Yamada T, Imai T, Ouchi K, Otagiri M, Hirayama F, Uekama K
Pharmaceutical Laboratories, Kissei Pharmaceutical Co., Ltd., Minamiazumi, Nagano, Japan.
Chem Pharm Bull (Tokyo). 2000 Sep;48(9):1264-9. doi: 10.1248/cpb.48.1264.
Interactions of KCA-098 with heptakis(2,6-di-O-methyl)-beta-cyclodextrin (DM-beta-CyD) in solution and in the solid state were studied by the solubility method, UV and fluorescence spectroscopy, powder X-ray diffractometry, and thermal analysis. The KCA-098/DM-beta-CyD system showed an A(L) type solubility diagram with stability constants of 5870 and 2220 M(-1) in aqueous and 10% methanol solutions, respectively. Following the addition of DM-beta-CyD, the maximum UV wavelength of KCA-098 was shifted to a longer wavelength and the fluorescence intensity was decreased. A similar spectral change was observed when KCA-098 was dissolved in less polar solvents, especially in proton-acceptor solvents, such as acetone and dimethylsulfoxide, suggesting that KCA-098 interacts with DM-beta-CyD through not only a hydrophobic interaction but also hydrogen bonding. The solid complex of KCA-098 with DM-beta-CyD in a molar ratio of 1:1 was prepared by the kneading method and the solvent evaporation method, using organic solvents. Powder X-ray diffractometric and differential scanning calorimetric studies indicated that KCA-098 was dispersed as microparticles on the DM-beta-CyD complex in the solid state prepared by the solvent evaporation method although it dispersed as crystals in the sample prepared by the kneading method. The dissolution of KCA-098 from the solid complex prepared by the former method was markedly faster than that prepared by the latter method, although it slowed down with the passage of time. The reduced dissolution of KCA-098 was explained by crystallization to the hydrate form in the medium. These data indicate that poorly water-soluble KCA-098 interacts with DM-beta-CyD in water and in the solid state and that a fast-dissolving form of KCA-098 can be obtained by evaporating with DM-beta-CyD using organic solvents.
采用溶解度法、紫外和荧光光谱法、粉末X射线衍射法以及热分析方法,研究了KCA - 098与七(2,6 - 二 - O - 甲基)-β-环糊精(DM -β- CyD)在溶液和固态中的相互作用。KCA - 098/DM -β- CyD体系呈现A(L)型溶解度图,在水溶液和10%甲醇溶液中的稳定常数分别为5870和2220 M(-1)。加入DM -β- CyD后,KCA - 098的最大紫外波长向长波长方向移动,且荧光强度降低。当KCA - 098溶解于极性较小的溶剂中,尤其是在质子受体溶剂(如丙酮和二甲基亚砜)中时,也观察到了类似的光谱变化,这表明KCA - 098与DM -β- CyD不仅通过疏水相互作用,还通过氢键相互作用。采用捏合法和溶剂蒸发法,使用有机溶剂制备了摩尔比为1:1的KCA - 098与DM -β- CyD的固体复合物。粉末X射线衍射和差示扫描量热研究表明,通过溶剂蒸发法制备的固态样品中,KCA - 098以微粒形式分散在DM -β- CyD复合物上;而在通过捏合法制备的样品中,KCA - 098以晶体形式分散。尽管随着时间推移溶解速度会减慢,但通过前一种方法制备的固体复合物中KCA - 098的溶解速度明显快于后一种方法制备的。KCA - 098溶解速度降低的原因是在介质中结晶为水合物形式。这些数据表明,难溶于水的KCA - 098在水中和固态下均与DM -β- CyD相互作用,并且通过使用有机溶剂与DM -β- CyD一起蒸发可以获得KCA - 098的速溶形式。
