Syndicate content

Cancer Treatment on a Cellular Level

The most common treatments for cancer are radiation and chemotherapy. However these treatments have side effects and also damage healthy tissues. Moreover, their effectiveness is limited when the cancer has spread throughout the body. Researchers at the Niels Bohr Institute in Copenhagen are therefore working to develop a gentler treatment that “tricks” the cancer cells, which would absorb a cytotoxin and therefore be destroyed, while healthy cells would remain unaffected. The results were published on March 2, 2016 in the scientific journal, Scientific Reports. The open-access article is titled “Restricted Mobility of Specific Functional Groups Reduces Anti-Cancer Drug Activity in Healthy Cells.” Physicist Murillo Martins, Ph.D., at the Niels Bohr Institute at the University of Copenhagen had an idea. He wanted to construct a kind of nanoscale “lorry” that could transport the cytotoxin directly to the cancer cells via the bloodstream and would prompt the cells to let the “load” in so that the cancer cells were destroyed. It is something you could imagine in a science fiction film, but could it be `done in the real world? The first task was the “vehicle” itself. For that he decided to use tiny magnetic beads, an approach well known in medical research. You can inject the beads into the bloodstream and by placing a magnet at the site where the tumor is located you can get the beads to move there. The next step was the cytotoxic load.

"We designed a ring-shaped sac of a biologically useful base material and using chemical processes we encapsulated the cytotoxin surrounding the beads. The coupling does not always happen, but using a separation process we can sort the beads from where the coupling with the sac did not succeed," explains Dr. Martins, a postdoc in X-Ray and Neutron Science at the Niels Bohr Institute, University of Copenhagen.

At the neutron scattering facility LANSCE in the US and the synchrotron facility at the Paul Scherrer Institute, PSI in Switzerland, they could “look inside” the package with the cytotoxin and confirm that the cytotoxin was encapsulated in the ring-shaped package.

The next problem to be solved was to get the package into the cell. A cell has a surrounding membrane that protects the cell against foreign substances. But it also has keyholes or receptors that can open up if the cell wants to let substances enter. These substances must have a key that fits into the keyholes.

"Then I thought, why do breast cancer, lung cancer and ovarian cancer so often spread to the bones? Bones are composed of minerals like calcium phosphates. Do cancer cells need these substances to grow? Can these substances be used as doorways to the cell? I decided to investigate this," explains Dr. Martins.

So he made a coating of calcium phosphate on the package with the cytotoxin. Now they had to test whether the idea worked. Would the package with the cytotoxin be absorbed into the cells? And which effect would they have?

They carried out experiments with breast cancer, lung cancer, and colon cancer, cells along with healthy cells (monocytes and fibroblasts) at the Laboratory of Tumor Immunology at the School of Bioscience in Botucatu, Brazil.

The studies showed that the cancer cells actually absorbed the packages with the cytotoxin. But what kind of effect would they have? Cancer cells and healthy cells have very different metabolisms and the two types of cells responded differently to the encapsulated anti-cancer agents.

"We could see that the nanoparticles with the cytotoxin were absorbed by the cancer cells. This caused the metabolism of the cancer cells to change and the cells showed signs that they were about to die. The healthy cells, meanwhile, do not show any evidences of absorbing the packages with the cytotoxin.

This suggests that the method can be used to send cytotoxin around the body with reduced toxicity and could therefore be potentially safer for healthy cells," explains Heloisa Bordallo, Associate Professor in X-Ray and Neutron Science at the Niels Bohr Institute.

[Press release] [Scientific Reports article]