Ionic liquids (ILs) as “green solvents” provided an effective and efficient procedure for Knoevenagel condensation reactions. It is applicable for a large range of aldehydes, ketones with active methylene compounds. ILs can significantly promote the reaction rates. High yields and selectivity of products have been observed. ILs can be recycled and reused. In this paper, the recent achievements of Knoevenagel condensation reactions promoted by ILs are reviewed.
There is increasing interest in the application of ionic liquids for the pretreatment and fractionation of lignocelluloses. In this study, a series of functional acidic ionic liquids (ILs) with various heterocyclic organic cations were synthesized. Corn stalks were successfully fractionated into lignin, hemicelluloses, and cellulose when ultrasonically pretreated with ILs at 70 °C for 3 h, and subsequently treated with alkaline extraction. High yields of IL-isolated lignin (18.3% to 19.6%) and (8.3% to 14.6%) were obtained using ILs in the absence and presence of water, respectively. The yield of cellulose ranged from 40.0 to 77.0% from IL treatments, whereas the yield of hemicelluloses ranged from 1.1% to 17.3%. Enzymatic hydrolysis of the isolated cellulose residual produced 89.2% to 94.9% reducing sugar with 77.8% to 86.1% glucose, which corresponded to 80.5% to 91.4% enzymatic conversion of cellulose. Syringol and vanillin were found as the main lignin degradation products.
Like bacteria, fungi play an important role in the composting process as major decomposers of organic substances. As only a small fraction of the fungi present in composting can be cultured because conventional microbiological techniques limited information on the composition of fungal communities in composting. Molecular methods are expected to give a more realistic view of species richness and distribution. For this purpose, we selected universal PCR primer set that allow the specific amplification of fungal 18S-ribosomal-DNA (rDNA) sequences. DNA was extracted from composting samples, and 18S rDNA genes were amplified by EF4/Fung5 (0.6kb) and EF4/NS2-GC (0.4kb). DGGE analysis of the fungal community in the composting of a microcosm experiment was carried out after amplification of total DNA with both primer pairs. Clear banding patterns were obtained with amplified production. 13 different bands excised from the DGGE gel were sequenced and compared with genbank. Sequencing showed that some could not be cultured; some were efficient cellulose-degrading strains. The results showed that diversity and composition of the fungal community in the composting can be analyzed by the combination of 18S rDNA PCR amplification and DGGE.
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