无定形固体
溶解
材料科学
化学工程
混溶性
同步加速器
结晶度
相(物质)
药品
聚合物
纳米技术
化学
有机化学
光学
药理学
复合材料
医学
工程类
物理
作者
Chenyang Shi,Luxi Li,Geoff G. Z. Zhang,Thomas B. Borchardt
标识
DOI:10.1021/acs.molpharmaceut.9b00651
摘要
Amorphous solid dispersions (ASDs) are new formulations currently being used in pharmaceutical industry. The ASDs, in which amorphous drug and polymeric excipients are intimately mixed at the molecular level, exhibit dramatically enhanced solubility and dissolution characteristics relative to their crystalline drug counterparts. In the process of achieving an ever-increasing drug loading (DL), it is noticed, however, that the drug release profile deteriorates significantly beyond a certain DL. As an example, a ritonavir-copovidone ASD achieves continuous and full drug release when DL ≤ 25 wt %. The release drops at 30 wt % and when DL ≥ 35 wt % there is virtually no drug release, behaving like a pure amorphous drug. In this Communication, the phase miscibility of ASD thin films has been investigated by in situ synchrotron X-ray fluorescence (XRF) imaging to elucidate the mechanism for the unique change in the extent of drug release as a function of DL. It is found that the drug release profile correlates well with the amorphous-amorphous phase separation (AAPS) onset. At a lower drug loading (up to 20 wt %), it takes more than 12 h for AAPS to happen while in sharp contrast, it only needs less than 10 min for DL ≥ 32.5 wt %. During AAPS, amorphous drug accumulates on the surface of the film, which prevents further dissolution from the interior of the ASD. The current study provides a mechanistic understanding of the confounding drug release profile of ASDs as a function of DL and opens the door for studying drug-excipient (e.g., polymer, surfactant) interactions via XRF imaging in the future.
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