1,2-Dichlorobenzene (1,2-DCB) is in various industries as solvents in herbicides, pesticides, and wax, and as degreasers or in the production of dyes. Studies on the hazards and risks of 1,2-DCB showed that this substance can cause skin corrosion, skin irritability, respiratory irritability, and certain target organ toxicity. Industrial workers are exposed to 1,2-DCB by inhalation or skin exposure and there is a lack of information on human hazards even though they can be exposed to organic compounds such as benzene or other DCB complexes rather than a single substance. In this study, we investigated the specific organ toxicity of 1,2- DCB and sex differences using whole-body inhalation in laboratory mice. Male and female mice were exposed to 0–120 ppm of the test substance for 13 weeks. After euthanization, the organs were collected, histopathological assessments and immunohistochemistry (IHC) were performed, and lipid peroxidation was analyzed. Macro and microscopic lesions were observed in the livers of male mice exposed to the test substance, and microscopic alterations were observed in the nasal cavities of male and female mice. IHC analysis of the liver confirmed a greater increase in cytochrome P450 induction in males than in female mice, and malondialdehyde and 4-hydroxynonenal were increased in both sexes by 1,2-DCB inhalation. Based on the relevant literature and experimental results, 1,2-DCB is believed to cause specific organ toxicity in the livers of male mice and the nasal cavities of both sexes of mice, which is supposed to be related to sex differences in cytochrome P450 induction and changes in lipid and oxidative products associated with the early metabolites of the test substance.

Catalytic activities of V2O5/TiO2 catalyst were investigated under reaction conditions such as reaction temperature, catalyst size, inlet concentration and space velocity. A 1,2-dichlorobenzene(1,2-DCB) concentrations were measured in front and after of the heated V2O5/TiO2 catalyst bed, and conversion efficiency of 1,2-DCB was determined from it's concentration difference. The conversion of 1,2-DCB using a pellet type catalyst in the bench-scale reactor was lower than that with the powder type used in the micro flow-scale reactor. However, when the pellet size was halved, the conversion was similar to that with the powder type catalyst. The highest conversion was shown with an inlet concentration of 100 ppmv, but when the concentration was higher or lower than 100 ppmv, the conversion was found to decrease. Complete conversion was obtained when the GHSV was maintained at below 10,000 h-1, even at the relatively low temperature of 250°C. Water vapor inhibited the conversion of 1,2-DCB, which was suspected to be due to the competitive adsorption between the reactant and water for active sites.

This study examined the catalytic destruction of 1,2-dichlorobenzene on V2O5/TiO2 nanoparticles. The V2O5/TiO2 nanoparticles were synthesized by the thermal decomposition of vanadium oxytripropoxide and titanium. The effects of the synthesis conditions, such as the synthesis temperature and precursor heating temperature, were investigated. The specific surface areas of V2O5/TiO2 nanoparticles increased with increasing synthesis temperature and decreasing precursor heating temperature. In addition, the removal efficiency of 1,2-dichlorobenzene was promoted by a decrease in heating temperature. However, the removal efficiency of 1, 2-dichlorobenzene was decreased by an anatase to rutile phase transformation at temperatures 1,300℃.