The purpose of this study is to determine whether sodium alginate solutions' rheological parameters are meaningful relative to sodium alginate's use in the formulation of calcium alginate gels. Calcium alginate gels were prepared from six different grades of sodium alginate (FMC Biopolymer), one of which was available in ten batches. Cylindrical gel samples were prepared from each of the gels and subjected to compression to fracture on an Instron Universal Testing Machine, equipped with a 1-kN load cell, at a cross-head speed of 120 mm/min. Among the grades with similar % G, (grades 1, 3, and 4), there is a significant correlation between deformation work (L(E)) and apparent viscosity (η(app)). However, the results for the partial correlation analysis for all six grades of sodium alginate show that L(E) is significantly correlated with % G, but not with the rheological properties of the sodium alginate solutions. Studies of the ten batches of one grade of sodium alginate show that η(app) of their solutions did not correlate with L(E) while tan δ was significantly, but minimally, correlated to L(E). These results suggest that other factors--polydispersity and the randomness of guluronic acid sequencing--are likely to influence the mechanical properties of the resultant gels. In summary, the rheological properties of solutions for different grades of sodium alginate are not indicative of the resultant gel properties. Inter-batch differences in the rheological behavior for one specific grade of sodium alginate were insufficient to predict the corresponding calcium alginate gel's mechanical properties.
Abstract. Polymeric excipients are often the least well-characterized components of pharmaceutical formulations. The aim of this study was to facilitate the QbD approach to pharmaceutical manufacturing by evaluating the inter-grade and inter-batch variability of pharmaceutical-grade polymeric excipients. Sodium alginate, a widely used polymeric excipient, was selected for evaluation using appropriate rheological methods and test conditions. The materials used were six different grades of sodium alginate and an additional ten batches of one of the grades. To compare the six grades, steady shear measurements were conducted on solutions at 1%, 2%, and 3% w/w, consistent with their use as thickening agents. Small-amplitude oscillation (SAO) measurements were conducted on sodium alginate solutions at higher concentrations (4-12% w/w) corresponding to their use in controlled-release matrices. In order to compare the ten batches of one grade, steady shear and SAO measurements were performed on their solutions at 2% w/w and 8% w/w, respectively. Results show that the potential interchangeability of these different grades used as thickening agents could be established by comparing the apparent viscosities of their solutions as a function of both alginate concentration and shear conditions. For sodium alginate used in controlled-release formulations, both steady shear behavior of solutions at low concentrations and viscoelastic properties at higher concentrations should be considered. Furthermore, among batches of the same grade, significant differences in rheological properties were observed, especially at higher solution concentrations. In conclusion, inter-grade and inter-batch variability of sodium alginate can be determined using steady shear and small-amplitude oscillation methods.
An improved pentafluorobenzylation method was developed for derivatization of L-tryptophan and its acidic metabolites (L-kynurenine, kynurenic acid, anthranilic acid, xanthurenic acid, 3-hydroxyanthranilic acid, picolinic acid, quinolinic acid) present at trace levels in aqueous samples. This method employs lyophilization of aqueous samples in the presence of excess tetrabutylammonium hydrogen sulfate, followed by base-catalyzed anhydrous pentafluorobenzylation. A comparison with other published methods shows the advantage of this modification for the derivatization of kynurenine metabolites. The derivatives were analyzed by gas chromatography/electron capture negative ion mass spectrometry (GC/ECNI-MS) or liquid chromatography/particle beam/ECNI-MS (LC/ECNI-MS). The detection limits for injected standards are in the femtogram range by GC/ECNI-MS and in the low picogram range by LC/ECNI-MS. GC/ECNIMS is 3.6 (xanthurenic acid) to 66 (quinolinic acid) times more sensitive than LC/ECNI-MS. The simultaneous determination of two neuroactive metabolites, quinolinic and kynurenic acids, in culture medium is presented. The minimum measurable concentrations of these metabolites in 100 microL of culture medium are 0.11 nM for quinolinic acid and 0.21 nM for kynurenic acid.
This investigation involved the evaluation of the emulsifier blend effect on the development of sustained release diclofenac microspheres intended for use in a suspension formulation. The microspheres were prepared using the hydrophobic congealable disperse phase method. The emulsifier blend consisted of glycerol, monostearate (GMS), a hydrophobic emulsifier with HLB = 3.8, and Tween 80, a hydrophilic emulsifier with a HLB value of 15. The effect of this blend on the encapsulation efficiency, size distribution and drug release from the microspheres was studied. A critical amount of GMS (> 0.2 g) was found to be necessary for good encapsulation efficiency. X-ray diffractograms revealed that the drug retains its crystalline state within the microspheres, indicating that the drug is present as a dispersion within the wax matrix. Increasing amounts of Tween 80 caused an increase in the drug release while increased amounts of GMS retarded the release. The hydrophilic emulsifier and the emulsifier blend influenced the size distribution of the formed microspheres. With an increase in the amount of hydrophilic emulsifier, there was an initial increase in the percent of desired size fraction (137.5 microns) of microspheres followed by a decrease. Microspheres with a larger size released the drug slowly compared to smaller size microspheres, while increase in drug load increased the rate of drug release. The release pattern fitted the Higuchi dissolution kinetics for spherical matrices. Different impeller blade designs formed microspheres that exhibited different release rates. The microspheres (mean size 137.5 microns), had a release profile that made them suitable to be formulated as a sustained release suspension.
In a number of infectious and inflammatory diseases, stimulation of the immune system can lead to increased accumulation of tryptophan metabolites via induction of kynurenine pathway enzymes in extrahepatic tissues. We developed a liquid chromatographic/mass spectrometric (LC/MS) method suitable for tracing the disposition of 13C isotopomers of L-tryptophan and L-kynurenine in various cultured cell, tissue slice, and whole animal model systems used to investigate tryptophan flux through the kynurenine pathway. The method employs extractive derivatization of the analytes and their 2H internal standards with pentafluorobenzyl bromide in order to enhance the negative ion chemical ionization (NICI) mass spectrometric response. Normal-phase liquid chromatographic separation of derivatized analytes was optimized using a silica column with organic solvents, followed by particle beam transfer and NICI-MS. Standard curves were linear over the range 1-250 ng per sample. Particle beam and mass spectrometric operating parameters were optimized with direct flow injections of 1-(methylamino) anthraquinone, which is an ideal test compound for the evaluation of LC/NICI-MS. The developed method was used to quantify the conversion of (13C6)L-tryptophan to (13C6)L-kynurenine by human monocytes (THP-1) stimulated with interferon-gamma, lung and brain tissue slices obtained from gerbils immune-stimulated with pokeweed mitogen. The effect of whole body immune stimulation on the plasma levels of endogenous L-kynurenine in mice stimulated with interferon-gamma was also quantified.
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