Bio-oil extraction of Jatropha curcas with ionic liquid co-solvent: Fate of biomass protein

Production and investigation of the physico-chemical properties of MEL-A from glycerol and coconut water

This work reports the production of MEL-A using coconut water as the carbon source. Proximate analysis of coconut water indicated the presence of nutrients necessary for growth of the organism and production of desired metabolite. The amount of MEL produced using coconut water was 3.85 g/L (± 0.35) with 74% of it being MEL-A when compared to 2.58 g/L (± 0.15) with 60% being MEL-A using glycerol, a conventional carbon source. MEL-A from coconut water consisted of 38.1% long-chain saturated fatty acids (C16:0 and C18:0) whereas with glycerol it was 9.6%. The critical micellar concentration of the biosurfactant from coconut water was 2.32 ± 0.21 µM when compared to 4.41 ± 0.25 µM from glycerol. The stability of O/W emulsion was reduced by 50% and 90% after incubation for 8 h in the case of MEL-A from coconut water and glycerol respectively when compared to synthetic surfactant, Tween-20. MEL-A from both the sources exhibited free radical scavenging activity (DPPH assay) in a dose-dependent manner wherein MEL-A from coconut water showed two fold higher activity than the other. The interaction of coconut water MEL-A with DPPC for drug encapsulation applications was also studied. The DSC measurements showed the differences in the interaction of drugs with DPPC/MEL-A liposome. The differences were also observed in the solubility of drugs after encapsulation with DPPC/MEL-A liposome.

Bacteria-activated chlorin e6 ionic liquid based on cation and anion dual-mode antibacterial action for enhanced photodynamic efficacy

With the increase in antibiotic resistance, the development of new antibacterial agents is urgent. Photosensitizers with no detectable resistance are promising antibacterial agents. However, most photosensitizers are insoluble, structurally unstable and ineffective against Gram-negative bacteria due to their negatively charged cell wall that hinder their use. In this study, a novel bacteria-activated photosensitizer ionic liquid was designed and assembled to improve the solubility, stability and antibacterial ability of photodynamic therapy. The cation 1-vinyl-3-dodecyl imidazole has been designed, which has strong binding energy with the major constituent of the cell wall. The anion selected was chlorin e6 (Ce6) since it could respond to the acidic microenvironment of bacterial infection. The Ce6 ionic liquid (Ce6-IL) composed of 1-vinyl-3-dodecyl imidazole and Ce6 not only exhibited bacteria-activated ability because its cation could firmly bond with peptidoglycan in the cell wall, but also had excellent acid responsive ability due to the protonation reaction of COO- in its anion. The binding energy of the cation with peptidoglycan was calculated via molecular dynamics simulation, and the pH-responsive behavior of Ce6-IL was verified via HR-MS. The surface potential, mechanical property, morphology and uptake rate results indicated that the cation could destroy the cell wall and promote the anion Ce6 to enter the bacteria. Due to the dual-mode antibacterial action of its cation and anion, Ce6-IL was more effective against Gram-negative and Gram-positive bacteria than Ce6 alone and had wide-spectrum antibacterial ability. The in vitro studies showed that the IC50 of Ce6-IL against E. coli and S. aureus was reduced by 100 and 10 times, respectively. Furthermore, the in vivo studies indicated that Ce6-IL was more effective for eliminating bacterial infection and could accelerate wound healing. The compatibility test showed that Ce6-IL had low toxicity and exhibited excellent biocompatibility.