Will Space Travel Break Our Hearts?
Using an animal model, researchers assessed the affect of iron ion radiation commonly found in outer space to see if exposures promoted the development of atherosclerosis, as terrestrial sources of radiation are known to do. They observed that cosmic radiation accelerated the development of atherosclerosis, independent of the cholesterol levels or circulating white blood cells of the mice. It also worsened existing atherosclerotic lesions.
“It’s well known that prolonged exposure to radiation sources here on Earth, including those used in cancer treatment, excessive occupational exposure and atomic bombs, are associated with an increased risk for atherosclerosis,” said Dennis Kucik, M.D., Ph.D., associate professor in the UAB Department of Pathology. “But cosmic radiation is very different from X-rays and other radiation found on Earth. The radiation risks of deep-space travel are difficult to predict, largely because so few people have been exposed.”
Accelerated ions in cosmic radiation interact differently with objects and people, Kucik said.
The only people who have been exposed to high levels of cosmic radiation are the 24 astronauts who have been to the Moon as part of NASA’s Apollo missions in the late 1960s and early 1970s. Kucik said because many people have early atherosclerosis -- whether they travel in space or not – they could not draw any conclusions from the small number of astronauts who have been outside the Earth’s magnetic field. And, he added, even if they could, with so few people it would be impossible to perform a relevant epidemiological study
Instead, Kucik and his colleagues examined atherosclerosis development in mice following targeted exposure to a particle beam of high-velocity iron ions — similar to those found in space — produced by scientists at Brookhaven National Laboratory in New York. They analyzed the mice at 13 and 40 weeks afterward to assess the development of atherosclerosis in the aorta and carotid arteries. They concluded there was involvement of components in the arterial wall in the biological response to radiation injury.
“At 13 weeks it was surprising and quite remarkable that we already could see permanent damage — an irreversible thickening of the artery wall where it had been exposed to radiation,” said co-author Janusz Kabarowski, Ph.D., assistant professor in the UAB Department of Microbiology. “The irradiation had no significant effect on the frequency of circulating immune and inflammatory white blood cells or plasma lipid profile.”
Kucik said the team’s findings also may inform cancer treatment. Newer proton radiation therapies can be targeted to stop and deposit all of their energy in a tumor, much like iron ions from space stop in the body. “No one knows the atherosclerotic risk of this therapy,” Kucik said. “Anything we learn through these studies on deep-space travel will be useful for cancer patients.”
Kucik and Kabarowski’s research was supported by a grant from the National Space Biomedical Research Institute through NASA. Co-authors on the paper are Tao Yu, Kiran Gupta, Xing Wu and Saman Khaled from the UAB Department of Pathology; Brian Parks, Shaohua Yu and Roshni Srivastava from the UAB Department of Microbiology; and Polly Chang from SRI International in Menlo Park, Calif.