X-ray structures of $${\bf 14}^+\hbox{BF}_4^{-}$$ and $${\bf...
X-ray structures of $${\bf 14}^+\hbox{BF}_4^{-}$$ and $${\bf 15}^+\hbox{BF}_4^{-}$$ , showing hexagonal channels lined with phenyl groups.
View ArticleThe hydrogen-bonding interactions occurring in these systems are illustrated...
The hydrogen-bonding interactions occurring in these systems are illustrated in Scheme 3 .
View ArticleAs expected, deprotonation of $${\bf 9}^{+}\hbox{BF}_{4}^{-}$$ with KO t Bu...
As expected, deprotonation of $${\bf 9}^{+}\hbox{BF}_{4}^{-}$$ with KO t Bu in THF occurred readily to afford the semiquinone and the quinone ( 10 ) (Scheme 2 ).
View ArticleNetwork (8) generated by the octahedral coordination of p-QMTC spacers to...
Network (8) generated by the octahedral coordination of p-QMTC spacers to Eu(III) nodes (hydrogens and carbonyls omitted for clarity). The network illustrated contains three unique p-QMTC units and...
View Article$$\uppi$$ – $$\uppi$$ stacking in [Eu(p-QMTC)(phen)(NO3)2(DMSO)]2 (7)...
$$\uppi$$ – $$\uppi$$ stacking in [Eu(p-QMTC)(phen)(NO3)2(DMSO)]2 (7) [Mn(CO)3 units and hydrogens omitted for clarity].
View ArticleNovel 3D MOMN derived from the anionic manganese quinone complex p-QMTC,...
Novel 3D MOMN derived from the anionic manganese quinone complex p-QMTC, dipyridyl disulfide (DPDS) linker and M(OAc)2 in MeOH solvent. The empirical formula is [M3(OAc)2(p-QMTC)4(DPDS)], M=Ni...
View ArticleThe X-ray structure of the one-dimensional MOMN derived from the anionic...
The X-ray structure of the one-dimensional MOMN derived from the anionic quinone complex (m-QMTC) and Cu(II) in DMSO. The empirical formula is [Cu(m-QMTC)2DMSO]∞.
View Article3D honeycomb metal-organometallic coordination network generated by p-QMTC...
3D honeycomb metal-organometallic coordination network generated by p-QMTC spacers and Cu(II) nodes, which adopt a square planar geometry.
View Article3D network [Cd(p-QMTC)2(4,4′-bipy)]∞ with (a) DMSO (left) and (b) NMP...
3D network [Cd(p-QMTC)2(4,4′-bipy)]∞ with (a) DMSO (left) and (b) NMP (right) solvent located in the rectangular micropores.
View ArticleRisk Factors for Immunological Responses Against Injectable DDS
Risk Factors for Immunological Responses Against Injectable DDS
View ArticleImmunological Reactions Against Injectable DDS and their Clinical Consequences
Immunological Reactions Against Injectable DDS and their Clinical Consequences
View ArticleRelative Risk of Immunogenicity for Several Antigen Categories
Relative Risk of Immunogenicity for Several Antigen Categories
View ArticleSimplified schematic presentation of the interrelationship between the...
Simplified schematic presentation of the interrelationship between the immunological reactions discussed in the text. The dashed arrows represent possible, not yet confirmed pathways for platelet...
View ArticleSchematic illustration of the interaction of molecules (orange bullets,...
Schematic illustration of the interaction of molecules (orange bullets, which can be drugs, targeting ligands, or repeat units of a polymer) with B cell receptors (BCRs, surface immunoglobulins on B...
View ArticlePrincipal Characteristics of Active Ingredient Polymer—Carriers
Principal Characteristics of Active Ingredient Polymer—Carriers
View ArticleConcentration dependences of wetting angle of model substrate by aqueous...
Concentration dependences of wetting angle of model substrate by aqueous polymer solutions and their mixtures with taurine: dextran (1), PHMG (1′) and their mixtures with taurine (2 and 2′,...
View ArticleDetermination of minimum σ∞ of polymer solutions (1) and their mixtures with...
Determination of minimum σ∞ of polymer solutions (1) and their mixtures with taurine (2) using dextran as an example.
View ArticleSurface tension of aqueous polymer solutions and their mixtures with taurine...
Surface tension of aqueous polymer solutions and their mixtures with taurine as functions of concentration: dextran (1), PHMG (1′), their mixtures with taurine (2 and 2′, respectively) (a); Sovidon...
View ArticleTypical time dependences of surface tension of aqueous dextran solutions and...
Typical time dependences of surface tension of aqueous dextran solutions and its mixture with taurine: dextran (1), mixture of dextran and taurine (2). Dextran concentration in aqueous solutions, 0.16...
View ArticlePenetration of drug drops into the eye through the lacrimal film.
Penetration of drug drops into the eye through the lacrimal film.
View ArticleJ-Vcharacteristics of polymer photovoltaic devices using pentacene-doped...
J-Vcharacteristics of polymer photovoltaic devices using pentacene-doped PEDOT:PSS as a hole-conducting layer.
View ArticleSEM images of pentacene-doped PEDOT:PSS films. Annealed at (a) 120°C, (b)...
SEM images of pentacene-doped PEDOT:PSS films. Annealed at (a) 120°C, (b) 140°C, (c) 160°C, and (d) 180°C for 1 h.
View ArticleAFM images of pentacene-doped PEDOT:PSS films. Annealed at (a) 120°C, (b)...
AFM images of pentacene-doped PEDOT:PSS films. Annealed at (a) 120°C, (b) 140°C, (c) 160°C, and (d) 180°C for 1 h.
View ArticleSurface resistance of pentacene-doped PEDOT:PSS films.
Surface resistance of pentacene-doped PEDOT:PSS films.
View ArticleWork function of pentacene-doped PEDOT:PSS films.
Work function of pentacene-doped PEDOT:PSS films.
View ArticleUV-visible transmittance spectra of pentacene-doped PEDOT:PSS films. The...
UV-visible transmittance spectra of pentacene-doped PEDOT:PSS films. The inset shows the magnified spectra from 530 to 550 nm.
View ArticleSEM micrographs of samples of the nanosystems SiO2-graft-PVP/Ag(nano) (a)...
SEM micrographs of samples of the nanosystems SiO2-graft-PVP/Ag(nano) (a) and SiO2-graft-PAA/Ag(nano) (b). Scale on insets: 0.1 μm.
View ArticleIR spectra of samples of SiO2 (1), SiO 2 TSM (2), SiO2-graft-PVP (3), and...
IR spectra of samples of SiO2 (1), SiO 2 TSM (2), SiO2-graft-PVP (3), and SiO2-graft-PAA (4).
View ArticleIn the last step, the silver nanoparticles formed on reduction of Ag+ by DMF...
In the last step, the silver nanoparticles formed on reduction of Ag+ by DMF (Scheme (3)) [11] are stabilized by the polymer component of the hybrid systems, forming nanocomposites of the...
View ArticleThen SiO2 with methacrylate groups enters into the reaction of...
Then SiO2 with methacrylate groups enters into the reaction of photoinitiated radical polymerization with N-vinylpyrrolidone or acrylic acid, and as a result the hybrid organic/inorganic systems...
View ArticleThe proposed method for synthesis of hybrid nanocomposites involves reaction...
The proposed method for synthesis of hybrid nanocomposites involves reaction of silanol groups on the surface of highly disperse SiO2 with 3-(trimethoxysilyl)propyl methacrylate, with liberation of...
View ArticlePermeation Kinetics of Tramadol HCL from Monolithic Matrix Films
Permeation Kinetics of Tramadol HCL from Monolithic Matrix Films
View ArticlePermeation of Tramadol HCL from the Monolithic Matrix Films
Permeation of Tramadol HCL from the Monolithic Matrix Films
View ArticleEffectiveness of Various Polymer-Welding Methods
Effectiveness of Various Polymer-Welding Methods
View ArticleChemical structure of polyvinyl caprolactam–polyvinyl acetate–polyethylene...
Chemical structure of polyvinyl caprolactam–polyvinyl acetate–polyethylene glycol graft copolymer (Soluplus®)
View ArticleEndothermic and Exothermic Events of GMO as Seen During Different Cycles of...
Endothermic and Exothermic Events of GMO as Seen During Different Cycles of MDSC
View ArticleExothermic and Endothermic Events Observed in GMO
Exothermic and Endothermic Events Observed in GMO
View ArticleThermal Analysis of GMO by Utilizing Various Heat-Cool-Heat Cycles of MDSC
Thermal Analysis of GMO by Utilizing Various Heat-Cool-Heat Cycles of MDSC
View ArticlePhysicochemical characterization and formulation consideration for...
Physicochemical characterization and formulation consideration for preparation of SLN
View Articlea MDSC of GMO physical mixtures with PVP, Eudragit, HPMC, and PEG; b MDSC of...
a MDSC of GMO physical mixtures with PVP, Eudragit, HPMC, and PEG; b MDSC of GMO physical mixtures with poloxamer, mineral oil, and olive oil
View ArticleExothermic and endothermic events observed in the MDSC of pure GMO,...
Exothermic and endothermic events observed in the MDSC of pure GMO, GMO-chitosan physical mixture, and freeze-dried GMO nanoparticles
View ArticleNMR of pure GMO and lab-grade GMO used in our study. The arrow indicates the...
NMR of pure GMO and lab-grade GMO used in our study. The arrow indicates the difference observed between pure GMO and lab-grade GMO
View Articlea XRD of pure GMO at room temperature; b MDSC of pure GMO; and c cryo-XRD at...
a XRD of pure GMO at room temperature; b MDSC of pure GMO; and c cryo-XRD at various temperatures during cooling and heating
View ArticleMDSC thermograms of different batch of GMO. Two samples of each GMO, its...
MDSC thermograms of different batch of GMO. Two samples of each GMO, its supernatant and its sediment were shown. (1, 2) represents cooling cycles and (3, 4) of heating cycle of GMO, (5, 6) represents...
View ArticleEndothermic and exothermic events of GMO as seen during different...
Endothermic and exothermic events of GMO as seen during different heat-cool-heat cycles of MDSC. The analysis showed that heating and cooling of GMO can result in changes in the exothermic and...
View ArticleCryo-microscopy of GMO during cooling and heating of melted GMO. The figure...
Cryo-microscopy of GMO during cooling and heating of melted GMO. The figure represents the visual confirmation of crystallization and melting events of GMO with change in temperature
View ArticleCryo-XRD of GMO. X-ray taken at different temperature during cooling of...
Cryo-XRD of GMO. X-ray taken at different temperature during cooling of melted GMO. The temperatures are selected based on the endothermic and exothermic events observed in MDSC of GMO
View ArticleExothermic and endothermic events observed in the MDSC of GMO. Cycle 2...
Exothermic and endothermic events observed in the MDSC of GMO. Cycle 2 represents the cooling cycle and cycle 3 represents the heating cycle. Cycle 1 is heating of GMO at constant rate to completely...
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