Scientists at Albert Einstein College of Medicine have developed a technique that may help prevent radiation damage to bone marrow by delivering melanin using particularly small nanoparticles. Melanin has been shown to protect the skin against radiation, and the same has now been demonstrated within the bones of mice. It is hoped that this technology might prevent the development of aplastic anemia in patients undergoing radiation therapy or in victims of radiation exposure.
Ekaterina Dadachova, Ph.D., senior author of the study, explaining the research:
Details of the technology from an Einstein press release:
Dr. Dadachova and her colleagues focused on packaging melanin in particles so small that they would not get trapped by the lungs, liver or spleen. They created “melanin nanoparticles” by coating tiny (20 nanometers in diameter) silica (sand) particles with several layers of melanin pigment that they synthesized in their laboratory.
The researchers found that these particles successfully lodged in bone marrow after being injected into mice. Then, in a series of experiments, they investigated whether their nanoparticles would protect the bone marrow of mice treated with two types of radiation.
In the first experiment, one group of mice was injected with nanoparticles and a second group was not. Three hours later, both groups were exposed to whole-body radiation. For the next 30 days, the researchers monitored the blood of the mice, looking for signs of bone marrow damage such as decreased numbers of white blood cells and platelets.
Compared with the control group, those receiving melanin nanoparticles before radiation exposure fared much better; their levels of white cells and platelets dropped much less precipitously. Ten days after irradiation, for example, platelet levels had fallen by only 10 percent in mice that had received nanoparticles compared with a 60 percent decline in untreated mice. Furthermore, levels of white blood cells and platelets returned to normal much more quickly than in the control mice.
A second experiment assessed not only bone-marrow protection but whether the nanoparticles might have the undesirable effect of infiltrating and protecting tumors being targeted with radiation. Two groups of mice were injected with melanoma cells that formed melanoma tumors. After one group of mice was injected with melanin nanoparticles, both groups received an experimental radiation treatment designed by Dr. Dadachova and her colleagues specifically for treating melanoma.
This treatment uses a radiation-emitting isotope “piggybacked” onto an antibody that binds to melanin. When injected into the bloodstream, the antibodies latch onto the free melanin particles released by cells within melanoma tumors. Their isotopes then emit radiation that kills nearby melanoma tumor cells.
Following the second experiment, the melanoma tumors shrank significantly and to the same extent in both groups of mice – indicating that the melanized nanoparticles did not interfere with the radiation therapy’s effectiveness. And once again, the melanized nanoparticles prevented radiation-induced bone-marrow damage: between the third and seventh day after the antibody-isotope radiation therapy was administered, mice injected with nanoparticles experienced a drop in white cells that was significantly less than occurred in mice not pre-treated with nanoparticles.
Press release: Novel Nanoparticles Prevent Radiation Damage…
Abstract in International Journal of Radiation Oncology, Biology and Physics: Melanin-Covered Nanoparticles for Protection of Bone Marrow During Radiation Therapy of Cancer