AI Article Synopsis
- * Results showed that the nano-sized TiO catalyst achieved complete degradation of the insecticides within 320 minutes, significantly faster than the commercial-sized catalyst.
- * Biochemical tests indicated that the TiO nanocatalyst caused no significant harm to rats, suggesting that it is a low-toxicity option for water detoxification, although further research is needed to explore breakdown products and ensure safety.
Article Abstract
The present study was performed to fabricate a titanium dioxide (TiO) nanocatalyst with proper characteristics for the removal of some insecticides (dimethoate and methomyl) from aqueous media. A TiO catalyst of regular (TiO-commercial-/HO/UV) or nano (TiO-synthesized-/HO/UV) size was employed as an advanced oxidation process by combining it with HO under light. Moreover, the total detoxification of insecticides after treatment with the most effective system (TiO(s)/HO/UV) was also investigated through exploring the biochemical alterations and histopathological changes in the liver and kidneys of the treated rats. Interestingly, the present study reported that degradation rates of the examined insecticides were faster using the TiO catalyst of nano size. Complete degradation of the tested insecticides (100%) was achieved under the TiO(s)/HO/UV system after 320 min of irradiation. The half-life values of the tested insecticides under HO/TiO(c)/UV were 43.86 and 36.28 for dimethoate and methomyl, respectively, whereas under the HO/TiO(c)/UV system, the half-life values were 27.72 and 19.52 min for dimethoate and methomyl, respectively. On the other hand, no significant changes were observed in the biochemical and histopathological parameters of rats administrated with water treated with TiO(s)/HO/UV compared to the control, indicating low toxicity of the TiO nanocatalyst-. Altogether, the advanced oxidation processes using TiO nanocatalyst can be considered as a promising and effective remediation technology for the complete detoxification of methomyl and dimethoate in water. However, further future research is needed to identify the possible breakdown products and to verify the safety of the used nanomaterials.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8431621 | PMC |
| http://dx.doi.org/10.3390/ijerph18179278 | DOI Listing |
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