Clinical Trials Search at Vanderbilt-Ingram Cancer Center

This is a Phase 1/2, open-label, non-randomized, 4-part Phase 1 trial to determine the safety
profile and identify the maximum tolerated dose (MTD) and/or recommended Phase 2 dose (RP2D)
of INBRX 106 administered as a single agent or in combination with the anti-PD-1 checkpoint
inhibitor (CPI) pembrolizumab (Keytruda).

This phase II trial studies the effect of the combination of ramucirumab and trifluridine/tipiracil or paclitaxel in treating patients with previously treated gastric or gastroesophageal junction cancer that has spread to other places in the body (advanced). Ramucirumab may damage tumor cells by targeting new blood vessel formation. Trifluridine/tipiracil is a chemotherapy pill and that may damage tumor cells by damaging their deoxyribonucleic acid (DNA). Paclitaxel may block cell growth by stopping cell division which may kill tumor cells. Giving ramucirumab and trifluridine/tipiracil will not be worse than ramucirumab and paclitaxel in treating gastric or gastroesophageal junction cancer.

This phase II trial studies how well acalabrutinib works in treating patients with chronic graft versus host disease. Acalabrutinib may be an effective treatment for graft-versus-host disease caused by a stem cell transplant.

This phase I/II trial studies the side effects and best dose of vorinostat in preventing graft versus host disease in children, adolescents, and young adults who are undergoing unrelated donor blood and bone marrow transplant. Sometimes the transplanted cells from a donor can make an immune response against the body's normal cells, called graft-versus-host disease. During this process, chemicals (called cytokines) are released that may damage certain body tissues, including the gut, liver and skin. Vorinostat may be an effective treatment for graft-versus-host disease caused by a bone marrow transplant.

This phase II trial investigates the effect of avelumab or hydroxychloroquine sulfate with or without palbociclib in treating patients with stage II-III breast cancer that is positive for disseminated tumor cells (DTCs) after curative therapy. DTCs are breast cancer cells that are asleep (dormant) in the bone marrow. There are multiple ways in which these cells stay alive, and three of these mechanisms are inhibited by the drugs in this trial. First, dormant cancer cells need a protein signal pathway involving CDK 4/6 to start dividing once they wake up in order to survive as an active cancer cell. Palbociclib works by blocking the CDK 4/6 protein and by doing so may limit the dormant cancer cell from being able to survive. In addition, palbociclib may also help both of the other drugs in the trial to work better. Second, dormant cancer cells also use a process called autophagy to generate their own nutrition, which can allow them to stay asleep. Hydroxychloroquine has been shown to block autophagy, which leads to starvation of the cells. Third, dormant cancer cells are able to hide from the bodys immune system. The immune system sends a type of cell called T cells throughout the body to detect and fight infections and diseasesincluding cancers. One way the immune system controls the activity of T cells is through the PD-1/PD-L1 (programmed cell death protein-1) pathway. However, some cancer cells hide from T-cell attack by taking control of the PD-1/PD-L1 interaction and this stops T cells from attacking cancer cells. Avelumab is an antibody designed to block the PD-1/PD-L1 pathway and helps the immune system in detecting and fighting dormant cancer cells. Because palbociclib, hydroxychloroquine, and avelumab work on the mechanisms that keep the dormant cells alive, taking one or a combination of these drugs may be able to eliminate DTCs.

This phase II trial tests whether designing radiation to avoid bone marrow in the spine (vertebral bone marrow) leads to less reduction of white blood cell counts (lymphopenia) in patients with lung cancer. This sparing technique could lead to better disease control and outcome.

Genes contain genetic code which tell the body which proteins to make. Many types of cancer
are caused by changes, or mutations, in a gene called KRAS. Researchers are looking for ways
to stop the actions of abnormal proteins made from the mutated KRAS gene. The so-called G12D
mutation in the KRAS gene is common in people with some solid tumors.

ASP3082 is a potential new treatment for certain solid tumors in people who have the G12D
mutation in their KRAS gene. Before ASP3082 is available as a treatment, the researchers need
to understand how it is processed by and acts upon the body. This information will help find
a suitable dose and to check for potential medical problems from the treatment.

People in this study will be adults with locally advanced, unresectable or metastatic solid
tumors with the G12D mutation in their KRAS gene (G12D mutation). Locally advanced means the
cancer has spread to nearby tissue. Unresectable means the cancer cannot be removed by
surgery. Metastatic means the cancer has spread to other parts of the body. They will have
been previously treated with standard therapies or refused to receive those treatments. In
the European Union (EU) and South Korea, people who have refused to receive treatment with
standard therapies cannot take part.

The main aims of the study are: to check the safety of ASP3082 by itself and together with
cetuximab (a common cancer medicine), how well it is tolerated, and to find a suitable dose
of ASP3082 by itself and together with cetuximab.

This is an open-label study. This means that people in this study and clinic staff will know
that they will receive ASP3082.

This study will be in 2 parts. In Part 1, different small groups of people will receive lower
to higher doses of ASP3082, by itself, or together with cetuximab. Only people with
colorectal cancer will receive ASP3082 together with cetuximab. Any medical problems will be
recorded at each dose. This is done to find suitable doses of ASP3082 by itself or together
with cetuximab to use in Part 2 of the study. The first group will receive the lowest dose of
ASP3082. A medical expert panel will check the results from this group and decide if the next
group can receive a higher dose of ASP3082. The panel will do this for each group until all
groups have received ASP3082 (by itself or together with cetuximab) or until suitable doses
have been selected for Part 2.

In Part 2, other different small groups of people will receive ASP3082 by itself or together
with cetuximab, with the most suitable doses worked out from Part 1. This will help find a
more accurate dose of ASP3082 to use in future studies.

ASP3082, and cetuximab (if used), will be given through a vein. This is called an infusion.
Each treatment cycle is 21 days long. They will continue treatment until: they have medical
problems from the treatment they can't tolerate; their cancer gets worse; they start other
cancer treatment; they ask to stop treatment; they do not come back for treatment.

People will visit the clinic on certain days during their treatment, with extra visits during
the first 2 cycles of treatment. During these visits, the study doctors will check for any
medical problems from ASP3082 by itself or together with cetuximab. At some visits, other
checks will include a medical examination, echocardiogram (ECHO) or multigated acquisition
(MUGA) scan, blood and urine tests and vital signs. Vital signs include temperature, pulse,
breathing rate, and blood pressure. (Blood oxygen levels will also be checked for people
treated with ASP3082 together with cetuximab.) Tumor samples will be taken during certain
visits during treatment and when treatment has finished.

People will visit the clinic within 7 days after stopping treatment. The study doctors will
check for any medical problems from ASP3082 by itself or together with cetuximab. Other
checks will include a medical examination, echocardiogram (ECHO) or multigated acquisition
(MUGA) scan, urine and blood tests and vital signs. After this, people will continue to visit
the clinic every 9 weeks. This is to check the condition of their cancer. They will do this
until 45 weeks after treatment stopped, or if their cancer is worse, they start other cancer
treatment, they ask to stop treatment, or they do not come back for treatment.

Also, people may visit the clinic at 30 days and 90 days after stopping treatment. At the
30-day visit, the study doctors will check for any medical problems from ASP3082 by itself or
together with cetuximab. People will have their vital signs checked and have some bloo

This phase II trial tests whether using genetic testing of tumor tissue to select the optimal treatment regimen works in treating patients with clear cell renal cell (kidney) cancer that has spread to other places in the body (advanced or metastatic). The current Food and Drug Administration (FDA)-approved regimens for advanced kidney cancer fall into two categories. One treatment combination includes two immunotherapy drugs (nivolumab plus ipilimumab), which are delivered by separate intravenous infusions into a vein. The other combination is one immunotherapy drug (nivolumab infusion) plus an oral pill taken by mouth (cabozantinib). Nivolumab and ipilimumab are immunotherapies which release the brakes of the immune system, thus allowing the patient's own immune system to better kill cancer cells. Cabozantinib is a targeted therapy specifically designed to block certain biological mechanisms needed for growth of cancer cells. In kidney cancer, cabozantinib blocks a tumors blood supply. The genetic (DNA) makeup of the tumor may affect how well it responds to therapy. Testing the makeup (genes) of the tumor, may help match a treatment (from one of the above two treatment options) to the specific cancer and increase the chance that the disease will respond to treatment. The purpose of this study is to learn if genetic testing of tumor tissue may help doctors select the optimal treatment regimen to which advanced kidney cancer is more likely to respond.

Multiple myeloma (MM) is a plasma cell disease characterized by the growth of clonal plasma
cells in the bone marrow. The purpose of this study is to assess the safety and toxicity of
ABBV-453 in adult participants with relapsed/refractory (R/R) MM. Adverse events and change
in disease activity will be assessed.

ABBV-453 is an investigational drug being developed for the treatment of R/R MM. Part 1 will
be a monotherapy dose escalation phase to determine the best dose of ABBV-453. In Part 2,
participants are placed in 1 of 3 groups called treatment arms. Each group receives a
different treatment. Approximately 28 to 48 adult participants in Part 1 and 150 to 312 adult
participants in Part 2 with R/R MM will be enrolled in the study in approximately 70 sites
worldwide.

In Part 1 and the Japan Cohort, Participants will receive oral ABBV-453 tablets once daily
(QD) in 28-day cycles. In Part 2, Arm 1, participants will receive continuous doses of oral
ABBV-453 tablets QD in combination with oral dexamethasone tablets once weekly in 28-day
cycles. In Part 2, Arm 2, participants will receive continuous doses of oral ABBV-453 tablets
QD in combination with subcutaneous injections of daratumumab every 1 to 4 weeks and oral
dexamethasone tablets once weekly in, 28-day cycles. In Part 2, Arm 3, participants will
receive continuous doses of oral ABBV-453 tablets QD in combination with subcutaneous
injections of daratumumab every 1 to 4 weeks, oral lenalidomide capsules QD on Days 1-21, and
oral dexamethasone tablets once weekly, in 28-day cycles.

There may be higher treatment burden for participants in this trial compared to their
standard of care. Participants will attend regular visits during the study at an approved
institution (hospital or clinic). The effect of the treatment will be frequently checked by
medical assessments, blood tests, and side effects.

This phase II trial studies the effects of niraparib in combination with dostarlimab prior to surgery in treating BRCA-mutated or PALB2-mutated stage I-III breast cancer. Niraparib is a PARP inhibitor, which means that it blocks an enzyme (proteins that help chemical reactions in the body occur) in cells called PARP. PARP helps repair deoxyribonucleic acid (DNA) when it becomes damaged. Blocking PARP may help keep cancer cells from repairing their damaged DNA, causing them to die. PARP inhibitors are a type of targeted therapy. Dostarlimab stimulates the immune system by blocking the PD-1 pathway. The PD-1 pathway controls the bodys natural immune response, but for some types of cancer, the immune system does not work as it should and is prevented from attacking tumors. Dostarlimab works by blocking the PD-1 pathway, which may help your immune system identify and catch tumor cells. Giving niraparib in combination with dostarlimab may work better against the tumor and maximize tumor shrinkage before surgery.