When human cells are exposed to titanium dioxide without the presence of UV light from the sun, the risk for bacterial infection more than doubles. This finding by a Stony Brook University-led research team, published early online in the Journal of Nanobiotechnology, raises concerns about exposure to titanium dioxide, a nanoparticle commonly used in millions of products worldwide ranging from cosmetics to toothpaste, gum, food coloring and medicines.
Tatsiana Mironava, center, points to excessive bacterial growth around titanium dioxide-exposed cells. The research team found when HeLa cells are exposed to titanium dioxide without UV exposure, the risk of bacterial infection grows exponentially. Other researchers include, from left, Miriam Rafailovich, Stephen Walker, and Yan Xu. Courtesy of John Griffin, Stony Brook University
When human cells are exposed to titanium dioxide without the presence of UV light from the sun, the risk for bacterial infection more than doubles. This finding by a Stony Brook University-led research team, published early online in the Journal of Nanobiotechnology, raises concerns about exposure to titanium dioxide, a nanoparticle commonly used in millions of products worldwide ranging from cosmetics to toothpaste, gum, food coloring and medicines.
Because some 4 million tons of titanium dioxide particles are produced worldwide, human exposure to them is almost certain during a lifetime. In combination with UV light, the nanoparticles exhibit prophylactic activity against bacteria and therefore are studied for anti-bacterial applications. Yet, in the paper titled “Exposure to TiO2 nanopartices increases Staphylococcus aureus infection of HeLa cells,” the researchers showed that in the absence of these powerful rays, bacteria thrive.
“We discovered an almost ‘perfect storm’ generated by titanium dioxide nanoparticles against the immune system when they are not impacted by UV light,” said Miriam Rafailovich, PhD, of the Department of Materials Science and Engineering (MSE) within the College of Engineering & Applied Sciences at Stony Brook University and a co-author on the paper. “This should raise a red flag regarding exposure risks related to products that include titanium dioxide in the absence of UV light.”
The researchers, headed by Dr. Tatsiana Mironava of the Department of Materials Science and Engineering, exposed some HeLa cells, a human cell line used in research, to titanium dioxide. Together with Yan Xu of MSE and Dr. Stephen Walker, a microbiologist in the Stony Brook School of Dental Medicine, they then exposed the cells to Staphylococcus aureus, a pathogen that causes a diverse range of human infections worldwide. They found that the titanium dioxide-exposed cells had 250 percent to 350 percent more bacteria per cell than HeLa cells not exposed to the nanoparticles. Additionally, bacterial-killing macrophages exposed to titanium dioxide ingested 40 percent fewer bacteria compared to other cells, further increasing the risk of infection.
The authors concluded that these factors, in combination, ”raise serious concerns regarding the impact of exposure to titanium dioxide nanoparticles on the ability of organisms to resist bacterial infection.”
Co-investigators for the research include: Stony Brook University faculty from MSE, and the Departments of Physiology & Biophysics, and Oral Biology & Pathology; faculty from Lehigh University, University of California, Los Angeles, undergraduate interns from Stern College for Women; and high school students from the Garcia Research Program at Stony Brook University.
The research was supported in part by the National Science Foundation.
Source: Stony Brook University
Our Understanding of Immune Issues Is Evolving: Here Are 5 Reasons Why
October 25th 2024The past 5 years in medicine have seen significant advances in RNA vaccines, understanding immune dysregulation, and improved interspecialty communication, promising better disease eradication and tailored treatments.