patients PBPCs will be exposed to a similar disabled virus carrying a different gene called the NeoR gene. The NeoR gene should not change the effects of chemotherapy on blood forming cells. The purpose of using the NeoR gene is that it will serve as a point of comparison, to see if the presence of the MDR1 drug resistance gene really helps blood forming cells withstand subsequent chemotherapy. Patients are then treated with a very high dose of another anti-breast cancer drug, one that is very toxic to bone marrow cells, and patients will then receive the frozen PBPCs, which contain the new genes, to help them recover from the chemotherapy. After recovery, patients will then be treated with high doses of paclitaxel (Taxol) and doxorubicin (Adriamycin) chemotherapy. Both of these drugs are very active against breast cancer, and the MDR1 gene may potentially protect bone marrow cells against these drugs. Samples of peripheral blood cells will be obtained before each of these doses of chemotherapy to determine whether the number of blood cells that contain the MDR1 gene in comparison to the number that contain the NeoR gene has increased in response to the chemotherapy.

NCT ID: NCT00001440 Completed - Neoplasm Metastasis Clinical Trials

Autologous T-Cell Transplantation and the Immunotherapy of Residual Disease in Breast Cancer: Pilot Study of Vaccine-Driven T-Cell Expansion in Patients Treated With Dose-Intensive Chemotherapy

Start date: July 1995
Phase: Phase 1
Study type: Interventional

The ability of chemotherapy to cure cancer, including breast cancer, has been limited by drug resistant residual tumor cells remaining after chemotherapy that generally result in relapse. Additional therapeutic strategies to eradicate these residual tumor cells are needed. The augmentation of specific anti-tumor immune responses, such as those mediated by T-cells, might represent such an additional strategy for the control or elimination of residual tumor cells. This approach might be especially effective if T-cell mediated responses were enhanced during both the period of T-cell repopulation that follows acute T-cell depletion and in the setting of minimal residual tumor burden present after dose intensive chemotherapy. Such chemotherapy is known to result in severe T-cell depletion. This pilot study has been designed to examine the feasibility of combining dose intensive chemotherapy with interventions aimed at the reconstitution of T-cell immunity. Metastatic or adjuvant breast cancer patients who have received dose intensive chemotherapy will subsequently receive a combination of autologous chemotherapy-naive T-cells, a patient-specific tumor antigen vaccine, and recombinant human interleukin-2. These interventions will be assessed for their ability to modulate T-cell number, T-cell function, and T-cell specificity during the period of T-cell repopulation. Such modulation may result in the effective reconstitution of generalized T-cell immunity with the generation of vaccine-specific anti-tumor T-cell responses.