33 Clinical Trials for Various Conditions
This phase II trial compares the impact of subcutaneous (SC) nivolumab given in an in-home setting to an in-clinic setting on cancer care and quality of life. Currently, most drug-related cancer care is conducted in clinic type centers or hospitals which may isolate patients from family, friends and familiar surroundings for many hours per day. This separation adds to the physical, emotional, social, and financial burden for patients and their families. Traveling to and from medical facilities costs time, money, and effort and can be a disadvantage to patients living in rural areas, those with low incomes or poor access to transport. Studies have shown that cancer patients often feel more comfortable and secure being cared for in their own home environments. SC nivolumab in-home treatment may be safe, tolerable and/or effective when compared to in-clinic treatment and may reduce the burden of cancer and improve the quality of life in cancer patients.
This phase I trial investigates the impact of cefazolin before surgery on the microbiome in patients with stage I-II melanoma. Antibiotics, such as cefazolin, given at the time of surgery may cause a significant change in the microbes (like bacteria and viruses) found in the stomach and intestines. This trial may help researchers learn if any changes in microbes affect the body's ability to respond to surgery and cancer.
This phase I trial investigates the effects of influenza vaccine in treating patients with stage I-IV melanoma. While intramuscular administration of influenza vaccine provides immunization against the influenza virus, giving influenza vaccine directly into the tumor (intralesional) may decrease the size of the injected melanoma tumor, or the extent of the melanoma within the body.
This trial studies the role of the gut microbiome and effectiveness of a fecal transplant on medication-induced gastrointestinal (GI) complications in patients with melanoma or genitourinary cancer. The gut microbiome (the bacteria and microorganisms that live in the digestive system) may affect whether or not someone develops colitis (inflammation of the intestines) during cancer treatment with immune-checkpoint inhibitor drugs. Studying samples of stool, blood, and tissue from patients with melanoma or genitourinary cancer may help doctors learn more about the effects of treatment on cells, and help doctors understand how well patients respond to treatment. Treatment with fecal transplantation may help to improve diarrhea and colitis symptoms.
This trial studies how well Young Melanoma Family Facebook intervention or Healthy Lifestyle Facebook intervention works in improving skin examination in participants with melanoma and their families. Young Melanoma Family Facebook intervention or Healthy Lifestyle Facebook intervention may help improve total cutaneous examinations, skin self-examinations, and sun protection among first degree relatives of young onset participants and the participants themselves.
This phase II trial studies the effect of a vaccine called CDX-1401 given with or without a biologic drug called CDX-301 in treating patients with stage IIB-IV melanoma. The cancer vaccine CDX-1401 attaches to a protein that is made in tumor cells. The vaccine helps the body recognize the tumor to fight the cancer. The biologic drug CDX-301 may help the body make more of the tumor fighting cells, known as dendritic cells. Another biologic drug, poly-ICLC, may stimulate the immune system and help these dendritic cells mature so that they can recognize the tumor. Giving CDX-301 may make the immune response to a combination of CDX-1401 and poly-ICLC better.
This randomized phase III trial studies sargramostim or vaccine therapy alone to see how well they work compared to sargramostim and vaccine therapy together in preventing disease recurrence in patients with melanoma that has been removed by surgery. Sargramostim may stimulate the immune system in different ways and stop tumor cells from growing. Vaccines made from peptides may help the body build an effective immune response to kill tumor cells. It is not yet known whether yeast derived sargramostim and vaccine therapy are more effective alone or together in preventing recurrence of melanoma.
This randomized phase III trial studies sargramostim before sentinel lymph node biopsy to see how well it works compared to hypertonic saline before sentinel lymph node biopsy in treating patients with melanoma. Biological therapies, such as sargramostim, may stimulate the immune system in different ways and stop cancer cells from growing. It is not yet known whether sargramostim is more effective than hypertonic saline in treating patients with stage IB-II melanoma undergoing sentinel lymph node biopsy.
This pilot clinical trial studies vaccine therapy and resiquimod in treating patients with stage II-IV melanoma that has been removed by surgery. Vaccines made from peptides may help the body build an effective immune response to kill tumor cell tumor cells. Biological therapies, such as resiquimod, may stimulate the immune system in different ways and stop tumor cells from growing. It is not yet known whether Gag:267-274 peptide vaccine and resiquimod are more effective when given together or separately
This phase II trial studies how well giving dabrafenib alone and in combination with trametinib before surgery works in treating patients with advanced melanoma that can be removed by surgery. Studying samples of tumor tissue in the laboratory from patients receiving dabrafenib and trametinib may help doctors learn more about the effects of these drugs on cells and help identify biomarkers that determine which patients will respond to these drugs best.
This phase II trial is studying how well saracatinib works in treating patients with stage III or stage IV melanoma that cannot be removed by surgery. Saracatinib may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth
This randomized phase II trial is studying vaccine therapy and sargramostim to see how well they work compared to vaccine therapy alone in treating patients who have undergone surgery for stage IIB, stage IIC, stage III, or stage IV melanoma. Vaccines made from peptides may make the body build an immune response to kill tumor cells. Colony-stimulating factors such as sargramostim increase the number of immune cells found in bone marrow or peripheral blood. Combining vaccine therapy with sargramostim may make a stronger immune response.
This pilot phase II trial studies how well giving vaccine therapy works in treating patients with stage IIC-IV melanoma. Vaccines made from melanoma peptides or antigens may help the body build an effective immune response to kill tumor cells
This randomized pilot phase II trial studies how well vaccine therapy works in treating human leukocyte antigen class 1 histocompatibility, A-2 (HLA-A2) positive patients with melanoma. Vaccines made from peptides may help the body build an effective immune response to kill tumor cells.
This phase II trial studies how well nivolumab works in treating patients with stage IIB-IIC melanoma that can be removed by surgery. Monoclonal antibodies, such as nivolumab, may interfere with the ability of tumor cells to grow and spread.
This clinical trial studies how well an interactive tailored website works in promoting sun protection and skin self-check behaviors in patients with stage 0-III melanoma. An internet-based program may help individuals to perform skin self-checks and engage in sun protection behaviors.
This pilot clinical trial studies intravital microscopy in identifying tumor vessels in patients with stage IB-IIIC melanoma undergoing sentinel lymph node biopsy. By examining sentinel lymph nodes through intravital microscopy before they are removed, doctors may learn specific information regarding how melanoma may spread to lymph nodes and other sites of the body.
This randomized pilot clinical trial studies melanoma antigen recognized by T-cells 1 (MART-1) antigen with or without toll-like receptor 4 (TLR4) agonist glucopyranosyl lipid A-stable oil-in-water emulsion (GLA-SE) in treating patients with stage II-IV melanoma that has been removed by surgery. Vaccines made from MART-1a peptide or antigen may help the body build an effective immune response to kill tumor cells. Giving TLR4 agonist GLA-SE with MART-1 antigen may help increase the immune response to MART-1a antigen.
This pilot clinical trial studies booster vaccination in preventing disease recurrence in previously vaccinated patients with melanoma that has been removed by surgery. Vaccines made from peptides may help the body build an effective immune response to kill tumor cells. Giving booster vaccinations may make a stronger immune response and prevent or delay the recurrence of cancer.
This pilot clinical trial studies intravital microscopy for identifying tumor vessels in patients with stage IA-IV melanoma that is being removed by surgery. New imaging procedures, such as intravital microscopy, may determine the extent of melanoma.
This phase I trial studies the side effects and best schedule of vaccine therapy with or without sirolimus in treating patients with cancer-testis antigen (NY-ESO-1) expressing solid tumors. Biological therapies, such as sirolimus, may stimulate the immune system in different ways and stop tumor cells from growing. Vaccines made from a person's white blood cells mixed with tumor proteins may help the body build an effective immune response to kill tumor cells that express NY-ESO-1. Infusing the vaccine directly into a lymph node may cause a stronger immune response and kill more tumor cells. It is not yet known whether vaccine therapy works better when given with or without sirolimus in treating solid tumors.
This pilot clinical trial studies recombinant interferon alfa-2b in treating patients with melanoma. Recombinant interferon alfa-2b may interfere with the growth of tumor cells and slow the growth of melanoma
The purpose of this study is to determine how safe and how well POL-103A works in preventing the relapse of melanoma after patients who have undergone surgery.
The overall goal of this study is to find out about the safety of injecting the genes (DNA) for human and mouse tyrosinase in patients with melanoma. There is no evidence yet that injection of tyrosinase DNA results in any clinical benefit. Tyrosinase is the substance found in melanoma cells that helps to produce their black color. The DNA used in this study was purified from bacteria which contains the gene for tyrosinase. DNA is material which contains the information needed to produce many substances in the body.
This is a pilot trial to investigate the use of GM-CSF DNA as an adjuvant for peptide vaccination in patients with metastatic melanoma. The objective of this study is to determine the safety and adjuvant effect of vaccination with the gene coding for human GM-CSF with a multi-epitope melanoma peptide vaccine (tyrosinase and gp100 peptides) in patients with AJCC stage IIB, IIC, III and IV melanoma who are HLA-A2+. We will assess whether use of GM-CSF DNA is safe and generates an immune response to peptides derived from antigens on melanoma cells.
RATIONALE: Vaccines made from DNA may help the body build an effective immune response to kill tumor cells. Giving the vaccine in different ways may make a stronger immune response and kill more tumor cells. PURPOSE: This randomized clinical trial is studying two different ways of giving vaccine therapy to compare how well they work in treating patients with stage IIB, stage IIC, stage III, or stage IV melanoma.
RATIONALE: Vaccines made from DNA may make the body build an effective immune response to kill tumor cells. PURPOSE: This randomized phase I trial is studying the side effects and best dose of vaccine therapy in treating patients with stage IIB, stage IIC, stage III, or stage IV melanoma.
RATIONALE: Vaccines may make the body build an immune response to kill tumor cells. Colony-stimulating factors such as sargramostim may increase the number of immune cells found in bone marrow or peripheral blood. Combining vaccine therapy with sargramostim may cause a stronger immune response and kill more tumor cells. PURPOSE: This randomized phase II trial is studying vaccine therapy and sargramostim to see how well they work compared to vaccine therapy alone in treating patients with stage II B, stage IIC, stage III, or stage IV melanoma.
This study is researching an experimental drug called REGN3767, also known as fianlimab (R3767), when combined with another medication called cemiplimab (each individually called a "study drug" or called "study drugs" when combined) compared with an approved medication called pembrolizumab. The objective of this study is to see if the combination of fianlimab and cemiplimab is an effective treatment compared to pembrolizumab in patients that have had melanoma removal surgery but are still at high risk for the recurrence of the disease. Pembrolizumab is an approved treatment in some countries in this clinical setting. The study is looking at several other research questions, including: * What side effects may happen from receiving the study drugs. * How much study drug is in the blood at different times. * Whether the body makes antibodies against the study drug (which could make the drug less effective or could lead to side effects). Antibodies are proteins that are naturally found in the blood stream that fight infections. * How administering the study drugs might improve quality of life.
This study is being done to see if the investigators can help the immune system to work against melanoma. A dendritic cell is another type of white blood cell. It has most, if not all, of the proteins needed to make T cells work to destroy cancer cells. However, dendritic cells do not normally have the cancer proteins on their surface. The challenge then is to combine the antigens with dendritic cells to make a vaccine. The investigators think that the body's T cells might then react against the tumor and help destroy it. This study will see if altered dendritic cells will make T cells work against tumor cells. The dendritic cells will be made in a lab and will carry the antigens. These cells then will be injected under the skin. In this study, the investigators are trying to help the body make a stronger immune response against the cancer. The patient will get the same kind of dendritic cell vaccine used in the earlier study, but with one major difference. The dendritic cells will contain messenger-RNA (mRNA). Cells use mRNA to make proteins. The mRNA will be put into dendritic cells by a laboratory method called electroporation. The mRNA is never given to the patient directly. This mRNA will help the dendritic cell make a tumor antigen like what the cancer expresses. The dendritic cell can then put this tumor antigen on its surface so that the body could make a stronger immune response against the tumor.