Evaluation of polymeric methacrylate-based monoliths in capillary electrochromatography for their potential to separate pharmaceutical compounds

Polymeric methacrylate-based monoliths are evaluated in capillary electrochromatography (CEC) and pressurized capillary electrochromatography (p-CEC) for their potential in pharmaceutical analysis. Using a given polymerization mixture as a basis for the monolith synthesis, different mobile phase pH at constant organic modifier concentrations are tested in both CEC and p-CEC. The test set consists of basic, acidic, amphoteric, and neutral compounds, which are mainly pharmaceuticals. Because of the mainly hydrophobic character of the stationary phase, the interactions are largest when the compounds appear in an uncharged state, but some ion-exchange phenomena with negatively charged compounds can also be observed. In CEC, acidic substances are most retained at low pH. For amphoteric and neutral compounds, no preference regarding analyzing pH can be derived from these experiments. For basics, a high pH is chosen, but a reduced solvent strength is needed to enhance the retention of these compounds. The retention mechanism in p-CEC can also be assigned to both hydrophobic and ionic interactions. For acidic, amphoteric, and neutral compounds, acceptable retention is seen. For the basic compounds, the retention with a mobile phase containing 50% organic modifier is low, as in CEC. However, when the organic modifier content in the mobile phase is decreased, retention increases and the selectivity of the stationary phase is more pronounced. This mode of operation presents a possibility for separating some test mixtures, thus some potential for pharmaceutical analysis is seen. More efforts are needed to obtain higher efficiencies and better peak shapes, which might be solved by a further optimization of both the stationary phase synthesis and the mobile phase composition.     

Light-driven horseradish peroxidase cycle by using photo-activated methylene blue as the reducing agent

In this work, the regeneration of native horseradish peroxidase (HRP), following the consecutive reduction of oxo-ferryl pi-cation (compound I) and oxo-ferryl (compound II) forms, was observed by UV-visible spectrometry and electron paramagnetic resonance (EPR) in the presence of methylene (MB+), in the dark and under irradiation. In the dark, MB+ did not affect the rate of HRP compound I and II reduction, compatible with hydrogen peroxide as the solely reducing species. Under irradiation, the dye promoted a significant increase in the native HRP regeneration rate in a pH-dependent manner. Flash photolysis measurements revealed significant redshift of the MB+ triplet absorbance spectrum in the presence of native HRP. This result is compatible with the dye binding on the enzyme structure leading to the increase in the photogenerated MB* yield. In the presence of HRP compound II, the lifetime of the dye at 520 nm decreased approximately 75% relative to the presence of native HRP that suggests MB* as the heme iron photochemical reducing agent. In argon and in air-saturated media, photoactivated MB+ led to native HRP regeneration in a time- and concentration-dependent manner. The apparent rate constant for photoactivated MB+-promoted native HRP regeneration, in argon and in air-saturated medium and measured as a function of MB+ concentration, exhibited saturation that is suggestive of dye binding on the HRP structure. The dissociation constant (KMB) observed for the binding of dye to HRP was 5.4+/-0.6 microM and 0.57+/-0.05 microM in argon and air-saturated media, respectively. In argon-saturated medium, the rate of the conversion of HRP compound II to native HRP was significantly higher, k2argon=(2.1+/-0.1)x10(-2) s(-1), than that obtained in air-equilibrated medium, k2air=(0.73+/-0.02)x10(-2) s(-1). Under these conditions the efficiency of photoactivated MB(+)-promoted native HRP regeneration was determined in argon and air-equilibrated media as being, respectively: k2/KMB=3.9x10(3) and 12.8x10(3) M(-1) s(-1).     

Specific interactions improve the loading capacity of block copolymer micelles in aqueous media

Block copolymer micelles find application in many fields as nanocarriers, especially in drug delivery. We report herein that specific interactions between hydrophobic guest molecules and core-forming segments can significantly improve the loading capacity of polymeric micelles. High loading capacities (>100% weight/weight of polymer (w/wp)) were systematically observed for the encapsulation of probes containing weak carboxylic acid groups by micellar nanoparticles having poly[2-(dialkylamino)ethyl methacrylate] cores (i.e., particles whose cargo space exhibits antagonist weak base functions), as demonstrated by the incorporation of indomethacin (IND), ibuprofen (IBPF), and trans-3,5-bis(trifluoromethyl)cinnamic acid (F-CIN) into either poly(ethylene oxide)-b-poly[2-(diisopropylamino)ethyl methacrylate] (PEO-b-PDPA) or poly(glycerol monomethacrylate)-b-PDPA (PG2MA-b-PDPA) micelles. The esterification of IND yielding to a nonionizable IND ethyl ester derivative (IND-Et) caused an abrupt decrease in the micellar loading capacity down to 10-15% w/wp. Similar results were also obtained when IND was combined with nonionizable block copolymers such as PEO-b-polycaprolactone (PEO-b-PCL) and PEO-b-poly(glycidyl methacrylate) (PEO-b-PGMA). The existence of acid-base interactions between the solubilizate and the weak polybase block forming the micelle core was confirmed by 1H NMR measurements. However, the incorporation of high numbers of hydrophobic guest molecules inside polymeric micelles can provoke not only an increase in the hydrodynamic size (2RH) of the objects but also a substantial change in the morphology (transition from spheres to cylinders). The application of the Higuchi model showed that the probe release followed a diffusion-controlled mechanism, and diffusion coefficients (D) on the order of 10-18-10-17 cm2/s were determined for IND release from 1.0 mg/mL PEO113-b-PDPA50 + 100% w/wp IND. Probe release from micelles with weak polybase-based cores can also be triggered by changes in the solution pH.     

The reaction of thiourea to dicyandiamidine sulfate on silver surfaces investigated by reflection-absorption infrared spectroscopy

The reaction pathway of thiourea degradation on silver surfaces was investigated with reflection-absorption infrared spectroscopy. Adsorption of thiourea from aqueous solution produces a thin stable thiourea film that is not removed by rinsing. Aging at elevated temperature results in conversion to dicyandiamidine sulfate. The same reaction product is observed on daguerreotypes that were treated with commercial thiourea based silver cleaner.     

Thermosensitive lactitol-based polyether polyol (LPEP) hydrogels

A series of new thermosensitive polymer hydrogels were prepared by reacting acylated poly(ethylene glycol) bis(carboxymethyl) ether (PEGBCOCl) with lactitol-based polyether polyols (LPEP). The polyether polyols were generated from propoxylation of lactitol and have molecular weights ranging from 1337 to 4055 g/mol. The hydrogels absorb water up to 1000% of their dry weight and expel free water at temperatures at and above 30°C. The wide ranging swelling behavior and excellent thermosensitivity depend closely on the degree of crosslinking and the propylene oxide lengths in the polyols. Differential scanning calorimetry of the hydrogels showed two endotherms associated with the phase transitions of PO and EO segments in the hydrogel structures. © 1998 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 36: 979–984, 1998     

Metallosupramolecular Thin Polyelectrolyte Films

Molecular recognition and electrostatic interaction of oppositely charged polyelectrolytes are combined in the fabrication of ultrathin metallosupramolecular multilayers [shown schematically in the picture, PEI=polyethyleneimine, PSS=poly(styrene sulfonate)]. The layers between the PSS layers are composed of an iron(II ) bis(terpyridine) coordination polymer.