TY - JOUR
T1 - Numerical simulation of IL-8-based relative inflammation potentials of aerosol particles from vehicle exhaust and non-exhaust emission sources in Japan
AU - Kajino, Mizuo
AU - Kayaba, Satoko
AU - Ishihara, Yasuhiro
AU - Iwamoto, Yoko
AU - Okuda, Tomoaki
AU - Okochi, Hiroshi
N1 - Publisher Copyright:
© 2024 The Authors
PY - 2024/1
Y1 - 2024/1
N2 - Spatial distributions of interleukin-8 (IL-8)-based relative inflammation potentials (IP) of PM2.5 from vehicle exhaust and non-exhaust emission sources in Japan are derived using the meteorology–chemistry model (NHM-Chem) and laboratory experiments. In this study, IP is first defined as multiplying PM2.5 from different emission sectors by supernatant IL-8 concentrations released using PM2.5 samples, normalized to that of particle-free controls. The simulated IP of primary exhaust particles IP(E) accounts for 3%–30% of the total vehicle IP (exhaust + non-exhaust, primary + secondary), IP(V), which is low in densely populated regions (3%–15%) and high (5%–30%) in less populated regions, because there are fewer exhaust PM2.5 emitters (diesel trucks) in more populated regions. The contribution of IP(V) to IP of the total environmental PM2.5, IP(A), varied substantially in space by approximately 3–5 times (the contributions are greater in larger cities as there is more traffic). In our estimates, IP(V) is approximately one and two orders of magnitude higher than IP(E) and IP(T), the IP of fresh tire wear particles (TWPs), respectively. IP(T) has a minor contribution to IP(V) and IP(A). Recently, however, aged TWPs have been reported to be toxic; thus, the aging process of TWPs needs to be considered in the future.
AB - Spatial distributions of interleukin-8 (IL-8)-based relative inflammation potentials (IP) of PM2.5 from vehicle exhaust and non-exhaust emission sources in Japan are derived using the meteorology–chemistry model (NHM-Chem) and laboratory experiments. In this study, IP is first defined as multiplying PM2.5 from different emission sectors by supernatant IL-8 concentrations released using PM2.5 samples, normalized to that of particle-free controls. The simulated IP of primary exhaust particles IP(E) accounts for 3%–30% of the total vehicle IP (exhaust + non-exhaust, primary + secondary), IP(V), which is low in densely populated regions (3%–15%) and high (5%–30%) in less populated regions, because there are fewer exhaust PM2.5 emitters (diesel trucks) in more populated regions. The contribution of IP(V) to IP of the total environmental PM2.5, IP(A), varied substantially in space by approximately 3–5 times (the contributions are greater in larger cities as there is more traffic). In our estimates, IP(V) is approximately one and two orders of magnitude higher than IP(E) and IP(T), the IP of fresh tire wear particles (TWPs), respectively. IP(T) has a minor contribution to IP(V) and IP(A). Recently, however, aged TWPs have been reported to be toxic; thus, the aging process of TWPs needs to be considered in the future.
KW - Interleukin-8
KW - NHM-Chem
KW - Numerical modeling
KW - Vehicle exhaust emission
KW - Vehicle non-exhaust emissions
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U2 - 10.1016/j.aeaoa.2024.100237
DO - 10.1016/j.aeaoa.2024.100237
M3 - Article
AN - SCOPUS:85183147600
SN - 2590-1621
VL - 21
JO - Atmospheric Environment: X
JF - Atmospheric Environment: X
M1 - 100237
ER -