肿瘤科（内科）

以下为当前的临床试验。

按位置、状态和其他条件筛选该研究列表。

1. Protein-bound Paclitaxel, Cisplatin, And Gemcitabine (GCN) Combined with Tumor Treatment Fields (TTF) in Patients with Metastatic Pancreatic Adenocarcinoma

   Jacksonville, Fla.

   The purpose of this study is to assess the safety of a specific treatment regimen (protein-bound Paclitaxel, Cisplatin, And Gemcitabine (GCN)) combined with a device called Tumor Treatment Fields (TTF) in preventing tumor growth in paitents with recurrent recurrent and/or metastatic pancreatic cancer (met-PC).

2. A Study to Compare Treatment With the Drug Selumetinib Alone Versus Selumetinib and Vinblastine in Patients With Recurrent or Progressive Low-Grade Glioma

   Rochester, Minn.

   The primary objectives of this study are to determine the maximum tolerated dose/recommended phase 2 dose (MTD/RP2D) of selumetinib + vinblastine for children with progressive or recurrent LGGs, and to determine if selumetinib + vinblastine will lead to improved event-free survival (EFS) outcome compared with selumetinib alone for children with progressive or recurrent LGGs.

3. Combination Therapy of Acalabrutinib, Venetoclax and Durvalumab to Treat Richter Transformation

   Rochester, Minn.

   The purpose of this study is to determine if the drug combination of acalabrutinib, durvalumab, and venetoclax will work to treat Richter’s transformation, and what doses of these drugs are safe for people to take. We also want to learn about the side effects of this combination. All study subjects will receive acalabrutinib, durvalumab, and venetoclax. Acalabrutinib is FDA approved for treatment of chronic lymphocytic leukemia and small lymphocytic lymphoma. Durvalumab is FDA approved for treatment in lung cancers including  non-small cell lung cancer and small cell lung cancer. Venetoclax is FDA approved for the treatment of CLL and SLL. The drug combination of acalabrutinib, durvalumab, and venetoclax is experimental and isn’t approved by the U.S. Food and Drug Administration (FDA). However, the FDA has allowed the use of this drug in this research study.

4. Highly Selective CDK7 Inhibitor Q901 in Selected Advanced Solid Tumors

   Rochester, Minn., Jacksonville, Fla., Scottsdale/Phoenix, Ariz.

   The purpose of part one of this study is to determine the maximum tolerated dose (MTD), dose-limiting toxicities (DLTs), and safety profile of Q901 monotherapy when administered via intravenous (IV) infusion once-weekly (QW) for 4 weeks and once every 2 weeks (Q2W) thereafter. Also, to establish for future clinical development the recommended Phase 2 dose (RP2D) of Q901 monotherapy when administered via IV infusion QW for 4 weeks and Q2W thereafter. 

   The purpose of part two of this study is to evaluate safety and tolerability and evidence of anticancer activity of Q901 as monotherapy and in combination with pembrolizumab. In Part 2 Cohort 1, an expansion phase at the established RP2D will be undertaken in participants with selected advanced solid tumors. In Part 2 Cohort 2, a safety run in and expansion phase will be undertaken with Q901 at the RP2D administered in combination with pembrolizumab (400 mg Q6W) in participants with advanced solid tumors.

5. A Study to Evaluate Bleomycin, Carboplatin, Etoposide, or Cisplatin in Treating Pediatric and Adult Patients with Germ Cell Tumors

   Rochester, Minn.

   The purpose of this study is to evaluate how well bleomycin, carboplatin, etoposide, or cisplatin work in treating pediatric and adult patients with germ cell tumors. Active surveillance may help doctors to monitor subjects with low risk germ cell tumors after their tumor is removed. Drugs used in chemotherapy, such as bleomycin, carboplatin, etoposide, and cisplatin, 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.

6. A Study to Collect Surgical Tumor Samples for Prostate Cancer-derived Tissue Graft

   Rochester, Minn.

   The purposes of this study are to collect prostate surgical samples from metastatic patients to establish xenograft tumor lines for future testing of potential therapies and for understanding mechanisms of therapy resistance via DNA/RNA sequencing, to collect patient blood samples for future DNA/RNA sequencing , and to collect patient urine samples for future prostate cancer related biomarker detection and DNA/RNA sequencing.

7. Long-Term Follow-Up of Patients Who Have Participated in Children's Oncology Group Studies

   Rochester, Minn.

   This clinical trial is studying long-term follow-up in patients who are or have participated in Children's Oncology Group studies. Developing a way to track patients enrolled in Children's Oncology Group studies will help doctors gather long-term follow-up information and may help the study of cancer in the future.

8. A Study of Standard Systemic Therapy with or without Definitive Treatment in Treating Participants with Metastatic Prostate Cancer

   La Crosse, Wis., Rochester, Minn., Scottsdale/Phoenix, Ariz.

   The purpose of this study is to evaouate how well standard systemic therapy with or without definitive treatment (prostate removal surgery or radiation therapy) works in treating participants with prostate cancer that has spread to other places in the body.

9. Innovative CAR-TIL immunotherapy against melanoma

   Jacksonville, Fla.

   The chimeric antigen receptor (CAR) T-cell therapy is a revolutionary cellular immunotherapy strategy that has transformed the treatment of B cell malignancies by engineering T cells to recognize B cell specific tumor markers; however, attempts to treat solid tumors with CAR T-cells have identified unique challenges that have rendered CAR T cells less effective against these tumors. Conventional CARs are designed to target tumor-associated antigens, but antigenic heterogeneity and the variable nature of surface antigen expression provide escape mechanisms for solid tumors from CAR T-cell attack. [1, 2] The solid tumor stroma acts as an immunosuppressive cloud that impedes the homing of peripheral CAR T-cells into the tumor microenvironment (TME). The hostile TME can also drive CAR T-cells to functional exhaustion and metabolic dysfunction, thus blunting the therapeutic efficacy of CAR T-cells.[3] Oncolytic viruses or radiation that generate local inflammation in the TME have been shown to promote T cell homing and infiltration [4] but do not address the exhaustion of tumor infiltrating lymphocytes (TILs). The PD-1/PD-L1 cascade allows tumors to evade the immune system by suppressing T cell function within the TME. [5, 6] An ideal adoptive cellular therapy must possess the ability to not only return to the site of the tumor but must also retain cytotoxic potential after a recognition event. We present here a CAR design that allows PD-1 to recognize PD-L1 on the tumor; however, the intracellular CAR design is one that results in T cell activation as opposed to inhibition. We hypothesize that targeting melanoma with a PD-1 (MC9324) CAR TIL therapy would capitalize on the tumor homing machinery of the TIL to drive the CAR TIL to the tumor where engagement of the PD-1 domain of the CAR with PD-L1 on the tumor cell would result in T cell cytotoxic killing.

10. Analyses of Metabolic Agents Following Brain Radiation

    Rochester, Minn.

    The purpose of this study is to determine the feasibility of serial cerebrospinal fluid (CSF) assessments to evaluate the pharmacodynamic impact of agents targeting radiation-induced biology administered following completion of brain radiation.