ABSTRACT
Many compound collections are stored under the same temperature conditions, which can limit flexibility by increasing the processing time required for high-demand compounds. In this study, the authors wanted to evaluate the impact of a hybrid-storage approach where high-demand compounds are stored for a shortened time period at room temperature to expedite processing operations. The use of a Covaris adaptive-focused acoustics platform was also characterized as a potential enhancement or alternative to storage at elevated temperatures. This study evaluated the impact of temperature, exposure, and solubilization on overall compound quality for short-term storage. A small library of 25 representative compounds was evaluated over an 18-week period to monitor the change in purity and concentration by high-performance liquid chromatography with ultraviolet detection. The authors concluded that temperature had a significant impact on compound concentration, and the effects due to exposure cycles were minimal. A storage time of 12 weeks at room temperature resulted in minimal compound loss, but storage times beyond this would be unacceptable because of a >20% decrease in concentration. Finally, the acoustic solubilization protocol also increased the number of compounds at the target concentration with no impact on overall purity, leading to a potential for increased storage times at frozen temperatures.