The Impact of Annealing Methods on the Encapsulating Structure and Storage-Stability of Freeze-Dried Pellets of Probiotic Bacteria.

IF 3.5 3区医学 Q2 CHEMISTRY, MULTIDISCIPLINARY

Pharmaceutical Research Pub Date : 2024-08-01 Epub Date: 2024-07-29 DOI:10.1007/s11095-024-03751-w

Shuai Bai Palmkron, Björn Bergenståhl, Stephen Hall, Sebastian Håkansson, Marie Wahlgren, Emanuel Larsson, Anna Millqvist Fureby

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Abstract

Objective: This paper investigates the critical role of material thickness in freeze-dried pellets for enhancing the storage stability of encapsulated bacteria. Freeze dried material of varying thicknesses obtained from different annealing durations is quantified using Scanning Electron Microscopy (SEM) and X-ray microtomography (μCT), the material thickness is then correlated to the storage stability of the encapsulated cells.

Methods: A formulation comprising of sucrose, maltodextrin, and probiotic cells is quenched in liquid nitrogen to form pellets. The pellets undergo different durations of annealing before undergoing freeze-drying. The material thickness is quantified using SEM and μCT. Storage stability in both oxygen-rich and oxygen-poor environments is evaluated by measuring CFU counts and correlated with the pellet structure.

Results: The varying annealing protocols produce a range of material thicknesses, with more extensive annealing resulting in thicker materials. Storage stability exhibits a positive correlation with material thickness, indicating improved stability with thicker materials. Non-annealed pellets exhibit structural irregularities and inconsistent storage stability, highlighting the impracticality of avoiding annealing in the freeze-drying process.

Conclusions: Extensive annealing not only enhances the storage stability of probiotic products but also provides greater control over the freeze-drying process, ensuring homogeneous and reproducible products. This study underscores the importance of material thickness in freeze-dried pellets for optimizing storage stability for probiotic formulations, and emphasize the necessity of annealing as a critical step in freeze-drying quenched pellets to achieve desired structural and stability outcomes.

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退火方法对冻干益生菌颗粒的封装结构和储存稳定性的影响

目的：本文研究了冷冻干燥颗粒中材料厚度对提高封装细菌储存稳定性的关键作用。使用扫描电子显微镜（SEM）和 X 射线显微层析成像（μCT）对不同退火时间获得的不同厚度的冻干材料进行量化，然后将材料厚度与封装细胞的储存稳定性联系起来：方法：由蔗糖、麦芽糊精和益生菌细胞组成的配方在液氮中淬火形成颗粒。在进行冷冻干燥之前，颗粒要经过不同时间的退火处理。使用 SEM 和 μCT 对材料厚度进行量化。在富氧和缺氧环境中的储存稳定性通过测量 CFU 计数进行评估，并与颗粒结构相关联：结果：不同的退火方案会产生不同厚度的材料，退火范围越广，材料越厚。储存稳定性与材料厚度呈正相关，表明材料越厚稳定性越好。未经退火的颗粒结构不规则，储存稳定性也不稳定，这说明在冷冻干燥过程中避免退火是不切实际的：大面积退火不仅能提高益生菌产品的储存稳定性，还能更好地控制冻干过程，确保产品的均匀性和可重复性。这项研究强调了冷冻干燥颗粒中材料厚度对优化益生菌配方储存稳定性的重要性，并强调了退火作为冷冻干燥淬火颗粒的关键步骤对实现理想的结构和稳定性结果的必要性。

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

Pharmaceutical Research 医学-化学综合

CiteScore

6.60

自引率

5.40%

发文量

276

审稿时长

3.4 months

期刊介绍： Pharmaceutical Research, an official journal of the American Association of Pharmaceutical Scientists, is committed to publishing novel research that is mechanism-based, hypothesis-driven and addresses significant issues in drug discovery, development and regulation. Current areas of interest include, but are not limited to: -(pre)formulation engineering and processing- computational biopharmaceutics- drug delivery and targeting- molecular biopharmaceutics and drug disposition (including cellular and molecular pharmacology)- pharmacokinetics, pharmacodynamics and pharmacogenetics. Research may involve nonclinical and clinical studies, and utilize both in vitro and in vivo approaches. Studies on small drug molecules, pharmaceutical solid materials (including biomaterials, polymers and nanoparticles) biotechnology products (including genes, peptides, proteins and vaccines), and genetically engineered cells are welcome.