Toxicity of exhaust emissions from high aromatic and non-aromatic diesel fuels using in vitro ALI exposure system

• Published in: The Science of the total environment Vol. 890; p. 164215
• Main Authors: Hakkarainen, Henri, Järvinen, Anssi, Lepistö, Teemu, Salo, Laura, Kuittinen, Niina, Laakkonen, Elmeri, Yang, Mo, Martikainen, Maria-Viola, Saarikoski, Sanna, Aurela, Minna, Barreira, Luis, Teinilä, Kimmo, Ihalainen, Mika, Aakko-Saksa, Päivi, Timonen, Hilkka, Rönkkö, Topi, Jalava, Pasi
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 10.09.2023
• Subjects: Air Pollutants - analysis; Air Pollutants - toxicity; Air-liquid interface; Aromatic; Engine exhaust; Gases; Gasoline - toxicity; Particulate Matter - analysis; Particulate Matter - toxicity; Toxicity; Vehicle Emissions - analysis; Vehicle Emissions - toxicity; DDA; ELPI; BC; THP-1; Toxicity; A549; DR; HEPA; DMEM; OA; FBS; UFP; LDSA; PMA; SP-AMS; Air-liquid interface; HEPES; PAH; Aromatic; CPC; SMPS; PM; Engine exhaust; ALI; ELISA
• ISSN: 0048-9697; 1879-1026
• DOI: 10.1016/j.scitotenv.2023.164215

The differences in the traffic fuels have been shown to affect exhaust emissions and their toxicity. Especially, the aromatic content of diesel fuel is an important factor considering the emissions, notably particulate matter (PM) concentrations. The ultra-fine particles (UFP, particles with a diameter of <100 nm) are important components of engine emissions and connected to various health effects, such as pulmonary and systematic inflammation, and cardiovascular disorders. Studying the toxicity of the UFPs and how different fuel options can be used for mitigating the emissions and toxicity is crucial. In the present study, emissions from a heavy-duty diesel engine were used to assess the exhaust emission toxicity with a thermophoresis-based in vitro air-liquid interface (ALI) exposure system. The aim of the study was to evaluate the toxicity of engine exhaust and the potential effect of 20 % aromatic fossil diesel and 0 % aromatic renewable diesel fuel on emission toxicity. The results of the present study show that the aromatic content of the fuel increases emission toxicity, which was seen as an increase in genotoxicity, distinct inflammatory responses, and alterations in the cell cycle. The increase in genotoxicity was most likely due to the PM phase of the exhaust, as the exposures with high-efficiency particulate absorbing (HEPA)-filtered exhaust resulted in a negligible increase in genotoxicity. However, the solely gaseous exposures still elicited immunological responses. Overall, the present study shows that decreasing the aromatic content of the fuels could be a significant measure in mitigating traffic exhaust toxicity. [Display omitted] •The toxicity of the exhaust from two diesel fuels with distinct aromatic contents were studied in vitro with ALI system.•Results show that the higher aromatic content of diesel fuel increases exhaust emissions and their emissions.•Genotoxicity was connected to the exhaust PM, whereas immunological responses were also evident with the gaseous phase.