View clinical trials related to Neoplasm Metastasis.
Filter by: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.
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 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.
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.
The suppression of IGF-I and growth hormone may significantly alter the pathobiology of osteosarcoma. SMS 201-955 pa LAR is a long acting analog of Somatostatin which inhibits the pituitary release of growth hormone, reducing levels of circulating IGF-I . Additional data on tamoxifen usage has also demonstrated a reduction in circulating IGF-I levels. The degree of suppression of IGF-I and growth hormone will be determined at two dose levels of SMS 291-955 pa LAR. Tamoxifen will be added to two of the cohorts to determine if the additive effects of tamoxifen and SMS 201-955 pa LAR will lead to additional reduction of circulating IGF-I and growth hormone levels. Arginine-stimulated GH tests to assess levels of growth hormone in the blood will be administered pre-treatment evaluation up to three times, one time on weeks 2, 8, 16, 28, 40, 52, and one month post last dose of SMS 201-955 pa LAR. The four cohorts for this study will receive 60 or 90 mg SMS 201-955 pa LAR injectable every four weeks for up to 52 weeks. Two of the cohorts will receive 10 mg Tamoxifen on a daily basis.
Tumors of the spine can be described as primary, meaning that the tumor originated from cells normally found in the spine, or metastatic, cells from another area of the body that have spread to the spine. Metastatic tumors are more common than primary tumors. Tumors of the spine can press against the spinal cord and interfere with information traveling down from the brain to the nerves of the spinal cord. As a result, patients with spinal tumors can suffer from loss of movement and sensation within areas of the body below the tumor. In addition, tumors of the spine are typically painful conditions. Presently, the treatment of choice for spinal tumors is radiation therapy. However, many tumors of the spine become resistant to radiation therapy. In addition, because the spinal cord is often so close to the tumor it can be damaged by the radiation. Absolute (100%) ethanol is commonly known as "alcohol". It is the same kind of alcohol found in alcoholic beverages. When pure alcohol is injected directly into a tumor it can destroy cells and blood vessels. Because of this feature, researchers would like to test the effectiveness of alcohol in treating patients with spinal tumors. Researchers believe that intratumoral ethanol injection is a treatment worth studying more closely because it is minimally invasive, has been proven to be an effective treatment for other types of metastatic tumors, can be used repeatedly, and does not interfere with other treatments such as surgery. In addition to testing the effectiveness of intratumoral ethanol injection, this study will attempt to determine the causes of pain associated with spinal tumors.
Malignant brain tumors are responsible for a significant amount of deaths in children and adults. Even with advances in surgery, radiation therapy, and chemotherapy, many patients diagnosed with a malignant brain tumor survive only months to weeks. In an attempt to improve the prognosis for these patients, researchers have developed a new approach to brain tumor therapy. This approach makes use of DNA technology to transfer genes sensitive to therapy into the cells of the tumor. Infections with the herpes simplex virus can cause cold sores in the area of the mouth. A drug called ganciclovir (Cytovene) can kill the virus. Ganciclovir is effective because the herpes virus contains a gene (Herpes-Thymidine Kinase TK gene) that is sensitive to the drug. Researchers have been able to separate this gene from the virus. Using DNA technology, researchers hope to transfer and implant the TK gene into tumor cells making them sensitive to ganciclovir. In theory, giving patients ganciclovir will kill all tumor cells that have the TK gene incorporated into them.
The clinical study entitled "A Phase I Study of Infusional Chemotherapy with the P-glycoprotein Antagonist PSC 833" seeks to determine the maximum tolerated dose for a proposed P-glycoprotein antagonist, PSC 833. PSC 833 is a cyclosporine analogue which is purportedly non-nephrotoxic and non-immunosuppressive. It has been shown in in-vitro studies to enhance chemosensitivity as well as cyclosporine and to be far better at increasing intracellular drug accumulation than the concentrations of verapamil which are clinically achievable. The purpose of this study is to define the maximum tolerated dose in combination with vinblastine, and to determine how the drug affects the pharmacokinetics of vinblastine. PSC 833 will most likely reduce the clearance of vinblastine, as reported for the parent compound, cyclosporine. This effect will increase the area under the curve (AUC) of vinblastine, may increase toxicity, and requires that the escalation scheme for PSC 833 be a conservative one. Initially, a 120 hour infusion of vinblastine will be given alone. Then 8 days of PSC 833 will follow to allow monitoring of adverse effects of PSC 833 alone. This first cycle of vinblastine will be given in the absence of PSC 833; in second and subsequent cycles both agents will be combined. Escalation of the PSC 833 will continue until a target concentration is reached, or until the maximum tolerated dose is reached. Clinical responses will be monitored in order to provide the best possible medical care to our patients.
This is a phase I/II study of interleukin-1, G-CSF and high dose ICE chemotherapy with autologous bone marrow transplant in patients with relapsed breast, testicular and lymphoid cancers. The initial goal of this study was to define the toxicity of interleukin-1 administered for 7 days prior to ICE chemotherapy. A total of 22 patients have been treated with IL-1 and ICE and results showed a more rapid engraftment (4.5 days) with IL-1. A second cohort of 18 patients also received G-CSF and engraftment was further shortened in some subgroups. Overall, the median time to engraftment was 16 days with both IL-1 and G-CSF. Accrual will continue to further define the toxicity and efficacy of this regimen.
This is a phase I study to determine the maximal tolerated dose of IL-3 given alone or sequentially with GM-CSF following FLAC chemotherapy in metastatic breast cancer patients.