Immediate-release Mechanism of Dehydrotrametenolic Acid and Dehydroeburicoic Acid in Poriae Cutis Total Triterpenoids Tablets Based on Liquid-solid Compact Technique

[Objectives]To study the immediate-release mechanism of dehydrotrametenolic acid and dehydroeburicoic acid in Poriae Cutis total triterpenoids tablets by liquid-solid compacts technique.[Methods] Taking dehydrotrametenolic acid and dehydroeburicoic acid as indicators,differences in dissolution were compared between liquid-solid compressed tablets and crude drug of total triterpenoids in Poriae Cutis;crude drug,powder of liquid-solid compressed tablets and excipients of liquid-solid compressed tablets were characterized by differential scanning calorimetry( DSC).[Results]Liquid-solid compact technique could significantly improve dissolution rate of dehydrotrametenolic acid and dehydroeburicoic acid. The total dissolution rate of dehydrotrametenolic acid and dehydroeburicoic acid in Poriae Cutis total triterpenoids tablets was 92%,t50( time for 50% total dissolution rate) and t_D( time for 63. 2% total dissolution rate) were 11. 18 min and 22. 71 min; the total dissolution rate of dehydrotrametenolic acid and dehydroeburicoic acid in crude drug of total triterpenoids was 29%,and t50 and t_D were231. 06 min and 359. 23 min. DSC showed that there was no mutual interaction between excipients and total triterpenoids in Poriae Cutis; on the DSC curve for powder of liquid-solid compressed tablets,the absorption peak vanished completely,indicating that the drug exists in the amorphous form in the liquid-solid powder.[Conclusions] Liquid-solid compact technique can increase the dissolution rate of total triterpenoids in Poriae Cutis and allow rapid release of poorly water soluble drugs.

Development of Transition Metal Nitrides as Oxygen and Hydrogen Electrocatalysts

With the increasing demand for energy, various emerging energy storage/conversion technologies have gradually penetrated human life, providing numerous conveniences. The practical application efficiency is often affected by the slow kinetics of hydrogen or oxygen electrocatalytic reactions(hydrogen evolution and oxidation reactions, oxygen evolution and reduction reactions) among the emerging devices. Therefore, the researchers devote to finding cost-effective electrocatalysts. Non-noble metal catalysts have low cost and good catalytic activity, but poor stability, agglomeration, dissolution, and other problems will occur after a long cycle, such as transition metal oxides and carbides. Transition metal nitrides(TMNs) stand out among all kinds of non-noble metal catalysts because of the intrinsic platinum-like electrocatalytic activities, relatively high conductivity, and wide range of tunability. In this review, the applications of TMNs in electrocatalytic fields are summarized based on the number of metals contained in TMNs. The practical application potentials of TMNs in fuel cell, water splitting, zinc-air battery and other electrochemical energy storage/conversion devices are also listed. Finally, the design strategies and viewpoints of TMNs-based electrocatalyst are summarized. The potential challenges of TMNs-based electrocatalyst in the development of electrocatalytic energy devices in the future are prospected.