23 Clinical Trials for Various Conditions
Background: - Sunitinib is drug that is approved for treating various types of cancers, including kidney cancers. However, it has not been approved to treat cancers of the thymus. Sunitinib works by blocking proteins that are responsible for cell division and growth. Some of these proteins can be found on thymus cancer cells. Researchers want to see if sunitinib can be used to treat advanced thymus cancer. It will be given to people who have had at least one earlier chemotherapy treatment containing platinum. Objectives: - To see if sunitinib is a safe and effective treatment for advanced thymus cancer that has not responded to earlier treatments. Eligibility: * Individuals at least 18 years of age who have advanced thymus cancer that has not responded to earlier treatments. * At least one previous cancer treatment must have been chemotherapy treatment containing platinum. Design: * Participants will be screened with a physical exam and medical history. Blood and urine samples will be collected. Imaging studies and tumor biopsies will be used to check the severity of the cancer. * Participants will take sunitinib tablets once a day, in the morning. They will take the tablets daily for 4 weeks, followed by 2 weeks of rest with no sunitinib. This 6-week period is called a cycle. * Treatment will be monitored with frequent blood tests and imaging studies. * Treatment cycles may be repeated as long as the tumor does not continue to grow and there are no severe side effects....
Background: - Individuals with cancer of the lung, chest cavity, ovary, or bladder, as well as patients who have been treated with adoptive cell therapy unfortunately commonly succumb to their disease. Some agree to donate their bodies to cancer research that may help the medical community better understand these diseases. Studies of cancer tumor tissue obtained soon after death may be used to answer questions about the origins, progression, and treatment of cancer. Researchers want to conduct a study that involves planned collection of cancer tumor tissue shortly after death. To do so, they will arrange to provide inpatient hospice care for people with lung cancer, ovarian cancer, bladder cancer, or patients who have been treated with adoptive cell therapy. \<TAB\> Objectives: - To collect cancer tissue biopsy samples as soon as possible after death. Eligibility: - Individuals who have cancer of the lung, chest cavity, ovary, or bladder, or those who have been treated with adoptive cell therapy and are planning to receive end-of-life hospice care are eligible to participate. Design: * Participants will agree to receive inpatient hospice care at the National Institutes of Health Clinical Center. Full details on end-of-life care preference will be acknowledged. * An autopsy will be performed at the clinical center within 3 hours of death. Tumor tissue will be collected from the primary site of cancer and from any areas of the body to which the cancer has spread. * Participants will not receive further cancer treatments as part of this study. This is a tissue collection study only....
A research study to learn about the biologic features of cancer development, growth, and spread. We are studying components of blood, tumor tissue, normal tissue, and other fluids, such as urine, cerebrospinal fluid, abdominal or chest fluid in patients with cancer. Our analyses of blood, tissue, and/or fluids may lead to improved diagnosis and treatment of cancer by the identification of markers that predict clinical outcome, markers that predict response to specific therapies, and the identification of targets for new therapies.
Background: Mesothelioma is an aggressive cancer that grows in the linings of the body; this can include the membranes that line the heart, lungs, and internal organs. Mesothelin (MSLN) is a protein that appears in high numbers in many tumors, including mesothelioma. Researchers are developing a new treatment that collects a person s own immune cells (T cells); the T cells are genetically modified to target and kill tumor cells with high levels of MSLN. Objective: To test a new treatment (TNhYP218 CAR T cells) in people with solid tumors including mesothelioma. Eligibility: People aged 18 and older with solid tumors including mesothelioma that returned or spread after standard treatment. Design: Participants will be screened. A small piece of tissue will be cut from a tumor (biopsy). The sample will be tested to see if it has enough MSLN. Participants will undergo leukapheresis: Blood will be taken from their body through a vein. The blood will pass through a machine that separates out the T cells. The remaining blood will be returned to the body through a different vein. Participant s T cells will be modified in a lab to produce TNhYP218 CAR T cells. Participants will enter the hospital. For 7 days, they will receive drugs to prepare their bodies for the study treatment. TNhYP218 CAR T cells will be administered into a vein. Participants will remain in the hospital for at least 7 more days. After discharge, participants will have follow-up visits for 5 years. These visits may include imaging scans, blood and heart tests, and a new biopsy. Long-term follow-up will continue another 10 years.
This exploratory study investigates how an imaging technique called 68Ga-FAPi-46 PET/CT can determine where and to which degree the FAPI tracer (68Ga-FAPi-46) accumulates in normal and cancer tissues in patients with cancer. Because some cancers take up 68Ga-FAPi-46 it can be seen with PET. FAP stands for Fibroblast Activation Protein. FAP is produced by cells that surround tumors (cancer associated fibroblasts). The function of FAP is not well understood but imaging studies have shown that FAP can be detected with FAPI PET/CT. Imaging FAP with FAPI PET/CT may in the future provide additional information about various cancers.
This study is to collect and validate regulatory-grade real-world data (RWD) in oncology using the novel, Master Observational Trial construct. This data can be then used in real-world evidence (RWE) generation. It will also create reusable infrastructure to allow creation or affiliation with many additional RWD/RWE efforts both prospective and retrospective in nature.
This study will determine the maximum-tolerated dose (MTD) for oral bosutinib when used in combination with pemetrexed. The MTD is the highest dose of bosutinib with pemetrexed that can be given without causing severe side effects. This study will also test the safety of this combination and see what effects (good or bad) it has on participants and their cancer.
Background: Mithramycin is a new cancer drug. In another study, people with chest cancer took the drug 6 hours a day for 7 straight days. Many of them had liver damage as a side effect. It was discovered that only people with certain genes got this side effect. Researchers want to test mithramycin in people who do not have those certain genes. Objectives: To find the highest safe dose of mithramycin that can be given to people with chest cancer who have certain genes over 24 hours instead of spread out over a longer period of time. To see if mithramycin given as a 24-hour infusion shrinks tumors. Eligibility: People ages 18 and older who have chest cancer that is not shrinking with known therapies, and whose genes will limit the chance of liver damage from mithramycin Design: Participants will be screened with: * Medical history * Physical exam * Blood and urine tests * Lung and heart function tests * X-rays or scans of their tumor * Liver ultrasound * Tumor biopsy * Participants will be admitted to the hospital overnight. A small plastic tube (catheter) will be inserted in the arm or chest. They will get mithramycin through the catheter over about 24 hours. * If they do not have bad side effects or their cancer does not worsen, they can repeat the treatment every 14 days. * Participants will have multiple visits for each treatment cycle. These include repeats of certain screening tests. * After stopping treatment, participants will have weekly visits until they recover from any side effects.
This phase II trial studies how well ribociclib works in treating patients with neuroendocrine tumors of the foregut, which includes the thymus, lung, stomach, and pancreas, that have spread to other places in the body and usually cannot be cured or controlled with treatment (advanced tumors). Ribociclib may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth.
This is a non-randomized clinical trial in patients with thymic carcinomas who failed prior systemic therapy. All subjects will receive pembrolizumab and epacadostat treatment in three week cycles until unacceptable toxicity, death, progressive disease or withdrawal.
The iCaRe2 is a multi-institutional resource created and maintained by the Fred \& Pamela Buffett Cancer Center to collect and manage standardized, multi-dimensional, longitudinal data and biospecimens on consented adult cancer patients, high-risk individuals, and normal controls. The distinct characteristic of the iCaRe2 is its geographical coverage, with a significant percentage of small and rural hospitals and cancer centers. The iCaRe2 advances comprehensive studies of risk factors of cancer development and progression and enables the design of novel strategies for prevention, screening, early detection and personalized treatment of cancer. Centers with expertise in cancer epidemiology, genetics, biology, early detection, and patient care can collaborate by using the iCaRe2 as a platform for cohort and population studies.
A research study of the drug amrubicin in patients with cancer of the thymus (thymoma or thymic carcinoma). We hope to learn whether this drug is an effective and safe treatment for thymic cancers.
We hope to determine the importance of different genes (including B receptors) in anthracycline-induced cardiomyopathy. This has important benefits to patients exposed to anthracyclines, as this could help determine whether certain individuals have increased susceptibility to cardiac injury.
Hypothesis 1- Using IMRT, the radiation therapy (RT) dose can be safely escalated from 58 Gy to 74 Gy given as 6 fractions/week with concurrent chemotherapy. Hypothesis 2- Esophageal motion can be used to customize planning organ at risk volumes. Hypothesis 3- Biological predictors of acute esophagitis can be used to identify patients at high risk of developing esophageal toxicity from radiation therapy and chemotherapy.
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)
This is a Phase 1, multiple dose, ascending dose escalation study to define a MTD/RD and regimen of XmAb20717, to describe safety and tolerability, to assess PK and immunogenicity, and to preliminarily assess anti-tumor activity of XmAb20717 in subjects with selected advanced solid tumors.
This phase III trial studies cabozantinib to see how well it works compared with placebo in treating patients with neuroendocrine or carcinoid tumors that may have spread from where it first started to nearby tissue, lymph nodes, or distant parts of the body (advanced). Cabozantinib is a chemotherapy drug known as a tyrosine kinase inhibitor, and it targets specific tyrosine kinase receptors, that when blocked, may slow tumor growth.
Background: * Cisplatin-containing chemotherapy is the standard treatment for advanced tumors of the thymus that cannot be removed surgically. * New treatment options are needed for patients with advanced tumors of the thymus that do not improve with cisplatin-containing therapy. * Belinostat is a drug that inhibits enzymes called histone deacetylase. Histone deacetylase inhibitors have shown promising activity in many cancers and may be useful in treating patients with thymic tumors. Objectives: -To assess the safety and effectiveness of belinostat for treatment of malignant thymic tumors in patients who failed after standard treatment. Eligibility: -Patients 18 years of age or older with an advanced thymic tumor that has progressed after treatment with platinum-containing chemotherapy. Design: * Patients receive belinostat treatment in 21-day cycles. The drug is given as an infusion through a vein during days 1 through 5 of each cycle. Treatment cycles continue as long as the medicine is tolerated and the cancer does not worsen. * Patients have a physical examination and several blood tests during every cycle. * Patients have an electrocardiogram every cycle before starting the belinostat infusion and again on the last day of the infusion. * Patients undergo computed tomography (CT) or other imaging test, such as ultrasound or MRI, every two cycles to evaluate the response of the tumor to treatment. * Tumor tissue obtained from a previous biopsy is used for research purposes.
This study will test the safety and effectiveness of two experimental medicines - depsipeptide and flavopiridol - given together to treat cancers of the lung, esophagus, and pleura. It will determine the highest dose that these drugs can safely be given together and will test whether giving them together works better at shrinking tumors than giving either one alone. Patients 18 years of age and older with cancer of the lung, esophagus, or pleura, or other cancers that have spread to the lungs or pleura may be eligible for this study. Candidates are screened with a medical history and physical examination, blood tests, electrocardiogram (EKG), x-rays and scans, pulmonary function tests, and a tumor biopsy (removal of a small piece of tumor tissue for microscopic examination). Participants are admitted to the hospital for treatment for approximately 10 days during each 28-day treatment cycle. Depsipeptide is infused through an arm vein or central venous catheter (tube placed in a large vein in the neck or chest) for 4 hours. When this infusion is complete, flavopiridol is infused over 72 hours. The dose of depsipeptide is increased four times over the period of the study with successive groups of patients, and flavopiridol is increased once to determine the maximum safe dose of giving these drugs together. Blood tests are done before and after each depsipeptide infusion and 3 more times for the next 24 hours, and at various times over 4 days during the flavopiridol infusion to evaluate the effects of the medicines. Samples are also drawn periodically throughout the treatment cycle to evaluate safety. Heart function is monitored with several EKGs before and during the depsipeptide doses. The drug has shown effects on EKG tracings, but does not appear to injure the heart muscle. Tumor biopsies are done before treatment begins and on the fifth day of the first treatment cycle. The biopsies may be done either in the operating room by passing a tube (bronchoscope) down the throat and into the lungs or in the Radiology Department using a thin needle put through the chest wall into the tumor. For the bronchoscopy, numbing medicine is sprayed into the back of the throat to reduce discomfort, and for the needle biopsy, the skin over the biopsy area is numbed. Optional repeat biopsies may be requested before the start of the second treatment cycle and on day 5 of that cycle. (The repeat biopsies are not required for participation in the study.) At the time of each tumor biopsy, a buccal mucosal biopsy is also done. This involves scraping a tongue depressor along the inside of the mouth to collect cells for examination. At the end of the first treatment cycle, patients return to NIH for evaluation with a physical examination, blood work, x-rays, and scans of the chest, abdomen, pelvis, and brain. Patients who are not experiencing significant drug side effects are offered a second cycle, exactly like the first. The two cycles complete one course of treatment, after which patients once again return to NIH for evaluation. Additional treatment cycles may be offered to patients whose tumors have shrunk or remained stable with therapy. Patients whose tumors have not responded to therapy or who have developed severe drug side effects are taken off the study.
This phase II trial tests how well ivonescimab works in treating patients with thymic carcinoma. Immunotherapy with monoclonal antibodies, such as ivonescimab, may help the body's immune system attack the cancer, and may interfere with the ability of tumor cells to grow and spread.
Determine the safety and effectiveness of Lu-177 DOTATOC in adult subjects with somatostatin receptor-expressing Pulmonary, Pheochromocytoma, Paraganglioma, Unknown primary, and Thymus neuroendocrine tumors or any other non-.GEP-NET. The treatment regimen will consist of 4 doses of 200 (±10%) mCi 177Lu-DOTATOC administered at 8+/- 1-week intervals.
The purpose of this study is to evaluate the safety, tolerability and effectiveness of selinexor in patients with advanced thymic epithelial tumor progressing after primary chemotherapy. This is a multicenter, open label phase II trial that uses a Simons two stage design. The study population is adults with histologically confirmed, advanced, inoperable TETs who are progressing after treatment with at least one platinum containing chemotherapy regimen. This study is comprised of 2 similar phase II trials, one running in US (25 patients) and one running in EU (25 patients): There are two study arms: Arm A: Thymoma * Stage 1: 15 patients * Stage 2: 10 patients Arm B: Thymic carcinoma * Stage 1: 15 patients * Stage 2: 10 patients
RATIONALE: Studying changes in thymus function in patients who have been undergoing androgen blockade therapy for prostate cancer may help doctors learn more about how well patients will respond to treatment, may help in planning cancer treatment, and may help the study of cancer in the future. PURPOSE: This clinical trial is studying the effect of androgen blockade therapy on thymus function in older patients who have undergone radical prostatectomy for localized prostate cancer.