Aqueous suspensions of poly(ethylene oxide)-grafted nanocrystalline cellulose (PEO-grafted NCC) were prepared in order to achieve steric instead of electrostatic stabilization. A two-step process was employed: in the first step NCC suspensions prepared by sulfuric acid hydrolysis were desulfated with sodium hydroxide, and in the second step the surfaces of the crystals were functionalized with epoxy-terminated poly(ethylene oxide) (PEO epoxide) under alkaline conditions. The PEO-grafted samples were analyzed by conductometric titration, ATR-IR, solid-state NMR, MALDI-TOF MS, SEC MALLS, and AFM. The covalent nature of the linkage was confirmed by weight increase and MALDI-TOF analysis. The PEO-grafted cellulose nanocrystals (CNCs) formed a stable colloidal suspension that remained well dispersed, while the desulfated nanoparticles aggregated and precipitated. Upon concentration of the PEO-grafted aqueous NCC suspension, a chiral nematic phase was observed.
Contrary to concepts handed down in the literature from the early days of vitamin E research, one-electron oxidation of vitamin E does not involve 5a-C-centered radicals. A combined approach of analytical techniques, in particular electron paramagnetic resonance spectroscopy (EPR), organic synthesis of special derivatives, isotopic labeling, kinetic studies, and computational chemistry was used to re-evaluate the one-electron and two-electron oxidation chemistry of alpha-tocopherol (alpha-toc). EPR in combination with 5a-13C-labeled compounds provided no indication of the involvement of 5a-C-centered radicals. Oxidation of special tocopherol derivatives were used to disprove the occurrence of 5a-C-centered one-electron intermediates. Additionally it was shown that those vitamin E reactions that were commonly evoked to plead for the involvement of C-centered tocopheryl radicals actually proceeded via heterolytic, i.e., non-radical, intermediates. The results will help to clear widely spread misunderstandings about the chemistry of vitamin E and will have mechanistic implications for the synthesis of tocopherol-based supramolecular structures and 5a-substituted alpha-tocopherol derivatives.
γ‐Tocopherol, a component of the essential nutrient mixture commonly designated as vitamin E, was chemically combined with differently substituted monofluoro‐ and difluorophenyl moieties to produce potential antagonists for the human aryl hydrocarbon receptor (AhR). 5‐Iodo‐γ‐tocopherol was a very reliable starting material for the Pd‐catalyzed reaction with (fluorophenyl)boronic acids (Suzuki coupling). The ortho‐ and meta‐fluoro‐substituted derivatives showed conformational isomerism due to restricted rotation around the interaromatic bond. This effect was investigated by NMR spectroscopy. Three of the derivatives showed very high potency in assays and are promising candidates for further testing.
The oxidative effect of carbanilation mixtures containing dimethylsulfoxide (DMSO) was demonstrated by means of alcohol model substances in which competitive carbanilation was prevented due to steric hindrance of the hydroxyl function, rendering those compounds specific probes for oxidation effects. Dimethylsulfonium ions and derived ylide species were shown to be the actually oxidizing species according to trapping methodology using lipophilic olefins which were converted into the corresponding cyclopropane and epoxide derivatives. The experimental data were in good agreement with DFT computations carried out on the B3LYP/6-311+G(d,p) level of theory. The direct interaction of cellulose and sulfoxide solvent was proven by means of methyl-(2-naphthyl)sulfoxide (MNSO) as a model for DMSO, which caused introduction of UV-detectable methylthionaphthyl ether moieties into the cellulose, formed in Pummerer-type side reaction paralleling the chemical behavior of DMSO. A facile color test-responding to sulfoxide-derived oxidizing species-was developed to assess the suitability of carbanilation conditions with regard to cellulose oxidation and degradation. DMSO-based carbanilation systems have to be used with great caution for determination of molecular weight parameters and for similar purposes which require complete maintenance of the cellulose integrity. Cellulose oxidation/ degradation by DMSO-derived intermediates upon carbanilation can be minimized but cannot be avoided completely. Thus, if cellulose integrity is an issue as it is in cellulose analytics, it is recommended to replace DMSO by solvent components of similar solution behavior but without the inherent danger of generating oxidants, such as pyridine or DMAc, whenever possible.
Cellulose nanocrystals (CNCs) form liquid crystals in aqueous solution that confer alignment to macromolecules and permit the measurement of residual dipolar couplings. CNCs possess many attractive features as an alignment medium. They are inexpensive, non-toxic, chemically inert, and robust to denaturants and temperature. Despite these advantages, CNCs are seldom employed as an alignment medium and the range of their applicability has not yet been explored. We have re-examined the use of CNCs in biomolecular NMR by analyzing the effects concentration, ionic strength, and temperature on molecular alignment. Stable alignment was obtained over wide ranges of temperature (10-70 degrees C) and pH (2.5-8.0), which makes CNCs potentially very useful in studies of thermophilic proteins and acid-stabilized molecules. Notably, we find that CNC suspensions are very sensitive to the concentrations of biological buffers, which must be taken into account when they are used in NMR analyses. These results have led us to develop a general procedure for preparing aligned samples with CNCs. Using the SH3 domain from the Fyn tyrosine kinase as a model system, we find that CNCs produce an alignment frame collinear with that of the commonly used Pf1 bacteriophage alignment medium, but of opposite magnitude.
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