Mutagenicity emission factors of canola oil and waste vegetable oil biodiesel: Comparison to soy biodiesel

•Biodiesels are sometimes made of either canola, soy, or waste vegetable oil (WVO).•Comparative mutagenicity of their emissions under the same conditions is needed.•We determined mutagenicity emission factors, revertants/megajoulethermal (rev/MJth).•The rev/MJth in Salmonella TA98 + S9 ranked: petro...

Full description

Saved in:
Bibliographic Details
Published in:Mutation research. Genetic toxicology and environmental mutagenesis 2019-10, Vol.846, p.403057, Article 403057
Main Authors: DeMarini, David M., Mutlu, Esra, Warren, Sarah H., King, Charly, Gilmour, M. Ian, Linak, William P.
Format: Article
Language:English
Subjects:
Activation, Metabolic
Air Pollutants - toxicity
Animals
Biodiesel
Biofuels - toxicity
Canola oil
Diesel exhaust
Industrial Waste
Microsomes, Liver - enzymology
Mutagenicity
Mutagenicity Tests
Particle Size
Particulate Matter - toxicity
Plant Oils - toxicity
Rapeseed Oil - toxicity
Rats
Salmonella - drug effects
Salmonella - genetics
Soybean Oil - toxicity
Vehicle Emissions - toxicity
Waste cooking oil
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Biodiesels are sometimes made of either canola, soy, or waste vegetable oil (WVO).•Comparative mutagenicity of their emissions under the same conditions is needed.•We determined mutagenicity emission factors, revertants/megajoulethermal (rev/MJth).•The rev/MJth in Salmonella TA98 + S9 ranked: petroleum > canola > WVO > soy.•The rev/MJth of biodiesels were generally 50–80% lower than that of petroleum diesel. Canola (or rapeseed) oil and waste vegetable oil (WVO) are used commonly to make biodiesel fuels composed completely from these oils (B100) or as blends with petroleum diesel (B0). However, no studies have reported the mutagenic potencies of the particulate matter with diameter ≤2.5 μm (PM2.5) or the mutagenicity emission factors, such as revertants/MJthermal (rev/MJth) for these biodiesel emissions. Using strains TA98 and TA100 with the Salmonella (Ames) mutagenicity assay, we determined these metrics for organic extracts of PM2.5 of emissions from biodiesel containing 5% soy oil (soy B5); 5, 20, 50, and 100% canola (canola B5, B20, B50, B100), and 100% waste vegetable oil (WVO B100). The mutagenic potencies (rev/mg PM2.5) of the canola B100 and WVO B100 emissions were generally greater than those of B0, whereas the mutagenicity emission factors (rev/MJth, rev/kg fuel, and rev/m3) were less, reflecting the lower PM emissions of the biodiesels relative to B0. Nearly all the rev/mg PM2.5 and rev/MJth values were greater in TA98 with S9 than without S9, indicating a relatively greater role for polycyclic aromatic hydrocarbons, which require S9, than nitroarenes, which do not. In TA100 -S9, the rev/mg PM2.5 and rev/MJth for the biodiesels were generally ≥ to those of B0, indicating that most of these biodiesels produced more direct-acting, base-substitution mutagenic activity than did B0. For B100 biodiesels and petroleum diesel, the rev/MJth in TA98 + S9 ranked: petroleum diesel > canola > WVO > soy. The diesel emissions generally had rev/MJth values orders of magnitude higher than those of large utility-scale combustors (natural gas, coal, oil, or wood) but orders of magnitude lower than those of inefficient open burning (e.g., residential wood fireplaces). These comparative data of the potential health effects of a variety of biodiesel fuels will help inform the life-cycle assessment and use of biodiesel fuels.
ISSN:1383-5718
1879-3592
1879-3592
DOI:10.1016/j.mrgentox.2019.05.013