Cancer cell during cell division. Credit: National Institutes of Health

An interdisciplinary team of scientists from KU Leuven, the University of Bremen, the Leibniz Institute of Materials Engineering, and the University of Ioannina has succeeded in killing tumour cells in mice using nano-sized copper compounds together with immunotherapy. After the therapy, the cancer did not return.

Recent advances in cancer therapy use one's own immunity to fight the cancer. However, in some cases, immunotherapy has proven unsuccessful. The team of biomedical researchers, physicists, and chemical engineers found that tumours are sensitive to copper oxide nanoparticles—a compound composed of copper and oxygen. Once inside a living organism, these nanoparticles dissolve and become toxic. By creating the nanoparticles using iron oxide, the researchers were able to control this process to eliminate cancer cells, while healthy cells were not affected.

"Any material that you create at a nanoscale has slightly different characteristics than its normal-sized counterpart," explain Professor Stefaan Soenen and Dr. Bella B. Manshian from the Department of Imaging and Pathology, who worked together on the study. "If we would ingest metal oxides in large quantities, they can be dangerous, but at a nanoscale and at controlled, safe, concentrations, they can actually be beneficial."

As the researchers expected, the cancer returned after treating with only the nanoparticles. Therefore, they combined the nanoparticles with immunotherapy. "We noticed that the copper compounds not only could kill the tumour cells directly, they also could assist those cells in the immune system that fight foreign substances, like tumours," says Dr. Manshian.

The combination of the nanoparticles and immunotherapy made the tumours disappear entirely and, as a result, works as a vaccine for lung and colon cancer—the two types that were investigated in the study. To confirm their finding, the researchers injected tumour cells back into the mice. These cells were immediately eliminated by the immune system, which was on the lookout for any new, similar, cells invading the body.

The authors state that the novel technique can be used for about sixty percent of all cancers, given that the cancer cells stem from a mutation in the p53 gene. Examples include lung, breast, ovarian, and colon cancer.

A crucial element is that the tumours disappeared without the use of chemotherapy, which typically comes with major side-effects. Chemotherapeutic drugs not only attack cancer cells, they often damage healthy cells along the way. For example, some of these drugs wipe out white blood cells, abolishing the immune system.

"As far as I'm aware, this is the first time that metal oxides are used to efficiently fight cancer cells with long-lasting immune effects in live models," Professor Soenen says. "As a next step, we want to create other metal nanoparticles, and identify which particles affect which types of cancer. This should result in a comprehensive database."

The team also plans to test tumour cells derived from cancer patient tissue. If the results remain the same, Professor Soenen plans to set up a clinical trial. For that to happen, however, there are still some hurdles along the way. He explains: "Nanomedicine is on the rise in the U.S. and Asia, but Europe is lagging behind. It's a challenge to advance in this field, because doctors and engineers often speak a different language. We need more interdisciplinary collaboration, so that we can understand each other better and build upon each other's knowledge."

Explore further Immune cell discovery opens door to new powerful cancer therapies

More information: Hendrik Naatz et al, Model-Based Nanoengineered Pharmacokinetics of Iron-Doped Copper Oxide for Nanomedical Applications, Angewandte Chemie International Edition (2019). Journal information: Angewandte Chemie International Edition Hendrik Naatz et al, Model-Based Nanoengineered Pharmacokinetics of Iron-Doped Copper Oxide for Nanomedical Applications,(2019). DOI: 10.1002/anie.201912312