Tang Xiaolin Charlie, Pikal Michael J
School of Pharmacy, U-2092, University of Connecticut, 372 Fairfield Road, Storrs, Connecticut 06269-2092, USA.
Pharm Res. 2005 Jul;22(7):1176-85. doi: 10.1007/s11095-005-6036-3. Epub 2005 Jul 22.
The aim of the study is to determine the degree of coupling between protein unfolding rate and system viscosity at low temperatures in systems relevant to freeze-drying.
The cold denaturation of both phosphoglycerate kinase (PGK) and beta-lactoglobulin were chosen as models for the protein unfolding kinetics study. The system viscosity was enhanced by adding stabilizers (such as sucrose), and denaturant (guanidine hydrochloride or urea) was added to balance the stabilizing effect of sucrose to maintain the cold denaturation temperature roughly constant. The protein unfolding kinetics were studied by both temperature-controlled tryptophan emission fluorescence spectroscopy and isothermal high-sensitivity modulated differential scanning calorimetry (MDSC) (Tzero). Viscometers were used to determine the system viscosity. To verify the predictions of structure based on protein unfolding dynamics, protein formulations were freeze-dried above the glass transition temperatures, and the protein structures in dry products were determined by fluorescence spectroscopy of reconstituted solids by extrapolation of the solution data to the time of reconstitution.
Empirical equations describing the effect of sucrose and denaturant (urea and guanidine hydrochloride) on protein cold denaturation were developed based on DSC observations [X. C. Tang and M. J. Pikal. The Effects of Stabilizers and Denaturants on the Cold Denaturation Temperature of Proteins and Implications for Freeze-Drying. Pharm. Res. Submitted (2004)]. It was found that protein cold denaturation temperature can be maintained constant in system of increasing sucrose concentration by simultaneous addition of denaturants (urea and guanidine hydrochloride) using the empirical equations as a guide. System viscosities were found to increase dramatically with increasing sucrose concentration and decreasing temperature. The rate constants of protein unfolding (or the half-life of unfolding) below the cold denaturation temperature were determined by fitting the time dependence of either fluorescence spectroscopy peak position shift or DSC heat capacity increase to a first-order reversible kinetic model. The half-life of unfolding did slow considerably as system viscosity increased. The half-life of PGK unfolding, which was only 3.5 min in dilute buffer solution at -10 degrees C, was found to be about 200 min in 37% sucrose at the same temperature. Kinetics of protein unfolding are identical as measured by tryptophan fluorescence emission spectroscopy and by high-sensitivity modulated DSC. The coupling between protein unfolding kinetics and system viscosity for both proteins was significant with a stronger coupling with PGK than with beta-lactoglobulin. The half-lives of PGK and beta-lactoglobulin unfolding are estimated to be 5.5 x 10(11) and 2.2 years, respectively, even when they are freeze-dried in sucrose formulations 20 degrees C above Tg'. Thus, freeze-drying below Tg' should not be necessary to preserve the native conformation. In support of this conclusion, native PGK was obtained after the freeze-drying of PGK at a temperature more than 60 degrees C above the system Tg' in a thermodynamically unstable system during freeze-drying.
Protein unfolding kinetics is highly coupled with system viscosity in high viscosity systems, and the coupling coefficients are protein dependent. Protein unfolding is very slow on the time scale of freeze-drying, even when the system is freeze-dried well above Tg'. Thus, it is not always necessary to freeze-dry protein formulations at temperature below Tg' to avoid protein unfolding. That is, protein formulations could be freeze-dried at product temperature far above the Tg', thereby allowing much shorter freeze-drying cycle times, with dry cake structure being maintained by the simultaneous use of a bulking agent and a disaccharide stabilizer.
本研究的目的是确定在与冷冻干燥相关的体系中,低温下蛋白质展开速率与体系粘度之间的耦合程度。
选择磷酸甘油酸激酶(PGK)和β-乳球蛋白的冷变性作为蛋白质展开动力学研究的模型。通过添加稳定剂(如蔗糖)提高体系粘度,并添加变性剂(盐酸胍或尿素)以平衡蔗糖的稳定作用,从而使冷变性温度大致保持恒定。采用温控色氨酸发射荧光光谱法和等温高灵敏度调制差示扫描量热法(MDSC)(Tzero)研究蛋白质展开动力学。使用粘度计测定体系粘度。为了验证基于蛋白质展开动力学的结构预测,在玻璃化转变温度以上对蛋白质制剂进行冷冻干燥,并通过将溶液数据外推至重构时间,利用重构固体的荧光光谱法测定干燥产品中的蛋白质结构。
基于差示扫描量热法(DSC)的观察结果,建立了描述蔗糖和变性剂(尿素和盐酸胍)对蛋白质冷变性影响的经验方程[X. C. Tang和M. J. Pikal。稳定剂和变性剂对蛋白质冷变性温度的影响及其对冷冻干燥的意义。《药物研究》(已提交,2004年)]。结果发现,以经验方程为指导,通过同时添加变性剂(尿素和盐酸胍),在蔗糖浓度不断增加的体系中可使蛋白质冷变性温度保持恒定。发现体系粘度随蔗糖浓度的增加和温度的降低而急剧增加。通过将荧光光谱峰位移动或DSC热容量增加的时间依赖性拟合为一级可逆动力学模型,确定了低于冷变性温度时蛋白质展开的速率常数(或展开半衰期)。随着体系粘度的增加,展开半衰期确实显著减慢。PGK展开的半衰期在-10℃的稀缓冲溶液中仅为3.5分钟,而在相同温度下37%蔗糖溶液中约为200分钟。通过色氨酸荧光发射光谱法和高灵敏度调制DSC测定的蛋白质展开动力学相同。两种蛋白质的蛋白质展开动力学与体系粘度之间的耦合显著,PGK的耦合比β-乳球蛋白更强。即使在比玻璃化转变温度(Tg')高20℃的蔗糖制剂中对PGK和β-乳球蛋白进行冷冻干燥,其展开半衰期估计分别为5.5×10^11年和2.2年。因此,在Tg'以下进行冷冻干燥对于保持天然构象并非必要。支持这一结论的是,在冷冻干燥过程中处于热力学不稳定体系的情况下,在高于体系Tg'超过60℃的温度下对PGK进行冷冻干燥后获得了天然PGK。
在高粘度体系中,蛋白质展开动力学与体系粘度高度耦合,且耦合系数取决于蛋白质。即使体系在远高于Tg'的温度下进行冷冻干燥,在冷冻干燥的时间尺度上蛋白质展开也非常缓慢。因此,并非总是需要在低于Tg'的温度下对蛋白质制剂进行冷冻干燥以避免蛋白质展开。也就是说,蛋白质制剂可以在远高于Tg'的产品温度下进行冷冻干燥,从而允许更短的冷冻干燥周期时间,同时使用填充剂和二糖稳定剂来维持干饼结构。
