View clinical trials related to Metastatic Cancers.
Filter by:To find out if combining psychoeducational interventions (such as education, counseling, and self-managed therapies) with an open-label placebo can help to improve your quality of life better than either the psychoeducational interventions or the placebo alone.
Adult patients with metastatic or locally advanced solid malignancies (including but not limited to breast, cancer, lung adenocarcinoma or squamous cell carcinoma, colorectal cancer, ovarian cancer, renal clear cell cancer, skin cutaneous melanoma), presenting or having presented an exceptional and unexpected response to an antineoplastic targeted therapy.
This is a national, multicenter, cross-sectional epidemiological study in adult Spanish participants diagnosed with advanced or metastatic melanoma.
Vertebral augmentation with radiotherapy to increase the functional status and quality of life for patients with vertebral body metastatic cancers.
Patients with metastatic or unresectable locally advanced malignancies harboring BRAF genomic alterations, the biological target of vemurafenib, and who are no more amenable to curative treatment. To explore the efficacy of vemurafenib as a single agent across diverse type of tumors guided by the presence of identified activating molecular alterations in the vemurafenib target gene, per cohort.
Phase I clinical trial of hypofractionated radiotherapy to an isolated index lesion in combination with the PD-1 inhibitor, Pembrolizumab in patients with metastatic cancers who have failed anti-PD-1 therapy (melanoma and NSCLC) and patients with metastatic cancers who have have progressed after at least one regimen of systemic therapy (breast, pancreas, and other).
The genomic heterogeneity of cancers implies that to effectively use targeted therapies the investigators will need to assess each individual cancer and match it to a biologically relevant targeted therapy. The investigators will use full genome sequencing to try to identify cancer "drivers" and corresponding drugs that may inhibit these pathways.
T cells can penetrate virtually every biologic space and have the power to dispose of normal or malignant cells as seen in viral and autoimmune diseases and in the rare spontaneous remis-sions of cancer. However, T cells are easily tolerized to self or tumor antigens and "immune surveillance" has manifestly failed in every cancer that is clinically apparent. It is the goal of these studies to supply the specificities and affinities to patient T cells without regard for their "endogenous" T cell receptor repertoire, directed by antibody-defined recognition to kill malignant cells based on their expression of antigen. We will achieve this by preparing chimeric IgCD28TCR genes in mammalian expression vectors to yield "designer T cells" from normal patient cells. This extends the approach of Anderson, Rosenberg and co-workers to introduce or augment expression of genes in patients' T cells in a therapeutic setting. Prior studies in model systems demonstrated that recombinant IgCD28TCR could direct modified T cells to respond to antigen targets with IL2 secretion, cellular proliferation, and cytotoxicity, the hallmarks of an effective, self-sustaining immune response. It therefore becomes of paramount interest to extend these studies to a human system of widespread clinical relevance to explore the clinical potential of this new technology. The target antigen for these studies is carcinoembryonic antigen (CEA) which is predominantly expressed on tumors of the colon and rectum, breast, pancreas and other sites.