Relevance of Rheological Properties of Sodium Alginate in Solution to Calcium Alginate Gel Properties

Abstract. 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. Interbatch differences in the rheological behavior for one specific grade of sodium alginate were insufficient to predict the corresponding calcium alginate gel's mechanical properties

Understanding Deformation Behavior and Compression Speed Effect in Gabapentin Compacts

Deformation mechanism and strain rate sensitivity of gabapentin powder was investigated in this work. Heckel analysis, specific surface area and indentation hardness measurements revealed an intermediate yield pressure and brittle fracture as the dominant type of deformation mechanism during consolidation. Strain rate sensitivity of gabapentin was studied by compressing it at 1 mm/min and 500 mm/min compression speeds. Gabapentin demonstrated an atypical strain rate sensitivity in compactibility profile (tensile strength vs. solid fraction). Compacts of gabapentin compressed at fast speed showed an increase in tensile strength when compared with those compressed at slow speed. To understand the effect of compression speed on gabapentin\u27s compactibility, PXRD analysis, surface area analysis, indentation hardness measurements, and consolidation modeling were performed. PXRD analysis carried out on compacts revealed no effect of speed on the physical solid-state stability of gabapentin. Specific surface area of compacts made at fast speed was higher than that of compacts made at slow speed. Indentation measurements performed on gabapentin compacts showed higher values of hardness in the case compacts made at fast speed. It was identified that at the fast compression speed, gabapentin shows greater particle fragmentation and form compacts with smaller pores

Baseline studies of the clay minerals society special clays: Specific surface area by the Brunauer Emmett Teller (BET) method

İrem Yeşilyurt, F. ( Aksaray, Yazar )The Clay Minerals Society published a complete characterization scheme for its ‘Source Clays’ but not for its ‘Special Clays’. To address this issue, the specific surface areas (SSAs) of the 16 special clays from The Clay Minerals Society were determined using the Brunauer, Emmett and Teller (BET) method of adsorption of an inert gas. Two BET measurements were performed for each of the 16 special clays, and the average BET SSA of each of the special clays was determined. The BET SSA of cookeite is reported for the first time. In the present study, special clays from The Clay Minerals Society are classified under three groups based on their BET special surface area values as Group-I special clays, with BET values of 0.1–10 m2/g, Group-II special clays, with BET values of 10–100 m2/g, and Group-III special clays, with BET values >100 m2/g. Comparisons which proved interesting were the those involving the mixed-layer clays and the synthetic clays. The systematic approach employed in this paper will allow for better comparisons to be made between different clays and will provide a comprehensive database for future applications of such material (e.g. as catalyst carriers, as adsorbents in waste treatments, etc.)...

Relevance of Rheological Properties of Sodium Alginate in Solution to Calcium Alginate Gel Properties

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 (LE) and apparent viscosity (ηapp). However, the results for the partial correlation analysis for all six grades of sodium alginate show that LE 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 ηapp of their solutions did not correlate with LE while tan δ was significantly, but minimally, correlated to LE. 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