The present study investigated the effects of dietary supplementation of purified amino acid (PAA) isolated and purified from animal slaughter house blood on growth performance and immune response of weanling piglets. A total of fifteen, 28 days old, weaned pigs were randomly distributed into three treatment groups, 5 pens per treatment (one head per pen). Each experimental diet was provided to five piglets per group (T0, 0% PAA; T1, 0.1% PAA; T2, 0.5% PAA). The feed consumption was calculated daily and body weight on a weekly basis. The blood samples were analyzed for plasma concentration of biochemical parameters and cytokines using ELISA Kit assay. Pigs fed with the 0.5% PAA have greater average daily weight gain (ADG) and feed efficiency (FE) as compared to those of T0 and T1. However, ADG and FE of T0 and T1 have no remarkable differences. The plasma cytokine levels were lower in T2 as compared to T0 and T1. The blood parameters like total bilirubin, blood urea nitrogen (BUN), glutamate oxalate transaminase (GOT) and glutamate pyruvate transaminase (GPT) were within the normal range in all the treatment groups. The study indicated that supplementation of 0.5% PAA have positive effect on the growth performance of the weanling pigs. Moreover, supplementation of the amino acid isolated and purified from animal slaughter house blood has no adverse effect on palatability of the feed and health of the animals.

The advanced oxidation treatment using persulfate and zero-valent iron (ZVI) has been evaluated as a very effective technology for remediation of soil and groundwater contamination. However, the high rate of the initial reaction of persulfate with ZVI causes over-consumption of an injected persulfate, and the excessively generated active species show a low transfer rate to the target pollutant. In this study, ZVI was modified using selenium with very low reactivity in the water environment with the aim of controlling the persulfate activation rate by controlling the reactivity of ZVI. Selenium-modified ZVI (Se/ZVI) was confirmed to have a selenium coating on the surface through SEM/EDS analysis, and low reductive reactivity to trichlroethylene (TCE) was observed. As a result of inducing the persulfate activation using the synthesized Se/ZVI, the persulfated consumption rate was greatly reduced, and the decomposition rate of the model contaminant, anisole, was also reduced in proportion. However, the final decomposition efficiency was rather increased, which seems to be the result of preventing persulfate over-consumption. This is because the transfer efficiency of the active species (SO4-∙) of persulfate to the target contaminant has been improved. Selenium on the surface of Se/ZVI was not significantly dissolved even under oxidation conditions by persulfate, and most of it was present in the form of Se/ZVI. It was confirmed that the persulfate activation rate could be controlled by controlling the reactivity of ZVI, which could greatly contribute to the improvement of the persulfate oxidation efficiency.