Johari G P, Kim S, Shanker Ravi M
Department of Materials Science and Engineering, McMaster University, Hamilton, Ontario, Canada L8S 4L7.
J Pharm Sci. 2007 May;96(5):1159-75. doi: 10.1002/jps.20921.
Molecular relaxation in ultraviscous melt and glassy states of aspirin, ibuprofen, progesterone, and quinidine has been studied by dielectric spectroscopy. The asymmetric relaxation spectra is characterized by the Kohlrausch distribution parameter of 0.46 +/- 0.02 for aspirin to 0.67 +/- 0.02 for progesterone. The dielectric relaxation time varies with the temperature, T, according to the Vogel-Fulcher-Tammann Equation, log(10)(tau(0)) = A(VFT) + [B(VFT)/(T - T(0))], where A(VFT), B(VFT), and T(0) are empirical constants. The extrapolated tau(0) at calorimetric glass-softening temperature is close to the value expected. The equilibrium permittivity, epsilon(0), is lowest for ibuprofen which indicates an antiparallel orientation of dipoles in its liquid's hydrogen-bonded structure. A decrease in epsilon(0) with time shows that ultraviscous aspirin, progesterone, and quinidine begin to cold-crystallize at a relatively lower temperature than ibuprofen. epsilon(0) of the cold-crystallized phases are, 4.7 for aspirin at 290 K, 2.55 for ibuprofen at 287 K, 2.6 for progesterone at 320 K, and 3.2 for quinidine at 375 K. It is argued that hydrogen-bonding, the Kohlrausch parameter, extent of localized motions and the long-range diffusion times all determine the physical and chemical stability of an amorphous pharmaceutical during storage.
通过介电谱研究了阿司匹林、布洛芬、孕酮和奎尼丁在超粘性熔体和玻璃态下的分子弛豫。不对称弛豫谱的特征在于,阿司匹林的科尔劳施分布参数为0.46±0.02,孕酮为0.67±0.02。介电弛豫时间根据Vogel-Fulcher-Tammann方程随温度T变化,log(10)(τ(0)) = A(VFT) + [B(VFT)/(T - T(0))],其中A(VFT)、B(VFT)和T(0)是经验常数。在量热玻璃软化温度下外推得到的τ(0)接近预期值。布洛芬的平衡电容率ε(0)最低,这表明其液体氢键结构中偶极子呈反平行取向。ε(0)随时间的降低表明,超粘性的阿司匹林、孕酮和奎尼丁在比布洛芬相对更低的温度下开始冷结晶。冷结晶相的ε(0)分别为:290K时阿司匹林为4.7,287K时布洛芬为2.55,320K时孕酮为2.6,375K时奎尼丁为3.2。有人认为,氢键、科尔劳施参数、局部运动程度和长程扩散时间都决定了无定形药物在储存期间的物理和化学稳定性。
