标题：Effect of hydrophilic additives on the dissolution and pharmacokinetic properties of itraconazole-enteric polymer hot-melt extruded amorphous solid dispersions
作者：Lang, Bo; Liu, Sha; McGinity, James W.; Williams, Robert O., III
作者机构：[Lang, Bo; Liu, Sha; McGinity, James W.; Williams, Robert O., III] Univ Texas Austin, Div Pharmaceut, Coll Pharm, 2409 Univ Ave,Mail Stop A1920, Austi 更多
通讯作者地址：[Williams, RO]Univ Texas Austin, Div Pharmaceut, Coll Pharm, 2409 Univ Ave,Mail Stop A1920, Austin, TX 78712 USA.
来源：DRUG DEVELOPMENT AND INDUSTRIAL PHARMACY
关键词：Glass transition temperature; miscibility; supersaturation; TPGS; tablet
摘要：Hot-melt extrusion technology has been widely reported for producing amorphous solid dispersions of poorly water-soluble compounds. A number of studies revealed that enteric polymers containing ionizable groups are able to improve the physical stability and maintain drug supersaturation, thereby enhancing oral bioavailability. However, our previous studies found that itraconazole (ITZ)-enteric polymer amorphous solid dispersions are hydrophobic and poorly wettable. Moreover, drug release in an acidic environment (i.e. stomach) is very limited, indicating a narrow absorption window. In the present study, we investigated the effect of hydrophilic additives on the in vitro and in vivo performance of ITZ-enteric polymer amorphous solid dispersions. Incorporating Vitamin E TPGS into ITZ-HPMCAS amorphous solid dispersions significantly improved drug release in the acidic media. Surprisingly, a low concentration of Vitamin E TPGS also enhanced the degree of drug supersaturation in neutral pH media, which is unique as compared with other tested hydrophilic additives. This effect is not due to the solubilization of the surfactant. We further formulated the amorphous solid dispersions into tablet dosage forms and evaluated their performance in a bio-relevant dissolution media. Our optimized formulations exhibited drastically enhanced dissolution profiles as compared with the commercial ITZ product and ITZ amorphous solid dispersion without hydrophilic additive. In vivo study showed that Vitamin E TPGS induced rapid drug absorption after oral administration. Moreover, the elimination half-life of ITZ was prolonged due to the enzyme inhibition effect of Vitamin E TPGS.