Lotions disrupt potentially unhealthy cloud around your body

Researchers have found that applying personal care products like lotions and fragrances can disrupt a potentially unhealthy “cloud” around our bodies, which is created by ozone reacting with oils on skin.
The application of these products acts as a physical barrier between ozone in the air and squalene on skin, hindering the generation of hydroxyl radicals that are highly reactive compounds present in this close-to-body region.
Additionally, ethanol solvent in fragrances can act as a hydroxyl radical sink, reducing the strength of the human oxidation field and potentially affecting indoor air quality and human exposure to pollutants.
The study’s findings have substantial implications for indoor air chemistry, air quality, and human health, as many chemicals in our immediate vicinity are transformed by the human oxidation field into unknown compounds.
Interestingly, body lotion and perfume both seem to dampen down this effect, suggesting that using these products may help mitigate the formation of potentially unhealthy compounds around our bodies.

A man walks through a cloud of bright blue smoke in silhouette.

The application of personal care products such as fragrances and body lotions suppresses a potentially unhealthy “human oxidation field” that exists around our bodies, researchers report.

The research appears in Science Advances.

This zone, which was the subject of a paper by the same team published in Science in 2022, is created when oils and fats on skin react with ozone, an important oxidant in the indoor environment.

Combined with emissions from cooking, cleaning, smoking, interior paint, rugs and furnishings, and the introduction of ozone transported from outdoors, this close-to-body region—in which highly reactive compounds called hydroxyl radicals are present—has the potential to substantially affect indoor air quality and human exposure to indoor pollutants.

In the paper, the researchers report that body lotion hinders the generation of a key hydroxyl radical precursor by acting as a physical barrier between ozone in the air and squalene—a naturally occurring oil—on skin. They also found that ethanol solvent in fragrances acts as a hydroxyl radical sink, which reduces the strength of the human oxidation field.

Co-corresponding author Manabu Shiraiwa, UC Irvine professor of chemistry, led the creation of a multiphase chemical kinetic model and collaborated with researchers at Penn State to build a computational fluid dynamics model to demonstrate how concentrations of the reactive components accrue indoors.

“Our team took a unique approach to simulate concentrations of chemical compounds near humans in the indoor environment,” Shiraiwa says.

“We developed a state-of-the-art chemical model that can simulate reactions of ozone with human skin and clothing that can lead to the formation of [hydroxyl radicals] and semi-volatile organic compounds.”

The authors say that their findings have substantial implications for indoor air chemistry, the air quality of occupied spaces, and human health since many of the chemicals in our immediate vicinity are transformed by the human oxidation field.

“If we buy a sofa from major furniture company, it’s tested for harmful emissions before being put on sale. However, when we sit on the sofa, we naturally transform some of these emissions because of the oxidation field we generate,” says lead author Jonathan Williams, who heads the study of organic reactive species at the Max Planck Institute for Chemistry.

“This can create many additional compounds in our breathing zone whose properties are not well known or studied. Interestingly, body lotion and perfume both seem to dampen down this effect.”

The work was part of the Indoor Chemical Human Emissions and Reactivity project, which brought together collaborators from Denmark, Germany, and the United States. Computer modeling was provided by the Modelling Consortium for Chemistry of Indoor Environments, based at UC Irvine and led by Shiraiwa. Both efforts were funded by grants from the Alfred P. Sloan Foundation.

Source: UC Irvine

The post Lotions disrupt potentially unhealthy cloud around your body appeared first on Futurity.

link

Q. What is the “potentially unhealthy cloud” around our bodies that researchers claim lotions disrupt?

A. The “cloud” refers to a zone of highly reactive compounds called hydroxyl radicals that exist around our bodies, which can affect indoor air quality and human exposure to pollutants.

Q. How do body lotions suppress this potentially unhealthy cloud?

A. Body lotions act as a physical barrier between ozone in the air and squalene on skin, hindering the generation of key hydroxyl radical precursors.

Q. What is the role of ethanol solvent in fragrances in relation to indoor air quality?

A. Ethanol solvent in fragrances acts as a hydroxyl radical sink, reducing the strength of the human oxidation field and potentially decreasing indoor pollutant concentrations.

Q. Who led the creation of a multiphase chemical kinetic model for simulating indoor air chemistry?

A. Co-corresponding author Manabu Shiraiwa, UC Irvine professor of chemistry, led the development of this model.

Q. What is the significance of the “human oxidation field” in relation to indoor air quality and human health?

A. The human oxidation field can transform chemicals in our immediate vicinity into new compounds with unknown properties, which can affect indoor air quality and human health.

Q. How do researchers simulate concentrations of chemical compounds near humans in the indoor environment?

A. Researchers developed a state-of-the-art chemical model that can simulate reactions of ozone with human skin and clothing to form hydroxyl radicals and semi-volatile organic compounds.

Q. What is the potential impact of the “human oxidation field” on indoor air quality and human health?

A. The formation of new compounds in our breathing zone due to the human oxidation field can have substantial implications for indoor air chemistry, air quality, and human health.

Q. How do body lotions and perfume affect the transformation of emissions from furniture and other sources?

A. Body lotions and perfume both seem to dampen down the effect of these emissions by reducing the strength of the human oxidation field.

Q. What is the name of the project that brought together researchers from Denmark, Germany, and the United States to study indoor chemical human emissions and reactivity?

A. The Indoor Chemical Human Emissions and Reactivity project.

Q. Who heads the study of organic reactive species at the Max Planck Institute for Chemistry?

A. Lead author Jonathan Williams.