Modeling the inactivation of Aspergillus niger spores in a model parenteral emulsion by high hydrostatic pressure and its effect on the emulsion droplet size

IF 1.2 4区 物理与天体物理 Q3 PHYSICS, MULTIDISCIPLINARY
Maricarmen Íñiguez-Moreno, G. Ascanio, M. Calderón‐Santoyo, E. Brito-Bazán, E. Brito-de la Fuente, J. A. Ragazzo‐Sánchez
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引用次数: 0

Abstract

ABSTRACT A predictive model based on the Box–Behnken design was developed to determine the effect of high hydrostatic pressure (HHP), temperature, and cycles (each holding time of 10 min) on the inactivation of Aspergillus niger spores and in the droplet size of a model emulsion. The obtained model presented goodness of fit to the data with a high correlation coefficient (R2  = 0.91) and adjusted correlation coefficient value ( 0.88), with no significant lack-of-fit test (p = 0.6031). The canonical analysis provides the conditions (37.29 °C, 263.33 MPa, and, 1.88 cycles) to reduce 5.0 Log10 CFU/mL of A. nigger. Under such conditions, emulsions exhibited a monomodal distribution of droplet size. However, as temperature and pressure increased, both the PDI, D3,2, and D4,3 values increased (p ≤ 0.05). In conclusion, the proposed model has the potential to predict the reduction of A. niger spores by HHP without causing emulsion destabilization.
高静水压对黑曲霉孢子在模拟肠外乳液中失活的建模及其对乳液液滴大小的影响
建立了基于Box-Behnken设计的预测模型,以确定高静水压力(HHP)、温度和循环(每次保存时间为10 min)对黑曲霉孢子灭活和模型乳剂液滴大小的影响。所得模型与相关系数较高的数据(R2 = 0.91)和调整后的相关系数值(0.88)的拟合优度均较好,无显著的拟合缺失检验(p = 0.6031)。典型分析表明,在37.29°C, 263.33 MPa, 1.88个循环的条件下,黑孢杆菌的浓度可降低5.0 Log10 CFU/mL。在此条件下,乳状液的液滴尺寸呈现单峰分布。但随着温度和压力的升高,PDI、D3、2、D4、3值均升高(p≤0.05)。综上所述,所提出的模型有可能在不引起乳剂不稳定的情况下预测HHP对黑曲霉孢子的减少。
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来源期刊
High Pressure Research
High Pressure Research 物理-物理:综合
CiteScore
3.80
自引率
5.00%
发文量
15
审稿时长
2 months
期刊介绍: High Pressure Research is the leading journal for research in high pressure science and technology. The journal publishes original full-length papers and short research reports of new developments, as well as timely review articles. It provides an important forum for the presentation of experimental and theoretical advances in high pressure science in subjects such as: condensed matter physics and chemistry geophysics and planetary physics synthesis of new materials chemical kinetics under high pressure industrial applications shockwaves in condensed matter instrumentation and techniques the application of pressure to food / biomaterials Theoretical papers of exceptionally high quality are also accepted.
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