Predictive model for the surface melting and puffing of freeze-dried amorphous materials

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Sukritta Anantawittayanon, Kiyoshi Kawai
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引用次数: 0

Abstract

It is thought that surface melting and puffing of freeze-dried amorphous materials are related to the difference between the surface temperature (Tsur) and freeze-concentrated glass transition temperature (Tg’) of the materials. Although Tg’ is a material-specific parameter, Tsur is affected by the type and amount of solute and freeze-drying conditions. Therefore, it will be practically useful for preventing surface melting and puffing if Tsur can be calculated using only the minimum necessary parameters. This study aimed to establish a predictive model for the surface melting and puffing of freeze-dried amorphous materials according to the calculated Tsur. First, a Tsur-predictive model was proposed under the thermodynamic equilibrium assumptions. Second, solutions with various solute mass fractions of sucrose, maltodextrin, and sucrose-maltodextrin mixture were prepared, and three material-specific parameters (Tg’, unfrozen water content, and true density) were experimentally determined. According to the proposed model with the parameters, the Tsur of the samples was calculated at chamber pressures of 13, 38, and 103 Pa. The samples were freeze-dried at the chamber pressures, and their appearance was observed. As expected, surface melting and puffing occurred at calculated Tsur > Tg’ with some exceptions. The water activity (aw) of the freeze-dried samples increased as the Tsur − Tg’ increased. This will have resulted from surface melting and puffing, which created a covering film, thereby preventing subsequent dehydration. The observations suggest that the proposed model is also useful for predetermining the drying efficiency and storage stability of freeze-dried amorphous materials.

冻干无定形材料表面熔化和膨化的预测模型。
一般认为,冻干无定形材料的表面熔化和膨化与材料的表面温度(Tsur)和冻干玻璃化转变温度(Tg')之间的差异有关。虽然 Tg'是特定材料的参数,但 Tsur 会受到溶质类型和数量以及冻干条件的影响。因此,如果只需使用最少的必要参数就能计算出 Tsur,那么对于防止表面熔化和膨化将非常有用。本研究旨在根据计算出的 Tsur 建立冻干无定形材料表面熔化和膨化的预测模型。首先,在热力学平衡假设下提出了一个 Tsur 预测模型。其次,制备了不同溶质质量分数的蔗糖、麦芽糊精和蔗糖-麦芽糊精混合物溶液,并通过实验确定了三种材料的特定参数(Tg'、解冻水含量和真实密度)。根据所提出的参数模型,计算了样品在 13、38 和 103 Pa 的腔室压力下的 Tsur。不出所料,在计算出的 Tsur >Tg' 时,表面会出现熔化和膨化现象,但也有例外。冻干样品的水活度(aw)随着 Tsur -Tg' 的增加而增加。这可能是由于表面熔化和膨化产生了一层覆盖膜,从而阻止了后续脱水。这些观察结果表明,所提出的模型对于预先确定冻干无定形材料的干燥效率和储存稳定性也很有用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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