Active clinical trials for "Liver Neoplasms"

Comprehensive preoperative planning and real-time intraoperative guidance are essential prerequisites for achieving precise liver resection. In pursuit of this goal, the investigators have developed innovative 3D printed liver models utilizing a physically crosslinked self-healing elastomer created through the copolymerization of 4-acryloylmorpholine (ACMO) and methoxy poly (ethylene glycol) acrylate (mPEGA). These printed models exhibit exceptional healing capabilities, efficiently restoring their structure within minutes at room temperature, and rapidly recovering within moments after being incised. Herein, the investigators aim to assess the viability of employing these 3D printed liver models as instrumental tools in designing the optimal surgical approach through an iterative trial-and-error methodology. Concurrently, the investigators aim to determine whether the integration of these 3D printed models into conventional methods (contrast-enhanced CT or MRI) can enhance the safety, ease, and efficiency of hepatic resection procedures.

PLATON (Platform for Analyzing Targetable Mutations) is a prospective, multicentre, observational cohort study with biobanking. In a first approach PLATON's pilot-study assesses genomic profiling in gastrointestinal cancer therapy and the frequencies of targetable mutations including Tumor Mutational Burden (TMB) and Microsatellite Instability Status (MSI), performing Next-generation deep sequencing (NGS) using the Foundation Medicine assays on tumor specimen and EDTA-whole blood samples. The Study Protocol does not define any further medical intervention or evaluate the efficacy or safety of the treatment decision made by the investigator. Another important objective of PLATON's pilot project is to evaluate whether and how many patients are treated based on their genomic profiles.

This proposal brings together multidisciplinary teams from four New York City institutions charged with reducing cancer disparities that affect approximately two million people residing in some of the most diverse and underserved communities in the United States. The intent of this collaborative research is captured by its acronym, DISRUPT: Diversity & IncluSion in Research Underpinning Prevention & Therapy Trials. To disrupt the norms that maintain heightened risk and poorer outcomes experienced by BIPOC, the research team propose three integrated and synergistic aims to improve diversity and inclusion in CTs through disruptive approaches at the community (Aim 1), provider, system and patient (Aim 2), and basic and translational scientist levels (Aim 3). All three aims focus on metrics for changing norms reified in institutional policies and established practice that will provide essential evidence to translate and scale these changes to institutions and networks involved in cancer treatment research. In Aim 1, the research team will partner with local organizations to formulate and disseminate new norms regarding cancer care and research and diffuse these new norms throughout the community via community organizations and Health Ambassadors bringing a different vantage point on CTs, raising awareness and increasing demand for access to cancer research. In Aim 2, the research team will create an electronic approach to identify key clinical characteristics of patients and trials and match patients and trials and bring these data to patients and their physicians at the time of key decisions. In Aim 3, the research team will provide and integrate essential experiential training in diversity, social determinants of health and the importance of conducting community-relevant work into basic and translational science training. This DISRUPT proposal provides the foundation to disrupt norms about cancer clinical trials in our communities, delivery systems and scientific research enterprises.

This study enrolls patients who have GPC3-positive solid tumors currently. Patients may be considered if the cancer has come back, has not gone away after standard treatment or the patient cannot receive standard treatment. This research study uses special immune system cells called GAP T cells, a new experimental treatment. 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. Antibodies are types of proteins that protect the body from infectious diseases and possibly cancer. T cells, also called T lymphocytes, are special infection-fighting blood cells that can kill other cells, including cells infected with viruses and tumor 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. Investigators have found from previous research that they can put a new gene into T cells that will make them recognize cancer cells and kill them. In preclinical studies, the investigators made several genes called a chimeric antigen receptor (CAR), from an antibody called GC33 that recognizes glypican-3, a proteoglycan found on solid tumors including pediatric liver cancers (GPC3-CAR). This study will test T cells genetically engineered with a GPC3-CAR (GAP T cells) in patients with GPC3-positive solid tumors (currently only enrolling liver tumors). The GAP T cells are an investigational product not approved by the Food and Drug Administration. The purpose of this study is to find the biggest dose of GAP T cells that is safe, to see how long they last in the body, to learn what the side effects are and to see if the GAP T cells will help people with GPC3-positive solid tumors. This study enrolls patients who have GPC3-positive solid tumors (currently only enrolling liver tumors).

This phase II trial studies how well software-aided imaging works in confirming tumor coverage with ablation (the removal or destruction of a body part or tissue or its function) on patients with liver tumors. The current standard for targeting tumor cells and evaluating the outcome of a liver ablation procedure is a visual inspection of the pre- and post-procedure computed tomography (CT) scans. Software-aided imaging systems, such as Morfeus, may help to improve the accuracy and effectiveness of liver ablation.

This is an open label, dose escalation and dose expansion study to evaluate the safety, tolerability, pharmacokinetics, and anti-tumor activity of STP705 administered intratumorally in cholangiocarcinoma, hepatocellular carcinoma or liver metastasis in subjects with advanced/metastatic or surgically unresectable solid tumors who are refractory to standard therapy. Goals: To determine the MTD or RP2D of STP705 when administered intratumorally into cholangiocarcinoma, hepatocellular carcinoma, or liver metastasis. To establish the dose of STP705 recommended for future phase 2 studies when administered intratumorally.

This phase 1 study is to determine the optimal dose and tolerability of a hypoxia-activating agent, tirapazamine, when it is combined with embolization in liver cancer. Liver cancer patients who are Child-Pugh score A, suitable for embolization with tumor no more than 4 nodules are eligible. Tirapazamine will be given by intra-arterial injection before embolization. Treatment effect is evaluated by MRI based on mRECIST criteria. Repeat treatment is necessary only if disease progression. Dose escalation cohort has been completed. Expansion cohort is open for metastatic liver dominant neuroendocrine tumor.

Many patients have cancers that have increased activity of a protein called STAT3 that contributes critically to the development and growth of their cancer. Despite our knowledge of STAT3's importance to cancer, scientists and doctors have not developed a drug that targets it and that patients can take to treat their cancer more effectively than treatments that are now available. Tvardi Therapeutics, Incorporated has developed a compound, TTI-101, which can be given by mouth and acts as a direct inhibitor of STAT3. Administration of TTI-101 to mice demonstrated that it blocked growth of cancers of the breast, head and neck, lung, and liver and it was safe when administered at high doses to mice, rats, and dogs. In this application, Tvardi is proposing to further develop TTI-101 for treatment of solid tumors for which the prognosis is dismal. The investigators will determine how safe it is when administered to patients with cancer, determine whether an adequate dose can be administered to patients with cancer that will block STAT3 in their cancer, and determine whether treatment with TTI-101 leads to reduced growth of their cancer.

This clinical trial studies the side effects and best way to perform yttrium Y-90 radioembolization in treating patients with liver cancer that has spread to other places in the body (metastatic). Yttrium Y-90 radioembolization is a therapy that injects radioactive microspheres directly into an artery that feeds liver tumors to cut off their blood supply. Performing yttrium Y-90 radioembolization in a single session may make treatment faster, minimize patient travel, and decrease the overall cost of the procedure.

This phase I/II trial studies the side effects of anti-CTLA4-NF monoclonal antibody (mAb) (BMS986218), nivolumab, and stereotactic body radiation therapy in treating patients with solid malignancies that has spread to other places in the body (metastatic). Immunotherapy with monoclonal antibodies, such as anti-CTLA4-NF mAb (BMS-986218) and nivolumab, may help the body's immune system attack the cancer, and may interfere with the ability of tumor cells to grow and spread. Stereotactic body radiation therapy uses special equipment to position a patient and deliver radiation to tumors with high precision. This method may kill tumor cells with fewer doses over a shorter period and cause less damage to normal tissue. Giving -CTLA4-NF mAb (BMS986218), nivolumab, and stereotactic body radiation therapy may kill more tumor cells.