Active clinical trials for "Sarcoma"

Prospective, open-label, dose-ranging, uncontrolled phase I/II study of Lurbinectedin in combination with irinotecan. The study will be divided into two stages: a Phase I dose escalation stage and a Phase II expansion stage.

This phase I trial studies the side effects and best dose of cord blood-derived expanded allogeneic natural killer cells (donor natural killer [NK] cells) and how well they work when given together with cyclophosphamide and etoposide in treating children and young adults with solid tumors that have come back (relapsed) or that do not respond to treatment (refractory). NK cells, white blood cells important to the immune system, are donated/collected from cord blood collected at birth from healthy babies and grown in the lab. Drugs used in chemotherapy, such as cyclophosphamide and etoposide, 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 NK cells together with cyclophosphamide and etoposide may work better in treating children and young adults with solid tumors.

This is an open-label, multi-institutional phase II randomized study comparing neoadjuvant radiotherapy followed by surgical resection to neoadjuvant pembrolizumab with concurrent radiotherapy, followed by surgical resection and adjuvant pembrolizumab. The total duration of pembrolizumab will be one year in the experimental arm.

A parallel-group randomized pilot trial at a single institution (Duke University) on the effect of postoperative hyperbaric oxygen therapy on wound healing in patients with soft tissue sarcoma undergoing surgical resection with neo-adjuvant radiation therapy.. Participants will be allocated to either the treatment group (HBOT) or control (standard of care) by computer-generated randomization, stratified by tumor size (≤10cm and >10cm). An unequal randomization of 2:1 will be utilized to provide experience prescribing HBOT to more patients.

This phase II Pediatric MATCH trial studies how well larotrectinib works in treating patients with solid tumors, non-Hodgkin lymphoma, or histiocytic disorders with NTRK fusions that may have spread from where it first started to nearby tissue, lymph nodes, or distant parts of the body (advanced) and have come back (relapased) or does not respond to treatment (refractory). Larotrectinib may stop the growth of cancer cells by blocking some of the enzymes needed for cell growth.

This study is for patients with neuroblastoma, sarcoma, uveal melanoma, breast cancer, or another cancer that expresses a substance on the cancer cells called GD2. The cancer has either come back after treatment or did not respond to treatment. Because there is no standard treatment at this time, patients are asked to volunteer in a gene transfer research study using special immune cells called T cells. T cells are a type of white blood cell that helps the body fight infection. The body has different ways of fighting infection and disease. No single way seems perfect for fighting cancers. This research study combines two different ways of fighting cancer: antibodies and T cells. Both antibodies and T cells have been used to treat patients with cancers. They have shown promise but have not been strong enough to cure most patients. We have found from previous research that we can put a new gene into T cells that will make them recognize cancer cells and kill them. In our last clinical trial we made a gene called a chimeric antigen receptor (CAR) from an antibody that recognizes GD2, a substance found on almost all neuroblastoma cells (GD2-CAR). We put this gene into the patients' own T cells and gave them back to 11 neuroblastoma patients. We saw that the cells did grow for a while, but started to disappear from the blood after 2 weeks. We think that if T cells are able to last longer they may have a better chance of killing GD2 positive tumor cells. Therefore, in this study we will add a new gene to the GD2 T cells that can cause the cells to live longer. T cells need substances called cytokines to survive and the cells may not get enough cytokines after infusion. We have added the gene C7R that gives the cells a constant supply of cytokine and helps them to survive for a longer period of time. In other studies using T cells, investigators found that giving chemotherapy before the T cell infusion can improve the amount of time the T cells stay in the body and therefore the effect the T cells can have. This is called lymphodepletion and we think that it will allow the T cells to expand and stay longer in the body, and potentially kill cancer cells more effectively. The GD2-C7R T cells are an investigational product not approved by the Food and Drug Administration. The purpose of this study is to find the largest safe dose of GD2-C7R T cells, and also to evaluate how long they can be detected in the blood and what affect they have on cancer.

sEphB-HSA may prevent tumor cells from multiplying and blocks several compounds that promote the growth of blood vessels that bring nutrients to the tumor. The purpose of this study is to learn if sEphB4-HSA will decrease the number or size of Kaposi sarcoma lesions in people.

Sarcoma which has spread to the lungs is most often treated with surgery. Even with surgery, most patients will not be cured and will die from their disease, probably because of small cancer cells that are present in the lungs at the time of surgery, but cannot be seen or detected. It is for this reason that we are looking for a better treatment. Giving chemotherapy after surgery is generally not recommended because it has significant side effects and no benefit has been proven. This study is investigating a new technique for delivering chemotherapy directly into the lungs at the time of surgery. Delivering chemotherapy directly to the lungs could potentially kill any microscopic cancer cells that are present in the lungs at the time of surgery, while sparing other major organs in the body from the side effects of chemotherapy. This technique is called In Vivo Lung Perfusion (IVLP). This is a Phase I, non-randomized, dose escalation study that will act as a pilot study for a larger prospective, multicenter, controlled clinical trial. Patients who have bilateral disease will have one lung undergo IVLP and the other lung will remain untreated with the IVLP (the other lung will be treated as current standard of care - either surgery or radiation) as a control lung. The patients will undergo a posterolateral thoracotomy. Lung metastases will be identified by visualization or palpation. After surgical isolation of the lung by proximal control of pulmonary artery and veins, IVLP will be initiated. After 3 hours of IVLP, the lung metastases will be removed in the usual fashion. Patients will be cared for post-surgery according to institutional standards. The patients will be followed for up to 2 years. The primary endpoint is safety. Secondary endpoints include additional safety endpoints and efficacy.

This phase II trial studies the side effects of hypofractionated radiation therapy in treating patients with soft tissue sarcomas prior to surgery. Hypofractionated radiation therapy delivers higher doses of radiation therapy over a shorter period of time and may kill more tumor cells and have fewer side effects.

The trial will use neoadjuvant hypofractionated radiotherapy followed by surgical resection in the treatment for soft tissue sarcoma. It will allow patients to be treated over a shorter course (5 or 15 days of radiation) compared to the traditional 5 week regimen. It is proposed that this will be possible without increasing the risk of wound complication or local recurrence compared with a traditional 5 week course of pre-operative radiation.