Firstly,we synthesized N-methacryloyl-histidine monomer and N-methacryloyl-histidine-Cu^2+ complex(MAH-Cu^2+).Then the molecular imprinting polymers(MIP) has been prepared by surface grafting on uniform polystyrene(PS) core using reversible addition-fragmentation transfer polymerization(RAFT) with MAH-Cu^2+ as the functional monomer,methyl paraoxon as the template to simulate phosphodiesterase(PTE).Finally,we have investigated the catalytic hydrolytic activities of MIP and non-imprinting polymers(NIP) to the template methyl paraoxon and the template analogue ethyl paraoxon respectively by UV spectrophotometry.The results showed that the catalytic hydrolytic activity of MIP to the template methyl paraoxon was highest and the value of k is 8.67×10^-5 mmol L^-1 min^-1,3.89-fold higher than MIP to the template analogue ethyl paraoxon,2.79-fold higher than NIP to the template methyl paraoxon.The KM,rm of MSP are also determined,and KM = 3.95×10^-4)mol/L,rm = 2.12μmol/ min.The MIP can be reused with only lose 7%of catalytic activity for four cycles.
p-Nitrophenol imprinted nanoparticles with a size range of 150-300 nm in diameter were prepared through miniemulsion polymerization. The imprinted polymer exhibited higher adsorption capacity for p-nitrophenol than the nonimprinted polymer. The hydrolysis of paraoxon in aqueous phase can be accelerated in the presence of the p-nitrophenol imprinted nanoparticles. The hydrolysis rate of paraoxon incorporated with the imprinted nanoparticles was 2.83×10-7 mol/(L·min), which was about 3.7 times higher compared to the non-imprinted nanoparticles, 12.7 times higher to the spontaneous hydrolysis. The nanoparticles have been mixed with polyacrylonitrile solution and electrospun into nanofibers, which can also be used to accelerate the hydrolysis of paraoxon and conveniently separated from liquid phase for further processing.
Lei ZhangYong GuoWen-hao ChiHe-guang ShiHong-qi Ren郭天瑛
