Oncology (Medical)

Below are current clinical trials.

Filter this list of studies by location, status and more.

1. Etiology, Prevention and Therapy Navigation of Cancer

   Rochester, Minn., La Crosse, Wis., Jacksonville, Fla., Scottsdale/Phoenix, Ariz., Eau Claire, Wis.

   The purpose of this study is to evaluate the integration of cancer pan-genetic testing into a cancer clinical practice and understand both its use and effect in “real world” practice conditions.

2. Personalized Neoantigen Peptide-Based Vaccine in Combination With Pembrolizumab for the Treatment of Advanced Solid Tumors, The PNeoVCA Study

   Jacksonville, Fla.

   The purpose of this study is to determine the safety and tolerability of personalized neoantigen peptide administered in combination with pembrolizumab to patients with advanced solid tumors. Patients' tumors will be sequenced during a pre-registration component or will have had successful sequencing pre-study. A personalized neoantigen peptide vaccine containing up to 20 unique peptides will be manufactured for each qualifying patient based on the results.

3. Immune Response to Antigens

   Jacksonville, Fla.

   The purpose of this study is to sequence patient germline and tumor samples, and nominate top neoantigen candidates using an in-house developed bioinformatics pipeline, and to validate the neoantigen candidates by laboratory assays using patient peripheral blood immune cells or serum.

4. Evaluate REC-4881 in Patients With FAP (TUPELO)

   Rochester, Minn., Scottsdale/Phoenix, Ariz.

   The purpose of this trial is to  designed to characterize the safety, tolerability, PK, PD, and preliminary activity of REC-4881 administered orally (PO) at multiple doses on a once daily schedule in participants with phenotypic classical FAP with disease involvement of the duodenum or the residual colon/rectum/pouch as the primary disease site.

5. 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.

6. A Study to Evaluate the Feasibility of Intraoperative Microdialysis (tissue sampling) during Neurosurgery for Central Nervous System Malignancies

   Rochester, Minn.

   Intraoperative Microdialysis During Neurosurgery for Central Nervous System Malignancies

7. A Study to Evaluate VSV-hIFNbeta-NIS to Treat Patients with Relapsed/Refractory Multiple Myleoma, Acute Myeloid Leukemia, or T-cell Lymphoma

   Rochester, Minn., Scottsdale/Phoenix, Ariz.

   This phase I trial studies the best dose and side effects of recombinant vesicular stomatitis virus carrying the human NIS and IFN beta genes (VSV-hIFNbeta-sodium iodide symporter [NIS]) in treating patients with multiple myeloma, acute myeloid leukemia, or T-cell lymphoma that has come back or does not respond to treatment. A virus, called VSV-hIFNbeta-NIS, which has been changed in a certain way, may be able to kill cancer cells without damaging normal cells.

8. Cell, Serum, and Buccal Bank for Patients with Chronic Myeloid Disorders and Acute Leukemia

   Rochester, Minn.

   This study is being done to store blood, buccal (cheek) cells, genetic material including DNA (deoxyribonucleic acid) and RNA (ribonucleic acid), and bone marrow so that they can be used for laboratory studies that may contribute to finding the causes of disease and factors that may determine disease progression and treatment response.

9. Breath Condensate of Lung Cancer Patients and Healthy Controls to Measure RNA Species in Exhaled Breath Condensate

   Rochester, Minn.

   The purpose of this study is to develop tests for early detection of lung cancer or lung fibrosis based on multiomics analyses of patients’ breath condensates.  

10. 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.