Predicting capsule fill weight from in-situ powder density measurements using terahertz reflection technology

The manufacturing of the majority of solid oral dosage forms is based on the densification of powder. A good understanding of the powder behavior is therefore essential to assure high quality drug products. This is particularly relevant for the capsule filling process, where the powder bulk density plays an important role in controlling the fill weight and weight variability of the final product. In this study we present a novel approach to quantitatively measure bulk density variations in a rotating container by means of terahertz reflection technology. The terahertz reflection probe was used to measure the powder density using an experimental setup that mimics a lab-scale capsule filling machine including a static sampling tool. Three different grades of α-lactose monohydrate excipients specially designed for inhalation application were systematically investigated at five compression stages. Relative densities predicted from terahertz reflection measurements were correlated to off-line weight measurements of the collected filled capsules. The predictions and the measured weights of the powder in the capsules were in excellent agreement, where the relative density measurements of Lactohale 200 showed the strongest correlation with the respective fill weight (R 2 =0.995). We also studied how the density uniformity of the powder bed was impacted by the dosing process and the subsequent filling of the holes (with excipient powder), which were introduced in the powder bed after the dosing step. Even though the holes seemed to be filled with new powder (by visual inspection), the relative density in these specific segments were found to clearly differ from the undisturbed powder bed state prior to dosing. The results demonstrate that it is feasible to analyze powder density variations in a rotating container by means of terahertz reflection measurements and to predict the fill weight of collected capsules

From nucleotides to ribozymes — A comparison of their metal ion binding properties

It is undisputable that the fates of metal ions and nucleic acids are inescapably interwoven. Metal ions are essential for charge compensation of the negatively charged phosphate–sugar backbone, they are instrumental for proper folding, and last but not least they are crucial cofactors for ribozyme catalysis. Considerable progress has been achieved in the past few years on the identification of metal ion binding sites in large DNA and RNA molecules, like in ribozymes including the ribosome. Hereby, most information was gained from crystallography, which fails to explain metal ion binding equilibria in solution as well as the factors that determine the coordination of a metal ion to a specific site. In contrast, such information is readily available for the low-molecular building blocks of large nucleic acids, i.e. for mononucleotides and to some extent also dinucleotides. In this review, we combine and compare for the first time both sets of information. The focus is thereby set on Mg2+, Ca2+, Mn2+, and Cd2+ because these four metal ions are either freely available in cells, have a large impact on the catalytic rate of ribozymes, and/or are often applied in RNA biochemistry. Our comparisons show that results obtained from small molecules can be directly transposed to the findings in large RNA structures like the ribosome. For example, the basic coordination-chemical properties of the different metal ions are reflected in their binding to large nucleic acid structures: macrochelate formation, e.g. the simultaneous intranucleotide coordination of a Mg2+ ion to the phosphate unit and the N7 site of a purine nucleobase (be it inner- or outersphere), is well known for mononucleotides. We show that the frequency of occurrence of this type of coordination is the same for mononucleotides and the ribosome