In this study, the effect of using a blended biodiesel fuel containing 10% rapeseed methyl ester (RME) on the composition and quantity of the chemicals emitted by a modern diesel engine was investigated. The diesel engine that was utilized fulfilled Japan's Post New Long Term emission standards and was equipped with an after-treatment system comprising a diesel oxidation catalyst and a catalyzed diesel particulate filter (c-DPF). Using the Japanese JE05 transient cycle as the testing cycle, the exhaust gas was sampled for three different states: when the after-treatment system was not deployed, termed ＂engine-out＂ (due to the sampling location); when the after-treatment system was deployed, termed ＂tailpipe-out＂ (likewise due the sampling location); and when the after-treatment system was deployed and the c-DPF was regenerating, termed ＂regen＂. Evidence from this study indicated that the use of 10% RME biodiesel had no significant impact on the emissions of CO, CO_2, the total hydrocarbons, and NO_x, which are regulated, regardless of the sampling state. However, the emissions of elemental carbon, organic carbon, and polycyclic aromatic hydrocarbons (PAHs), which are unregulated, showed some effects. During engine-out and tailpipe-out, emissions of the elemental carbon species EC2 were slightly lower when using the biodiesel blend than the petroleum diesel (D) fuel; however, an increase in the organic carbon species OC1 and OC2 and in some PAHs was observed during regen because of the sizable consumption of the biodiesel blend compared to D fuel. These results confirm that 10% RME biodiesel is a promising alternative to fossil fuels for diesel engines, but it is important to grasp the behavior of individual components and carefully investigate the effects of increased mixing ratios.