Henry Ford Health Researchers Work to Cause Brain Cancer Cells to Self-destruct

Researchers in the Hermelin Brain Tumor Center at Henry Ford Health in Detroit are leading a Phase 1 clinical trial studying the maximum tolerated dose of an oncolytic adenovirus, a mutated virus engineered to selectively replicate in and destroy cancer tissue.

The work is being done in combination with fractionated stereotactic radiosurgery among patients who are undergoing resection of a recurrent high-grade astrocytoma brain tumor.

“The participants in this study have progressive high-grade astrocytoma as well as glioblastoma, and are scheduled to undergo repeat surgery,” says Dr. Tobias Walbert, principal investigator of the study and co-director of the Hermelin Brain Tumor Center at Henry Ford Health.

“After the removal of as much tumor tissue as possible, a modified oncolytic adenovirus is injected into the wall of the resection cavity and any residual tumor tissue. The goal of this study is to determine the maximum tolerated dose of the injected adenovirus, which is engineered to selectively replicate in and destroy cancer tissue.”

This treatment is combined with a combination of oral 5-fluorocytosine and valganciclovir prodrug therapy, which are designed to only become toxic once they are inside tumor cells. The process is known as “suicide-gene therapy,” as these prodrugs cause the tumor cells to self-destruct.

Following the surgery to remove as much tumor tissue as possible, patients will be treated with fractionated radiosurgery, which is a process in which the total dose of stereotactic radiation is divided into several  doses administered to the patient’s remaining brain tumor tissue on separate days of treatment.

“This study will help advance medical research data on oncolytic adenovirus mediated double suicide-gene therapy in patients with high-grade astrocytoma,” says Dr. Farzan Siddiqui, co-investigator of the study and radiation oncologist at Henry Ford Health. “Gathering data on the maximum tolerated dose in combination with fractioned stereotactic radiosurgery will be essential to understanding the full potential therapeutic benefit to patients.”

When a cancer cell self-destructs, the activated prodrug inside it may be passed on to neighboring tumor cells. This is known as a “bystander effect,” and it may allow a single infected cancer cell to not only destroy itself, but also several other cancer cells around it.

Additionally, when cancer cells self-destruct in this manner, they may attract immune cells that work to clear the body of dead and dying cells. If many cancer cells self-destruct at once, it may potentially provoke an immune system response against any remaining tumor cells.

Since 1993, Henry Ford’s Hermelin Brain Tumor Center has been recognized by the National Cancer Institute as a national leader for delivering leading brain tumor therapies. Henry Ford was among a select group of the nation’s centers, and the only one in Michigan, chosen to participate in the NCI-funded Adult Brain Tumor Consortium and Brain Tumor Trials Collaborative.

As a major contributor to The Cancer Genome Atlas, a landmark cancer genomics program that molecularly characterized over 20,000 primary cancers, the Hermelin Brain Tumor Center at Henry Ford has the third largest tumor bank in the world with more than 3,000 brain tumor tissue samples and corresponding data for treatments and outcomes.

To learn more about the study, visit here.

Henry Ford Health engages in more than 2,000 research projects annually, and trains more than 4,000 medical students, residents, and fellows every year across 50-plus accredited programs.

Overall, the health care system has 33,000 employees, including nearly 6,000 physicians and researchers from the Henry Ford Medical Group, Henry Ford Physician Network, and Jackson Health Network, and 250-plus locations throughout Michigan. The facilities include five acute care hospitals, two destination facilities for complex cancer and orthopedics and sports medicine care, three behavioral health facilities, primary care, and urgent care centers.