13 Clinical Trials for Various Conditions
This phase I trial studies the side effects and best dose of ganetespib when given together with paclitaxel, carboplatin, and radiation therapy in treating patients with stage II-III esophageal cancer. Ganetespib may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth. Drugs used in chemotherapy, such as paclitaxel and carboplatin, work in different ways to stop the growth of tumor cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Radiation therapy uses high-energy x-rays to kill tumor cells and shrink tumors. Giving ganetespib in combination with paclitaxel, carboplatin, and radiation therapy may be a better treatment for patients with esophageal cancer.
Background: - Mithramycin is a drug that was first tested as a cancer therapy in the 1960s. It acted against some forms of cancer, but was never accepted as a treatment. Research suggests that it may be useful against some cancers of the chest, such as lung and esophageal cancer or mesothelioma. Researchers want to see if mithramycin can be used to treat these types of cancer. Objectives: - To see if mithramycin is safe and effective against different chest cancers. Eligibility: - Individuals at least 18 years of age who have lung, esophagus, pleura, or mediastinum cancers. Design: * Participants will be screened with a physical exam and medical history. Blood and urine samples will be collected. Imaging studies and tumor tissue samples will be used to monitor the cancer before treatment. * Participants will receive mithramycin every day for 7 days, followed by 7 days without treatment. Each 14-day round of treatment is called a cycle. * Treatment will be monitored with frequent blood tests and imaging studies. * Participants will continue to take the drug for as long as the side effects are not severe and the tumor responds to treatment.
The purpose of this Phase I study is to determine the recommended phase 2 dose (RP2D) and safety profile of NBTXR3 activated by radiation therapy with concurrent chemotherapy for the treatment of patients with esophageal adenocarcinoma. NBTXR3 is a drug that when activated by radiation therapy, may cause targeted destruction of cancer cells. Radiation therapy uses high energy x-rays to kill tumor cells and shrink tumors. Chemotherapy drugs, such as oxaliplatin, fluorouracil, capecitabine, docetaxel, paclitaxel, and carboplatin, work in different ways to stop the growth of tumor cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Giving NBTXR3 activated by radiation therapy with concurrent chemotherapy may help control the disease.
The goal of this clinical research study is to learn if giving chemotherapy and radiation therapy before surgery for early-stage esophageal cancer can help to control the disease and if so, for how long. The safety of this treatment will also be studied.
The goal of this clinical research study is to learn how safe and effective proton-beam therapy (PBT) may be in comparison to intensity modulated radiation therapy (IMRT) in combination with chemotherapy in patients with esophageal cancer. PBT and IMRT are both forms of radiation therapy that are designed to treat a specific area of the body while affecting as little of the surrounding normal tissue as possible. PBT is a newer technology that is designed to further reduce the amount of radiation that affects the surrounding normal tissue. However, this is still being studied.
Our goal is to develop a reliable, physician and patient-friendly, pre-operative Thoracic Onco-Geriatric Assessment (TOGA) to predict surgical risk in geriatric oncology patients with thoracic neoplasms of the lung, esophagus, pleura and thymus, modeled upon existing CGA tools, including the Preoperative Assessment of Cancer in the Elderly (PACE)
Background: * Chromatin is is the structural building block of a chromosome. It is found inside the nucleus of the cell and consists of a complex of DNA and protein. * Cancers of the lung, pleura (lung lining) and esophagus show profound changes in chromatin structure that may affect the course of disease in patients. * A better understanding of these diseases and the genetic changes associated with them may be helpful in developing new treatments for them. Objectives: * To evaluate people with cancer of the lung, pleura or esophagus for participation in NCI clinical trials. * To obtain biopsies (small pieces of tissue) from tumor, normal tissue and blood samples to learn more about the cellular changes in blood and tissue in tumors of the lung, esophagus and pleura and surrounding structures in the chest. Eligibility: Patients 2 years of age and older with cancer of the lung, esophagus, pleura, mediastinum or chest wall, or cancers of other origin that have invaded the lung. Note: Patients \>= 2 years of age and under 18 years of age may only participate in research sample collection. Design: * Up to 1310 patients may be included in this study. * Patients undergo standard tests for evaluating the stage of their disease and for determining eligibility for an NCI investigational treatment study. * All patients undergo bronchoscopy and bronchoalveolar lavage ("washing" with salt water) to assess their tumor and collect a sample of normal tissue. Patients whose tumor is located on the outside portion of the lung may also undergo thoracoscopy to obtain a tumor sample. For bronchoscopy and bronchoalveolar lavage a tube with a light is passed through the nose or mouth into the lungs to examine the airways. Salt water is injected through the tube and then withdrawn to obtain cells for laboratory studies. For the thoracoscopy a small tube with a light is put through a small hole in the chest to obtain the tumor sample. Both procedures are usually done under general anesthesia. The tissue is examined to identify cell characteristics of people who respond to certain therapies and to identify markers on the surface of the tissue that may be useful in future research and treatment. * Blood and urine samples are collected from patients. * Patients who are eligible for a treatment study at NCI are offered participation in the study. * Patients for whom standard surgery, radiation or chemotherapy is more appropriate may receive treatment at NCI or with their own physician. * Patients who receive treatment at NCI return for follow-up examinations 4 weeks after discharge and then every 2 to 4 months depending on the nature of their cancer.
This study assesses for early signs of damage to the heart following chest radiation therapy using both imaging (cardiac magnetic resonance imaging and cardiac positron emission tomography) and changes in blood biomarkers. This study determines if any changes in the heart muscle can be detected either during the course of radiation therapy or shortly thereafter using specialized imaging techniques or blood tests. Cardiac magnetic resonance imaging may be used to help provide information about changes in the heart structure and function following radiation therapy. Positron emission tomography looks at differences in how the heart takes up radioactive sugar which is injected into the vein to assess changes in heart function following radiation therapy. This study may help identify patients at risk of heart issues following radiation therapy to the chest and ultimately help in the development of more effective and safe treatments for cancer in the future.
Background: During recent years, cancer-testis (CT) antigens (CTA), particularly those encoded by genes on the X chromosome (CT-X genes), have emerged as attractive targets for cancer immunotherapy. Whereas malignancies of diverse histologies express a variety of CTAs, immune responses to these proteins appear uncommon in cancer patients, possibly due to low-level, heterogeneous antigen expression, as well as immunosuppressive regulatory T cells present within tumor sites and systemic circulation of these individuals. Conceivably, vaccination of cancer patients with tumor cells expressing high levels of CTAs in combination with regimens that deplete or inhibit T regulatory cells will induce broad immunity to these antigens. In order to examine this issue, patients with primary lung and esophageal cancers, pleural mesotheliomas, thoracic sarcomas, thymic neoplasms and mediastinal germ cell tumors, as well as sarcomas, melanomas, germ cell tumors, or epithelial malignancies metastatic to lungs, pleura or mediastinum with no evidence of disease (NED) or minimal residual disease (MRD) following standard multidisciplinary therapy will be vaccinated with H1299 tumor cell lysates with Iscomatrix adjuvant. Vaccines will be administered with or without metronomic oral cyclophosphamide (50 mg by mouth (PO) twice a day (BID) x 7day (d) every (q) 14d), and celecoxib (400 mg PO BID). Serologic responses to a variety of recombinant CTAs as well as immunologic responses to autologous tumor or epigenetically modified autologous Epstein-Barr virus (EBV) transformed lymphocytes will be assessed before and after a six month vaccination period. Primary Objectives: 1. To assess the frequency of immunologic responses to CTAs in patients with thoracic malignancies following vaccinations with H1299 cell lysate/Iscomatrix(TM) vaccines alone in comparison to patients with thoracic malignancies following vaccinations with H1299 cell lysate/Iscomatrix vaccines in combination with metronomic cyclophosphamide and celecoxib. Secondary Objectives: 1. To examine if oral metronomic cyclophosphamide and celecoxib therapy diminishes the number and percentage of T regulatory cells and diminishes activity of these cells in patients with thoracic malignancies are at risk of recurrence. 2. To examine if H1299 cell lysate/Iscomatrix(TM) vaccination enhances immunologic response to autologous tumor or epigenetically modified autologous EBV-transformed lymphocytes (B cells). Eligibility: * Patients with histologically or cytologically proven small cell or non-small cell lung cancer (SCLC;NSCLC), esophageal cancer (EsC), malignant pleural mesothelioma (MPM), thymic or mediastinal germ cell tumors, thoracic sarcomas, or melanomas, sarcomas, or epithelial malignancies metastatic to lungs, pleura or mediastinum who have no clinical evidence of active disease (NED), or minimal residual disease (MRD) not readily accessible by non-invasive biopsy or resection/radiation following standard therapy completed within the past 26 weeks. * Patients must be 18 years or older with an Eastern Cooperative Oncology Group (ECOG) performance status of 0 - 2. * Patients must have adequate bone marrow, kidney, liver, lung and cardiac function. * Patients may not be on systemic immunosuppressive medications at time vaccinations commence. Design: * Following recovery from surgery, chemotherapy, or chemo/radiotherapy (XRT), patients with NED or MRD will be vaccinated via IM injection with H1299 cell lysates and Iscomatrix(TM) adjuvant monthly for 6 months. * Vaccines will be administered with or without with metronomic oral cyclophosphamide and celecoxib. * Systemic toxicities and immunologic response to therapy will be recorded. Pre and post vaccination serologic and cell mediated responses to a standard panel of CT antigens as well as autologous tumor cells (if available) and EBV-transformed lymphocytes will be assessed before and after vaccination. * Numbers/percentages and function of T regulatory cells in peripheral blood will be assessed before, during, and after vaccinations. * Patients will be followed in the clinic with routine staging scans until disease recurrence. * The trial will randomize 28 evaluable patients per arm to either receive vaccine alone or vaccine plus chemotherapy in order to have 80% power to determine if the frequency of immune responses on the combination arm exceeds that of the vaccine alone arm, if the expected frequencies of immune responses on the two arms were 20% and 50%, using a one-sided 0.10 alpha level Fisher's exact test. * Approximately 60 patients will be accrued to this trial.
RATIONALE: Comparing results of diagnostic procedures, such as computed tomography scan (CT scan), done before and after radiation therapy to help detect movement of the esophagus may help doctors plan the best treatment. PURPOSE: This clinical trial is using CT scan to help detect movement of the esophagus in patients undergoing radiation therapy to the chest.
ActivSight™ combines an innovative form factor and proprietary software to deliver precise, objective, real-time visualization of blood flow and tissue perfusion intraoperatively for laparoscope-based surgery. A small adaptor that fits between any existing laparoscope and camera systems and a separate light source placed along any current commercial system will deliver objective real-time tissue perfusion and blood flow information intraoperatively. Primary Objective: To determine the feasibility of ActivSight™ in detecting and displaying tissue perfusion and blood flow in the conduit and foregut anastomoses in esophageal resection/reconstructive surgery. The investigators will compare the precision and accuracy among the naked eye inspection, ICG and LSCI in assessing the vascularity of the conduit.
The goal of this clinical research study is to learn if glutamine can help control and prevent sores, blisters, or inflammation in your mouth or esophagus due to your current treatment. In this study, glutamine will be compared to a placebo. A placebo is not a drug. It looks like the drug but is not designed to treat any disease or illness. It is designed to be compared with a study drug to learn if the study drug has any real effect.
The goal of this clinical research study is to learn if the level of nitric oxide you breathe out may relate to the amount of breathing complications that you may experience due to radiation treatment.