In this study we present detailed characterization of a protein-PEG conjugate using two separation techniques, that is, asymmetrical-flow field-flow fractionation (AF4) and size-exclusion chromatography (SEC), which were onlinecoupled to a series of successively connected detectors: an ultraviolet,a multiangle light-scattering, a quasi-elastic light-scattering, and a refractive-index detector (UV-MALS(QELS)-RI). Matrix-assisted laser-desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) was used as a complementary characterization technique. The results of AF4 as well as SEC on two columns connected in series, with both separation techniques coupled to a multidetection system, indicate the uniform molar massand chemical composition of the conjugate, that is, the molar ratio of protein to PEG is 1/1, the presence of minute amounts of residual unreacted protein and the aggregates with the same chemical composition as that of the conjugate. Since the portion of aggregated species is smaller in the acetate buffer solution containing 5% sorbitol than in the acetate buffer solution with 200-mM sodium chloride, the former buffer solution is more suitable for conjugate storage. The separation using only one SEC column results in poorly resolved peaks of the PEGylated protein conjugate and the aggregates, whereas MALDI-TOF MS analysis reveal the presence of the residual protein, but not theaggregates.
COBISS.SI-ID: 5034522
We analyzed various miktoarm star copolymers of the PS(PI)x type (x = 2, 3, 5, 7), which consist of one long polystyrene (PS) arm (82 or 105 kDa) and various numbers of short polyisoprene (PI) arms (from 11.3 to 39.7 kDa), prepared by anionic polymerization and selective chlorosilane chemistry. The length of the PI arm in stars decreases with the number of arms, so that the chemical compositions of all PS(PI)x samples were comparable. Our aim was to determine the purity of samples and to identify exactly the constituents of individual samples. For this purpose we used a variety of separation techniques (size-exclusion chromatography (SEC), reversed-phase liquid-adsorption chromatography (RP-LAC), and two-dimensional liquid chromatography (2D-LC)) and characterization techniques (UV-MALS- RI multidetection SEC system, NMR, and MALDI-TOF MS). The best separation and identification of the samples' constituents were achieved by RP-LAC, which separates macromolecules according to their chemical composition, and a subsequent analysis of the off-line collected fractions from the RP-C18 columnby SEC/UV-MALS-RI multidetection system. The results showed that all PS(PI)x samples contained the homo-PS and homo-PI in minor amounts and the high-molar-mass (PS)y(PI)z (y ) 1) species, the content of which is higher in the samples PS(PI)5 and PS(PI)7 than in the samples PS(PI)2 and PS(PI)3. The major constituent of the PS(PI)2 sample was the one with the predicted structure. On the other hand, the major components of the PS(PI)x (x = 3, 5, and 7) samples were the stars consisting of a smaller number of PI arms than predicted from the functionalities of chlorosilane coupling agents. These results are in agreement with the average chemical composition of samples determined by proton NMR spectroscopy and characterization of the constituentsby MALDI-TOF MS.
COBISS.SI-ID: 5044506
Poly(methylmetacrylate)/montmorillonite (PMMA)/(MMT) nanocomposites were prepared by a one-step in situ intercalative solution polymerization involving the simultaneous modification of the MMT with a quaternary ammonium salt (cetyl-trimethylammonium bromide, CTMAB), polymerization and polymer intercalation. Using benzoyl peroxide as an initiator, intercalated nanocomposites were formed and characterized by NMR, DSC, TGA, XRD, TEM and SEC. It was observed that it was not the MMT, but rather the CTMAB, that influences the polymerization reaction, especially the reaction yield, the molar mass averages and the molar mass distribution of the PMMA. The thermal stability of the PMMA was improved by the addition of both the MMT and/or the CTMAB.
COBISS.SI-ID: 5026330
In our research, we have utilized high energy ultrasound for the liquefaction of different lignocellulosic materials, wood wastes in particular. We developed a highly efficient way of transforming this biomass waste into valuable chemicals. It was found, that the reaction yield in all experiments was high and that the reaction times were shortened up to nine times when using the ultrasound process with smaller residual particles and with no influence on the hydroxyl number of the final products. The use of the ultrasound process inhibits the formation of the large molecular structures during the liquefaction from the degradation products, by keeping the reactive segments apart and due to such a short reaction time being used. The short reaction time and subsequent low energy consumption for the liquefaction reaction leads to the creation of the new method for the transformation of the wood waste materials into valuable chemicals.
COBISS.SI-ID: 1964681