Tests on airway tissue reveal glo vapour has minimal impact compared to smoke
Scientists at British American Tobacco observed changes in just two genes when human airway tissue was exposed to vapour from its tobacco heating product (THP) – glo. This compares to thousands of gene changes observed in tissue exposed to cigarette smoke. The impact on tissue exposed to glo vapour was minimal and more comparable with that of air when tested in laboratory conditions (Figure 1).
These results add to evidence suggesting that glo has the potential to be substantially reduced risk compared to smoking conventional cigarettes.
'Products like glo are very new and consumers and regulators alike want as much information as possible. That is why testing the impact of glo vapour compared to smoke is so important,' explains Dr James Murphy, Head of Reduced Risk Substantiation at British American Tobacco. 'Here we are observing gene expression, which can give an indication of whether exposure to an aerosol, like smoke or glo vapour, has had particular toxic effects.'
'Our results clearly show that cigarette smoke triggers a robust gene expression response,' Murphy says. 'However, exposure to vapour from glo, a tobacco heating product (THP), has very limited impact on gene expression compared to smoke–there is a striking difference!'
glo is part of an ever-increasing portfolio of potentially reduced risk products being developed by British American Tobacco as an alternative to traditional cigarettes.
In this study, scientists at British American Tobacco used human cells grown in the lab to test the impact of glo vapour compared to smoke and air.
The tissue (MucilAir™) is made up of cells that grow in the lab to create a 3-dimensional structure that mimics the natural structure and characteristics of the living human airway. The resulting tissue is, for example, capable of producing mucus, just like in the living airway, and is covered in hair-like projections called cilia, which are used to expel inhaled dust from the respiratory system.
Using a robot that mimics how consumers use their products, this tissue was exposed to air, smoke from a reference cigarette (3R4F), or vapour from glo continuously for one hour. Then, to measure the cell response, the scientists mapped the genes that were switched on and off at 24 hours and 48 hours after the one-hour exposure.
This involves breaking open the cells and the cell nucleus to get at the genetic material inside it. The material is then studied to determine what genes are impacted.
'Our technology is state-of-the-art', says Murphy. 'We have the capability to profile the activity of tens of thousands of genes simultaneously, providing more information than ever before on the genetic profile of exposed cells.'
Results show that cigarette smoke triggered thousands (2809) of changes in the expression of genes strongly involved in the development of lung cancer, inflammation and fibrosis. In contrast, only two genes were affected by exposure to glo vapour*. (Figure 1).
These results, which are published in the journal Scientific Reports (doi: 10.1038/s41598-018-19627-0) add to evidence that glo vapour may cause less damage to cells as compared to cigarette smoke. Future studies will look at the impact on human tissues of more intense and longer exposure to this vapour.
Previous research conducted by British American Tobacco has shown that glo vapour contains around 90-95% less toxicants compared to cigarette smoke from a reference cigarette, in terms of the priority list of nine toxicants that the World Health Organisation recommends reducing in cigarette smoke*.
British American Tobacco's Commitment to NGPs
British American Tobacco has invested more than US$2.5 billion over the last six years in developing and commercialising a world-leading portfolio of products in the Next Generation Products (NGPs) category. British American Tobacco currently has NGPs in 16 markets with plans to be in 40 countries by the end of 2018. BAT has a bold ambition to realise revenue of more than £5bn from NGPs by 2022.