Degradation Rate Observations as a Function of Drug Load in Solid-State Drug Products.

Degradation rates of solid-state drug products generally increase as the drug load decreases. A model for quantifying this effect based on surface area ratios is proposed here. This model relates the degradation rate to an estimate of the proportion of drug substance in contact with the excipient, and that the drug substance in contact with excipients degrades more quickly. Degradation data from previously published case studies and from 5 new case studies were found to be consistent with our proposed model; our model performed better than similar previously published models. It was also found that the relationship between degradation rate and drug load is largely independent of the temperature and humidity conditions, suggesting that drug load solely affects the pre-exponential factor of the Arrhenius equation and does not significantly affect the activation energy of the degradation process. A second method for calculating the proportion of the drug substance surface in contact with the excipient surface is presented in the Supplementary Material. Fundamentally, the 2 methods are very similar and provide almost identical fits to the experimental data.

Reproducibility of the Measurement of Bulk/Tapped Density of Pharmaceutical Powders Between Pharmaceutical Laboratories.

The bulk properties of a powder are dependent on the preparation, treatment, and storage of the sample, that is, how it was handled. The particles can be packed to have a range of bulk densities and, moreover, the slightest disturbance of the powder bed may result in a changed bulk density. Thus, the bulk density of a powder is often difficult to measure with good reproducibility and, in reporting the results, it is essential to specify how the determination was made. In this article, we measured the bulk density, tapped density, and calculated the Hausner ratio of commonly used excipients with similar tapped density testers and followed the United States Pharmacopeia 30-National Formulary 25-S1 testing procedure. Based on the analysis, within lot and lot-to-lot variability and the relative errors for bulk density, tapped density, and Hausner ratio were found to be acceptable. Lot-to-lot differences were generally not measurable using this test as they were found to be within the variability of the test. The results also indicated that there was no statistically significant bias between sites for tapped density and Hausner ratio, but there was a marginally significant bias in the bulk density data set.

Development of Near Infrared Spectroscopy-based Process Monitoring Methodology for Pharmaceutical Continuous Manufacturing Using an Offline Calibration Approach.

A near-infrared (NIR) calibration was developed using an efficient offline approach to enable a quantitative partial least-squares (PLS) chemometric model to measure and monitor the concentration of active pharmaceutical ingredients (API) in powder blends in the feed frame (FF) of a tablet press. The approach leveraged an offline "feed frame table," which was designed to mimic the full process from a NIR measurement perspective, thereby facilitating a more robust model by allowing more sources of variability to be included in the calibration by minimizing the consumption of API and other raw materials. The design of experiment (DOE) for the calibration was established by an initial risk assessment and included anticipated variability from factors related to formulation, process, environment, and instrumentation. A test set collected on the feed frame table was used to refine the PLS model. Additional fully independent test sets collected from the continuous drug product manufacturing process not only demonstrated the accuracy and precision of the model but also illustrated its robustness to material variability and process variability including mass flow rate and feed frame paddle speed. Further, it demonstrated that a calibration can be generated on the offline feed frame table and then successfully implemented on the full process equipment in a robust manner. Additional benefits of using the feed frame table include streamline model monitoring and maintenance activities in a manufacturing setting. The real-time monitoring enabled by this offline calibration approach can be useful as a key component of the control strategy for continuous manufacturing processes for drug products, including detecting special cause variations such as transient disturbances and enabling product collection/rejection based upon predetermined concentration limits, and may play an important role in enabling real-time release testing (RTRt) for manufactured pharmaceutical products.

Evaluation of a hydrophilic interaction liquid chromatography design space for sugars and sugar alcohols.

Based on a column-screening exercise, a column ranking system was developed for sample mixtures containing any combination of 26 sugar and sugar alcohol analytes using 16 polar stationary phases in the HILIC mode with acetonitrile/water or acetone/water mobile phases. Each analyte was evaluated on the HILIC columns with gradient elution and the subsequent chromatography data was compiled into a statistical software package where any subset of the analytes can be selected and the columns are then ranked by the greatest separation. Since these analytes lack chromophores, aerosol-based detectors, including an evaporative light scattering detector (ELSD) and a charged aerosol detector (CAD) were employed for qualitative and quantitative detection. Example qualitative applications are provided to illustrate the practicality and efficiency of this HILIC column ranking. Furthermore, the design-space approach was used as a starting point for a quantitative method for the trace analysis of glucose in trehalose samples in a complex matrix. Knowledge gained from evaluating the design-space led to rapid development of a capable method as demonstrated through validation of the following parameters: specificity, accuracy, precision, linearity, limit of quantitation, limit of detection, and range.

A Demonstration of Mixing Robustness in a Direct Compression Continuous Manufacturing Process.

The purpose of this work was to assess the impact of continuous mixing on tablet critical quality attributes (CQAs) manufactured using a continuous, direct compression process. A 9-run design of experiments (DoE) that bracketed the range of commercially relevant mixer speeds, mixer orientations, and mass flow rates was executed using a formulation containing a cohesive drug substance at relatively low drug load. Drug substance dispensed concentration using loss-in-weight feeders was within 1% of target for each experiment with 30-s mass flow relative standard deviation values of 3.5% or less. Higher mass flow rates resulted in first off tablets closer to target potency, a shorter tablet potency startup phase, and greater assurance of passing content uniformity testing. Dissolution profiles from the DoE runs that bracketed mixer shear conditions were similar, indicating mixing had minimal impact on drug substance release from the tablets. None of the DoE parameters had a practical impact on the description CQA (tablet breaking force, friability, and appearance). Collectively, these results highlight that for this study continuous mixing within a direct compression process is robust and is assessed as low risk of adversely impacting drug product CQAs provided there is appropriate control of the continuous feeders.

On-line application of near-infrared spectroscopy for monitoring water levels in parts per million in a manufacturing-scale distillation process.

An on-line analytical method based on transmission near-infrared spectroscopy (NIRS) for the quantitative determination of water concentrations (in parts per million) was developed and applied to the manufacture of a pharmaceutical intermediate. Calibration models for water analysis, built at the development site and applied at the manufacturing site, were successfully demonstrated during six manufacturing runs at a 250-gallon scale. The water measurements will be used as a forward-processing control point following distillation of a toluene product solution prior to use in a Grignard reaction. The most significant impact of using this NIRS-based process analytical technology (PAT) to replace off-line measurements is the significant reduction in the risk of operator exposure through the elimination of sampling of a severely lachrymatory and mutagenic compound. The work described in this report illustrates the development effort from proof-of-concept phase to manufacturing implementation.