The effect of avian eggshell membrane structure on microbial penetration: A simulation study

IF 2 4区 生物学 Q2 BIOLOGY
Seungwoo Sim , Cheol-Min Park , Sang-Hee Lee , Haeun Cho , Youngheum Ji , Heeso Noh , Sang-im Lee
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引用次数: 0

Abstract

Avian eggshells exhibit excellent antimicrobial properties. In this study, we conducted simulation experiments to explore the defense mechanisms of eggshell membranes with regards to their physical features. We developed a mathematical model for the movement of microorganisms and estimated their penetration ratio into eggshell membranes based on several factors, including membrane thickness, microbial size, directional drift, and attachment probability to membrane fibers. These results not only suggest that an eggshell membrane with multiple layers and low porosity indicates high antimicrobial performance, but also imply that the fibrous network structure of the membrane might contribute to effective defense. Our simulation results aligned with experimental findings, specifically in measuring the penetration time of Escherichia coli through the eggshell membrane. We briefly discuss the significance and limitations of this pilot study, as well as the potential for these results, to serve as a foundation for the development of antimicrobial materials.

禽蛋壳膜结构对微生物渗透的影响:模拟研究
禽类蛋壳具有出色的抗菌特性。在本研究中,我们进行了模拟实验,以探索蛋壳膜的物理特性对其防御机制的影响。我们建立了一个微生物运动的数学模型,并根据膜厚度、微生物大小、定向漂移和附着在膜纤维上的概率等几个因素估算了微生物对蛋壳膜的渗透率。这些结果不仅表明,多层、低孔隙率的蛋壳膜具有很高的抗菌性能,而且还意味着膜的纤维网络结构可能有助于有效防御。我们的模拟结果与实验结果一致,特别是在测量大肠杆菌穿透蛋壳膜的时间方面。我们简要讨论了这项试验研究的意义和局限性,以及这些结果作为抗菌材料开发基础的潜力。
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
Biosystems
Biosystems 生物-生物学
CiteScore
3.70
自引率
18.80%
发文量
129
审稿时长
34 days
期刊介绍: BioSystems encourages experimental, computational, and theoretical articles that link biology, evolutionary thinking, and the information processing sciences. The link areas form a circle that encompasses the fundamental nature of biological information processing, computational modeling of complex biological systems, evolutionary models of computation, the application of biological principles to the design of novel computing systems, and the use of biomolecular materials to synthesize artificial systems that capture essential principles of natural biological information processing.
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