Conor G Harris, Lewis Semprini, Willie E Rochefort, Kaitlin C Fogg
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引用次数: 0
摘要
在这篇微型综述教程中,我们将探讨实验设计 (DOE) 作为一种强大的统计工具在生物技术中的应用。具体来说,我们将回顾水凝胶材料在与绿色微生物学(利用微生物促进可持续发展)相关的各种微生物应用中的优化。水凝胶是一种具有高保水能力的三维聚合物网络,在固定微生物方面起着关键作用,并为指导微生物命运提供了一个必不可少的可定制环境。我们的研究重点是应用 DOE 为一系列真菌和细菌精确定制水凝胶成分,这些真菌和细菌可用于可持续生产化合物或消除有害物质。我们研究了各种 DOE 设计策略,如中心复合设计、方框-贝肯设计和优化设计,并讨论了它们在各种水凝胶配方中的战略实施。我们的分析探讨了 DOE 在提炼由各种聚合物(包括天然聚合物和合成聚合物)制成的水凝胶过程中不可或缺的作用。我们说明了 DOE 如何促进对水凝胶特性的细微控制,而这种控制是采用标准的一次一个因素的方法无法实现的。此外,本综述还揭示了不同材料和应用中的一个共同发现:水凝胶参数与细胞行为之间存在显著的相互作用。这凸显了细胞-水凝胶相互作用的复杂性以及对水凝胶材料特性和细胞功能的影响。最后,本综述不仅强调了 DOE 在简化优化细胞-水凝胶过程方面的功效,还将其定位为促进我们对细胞-水凝胶动力学理解的重要工具,有可能为生物技术应用和生物工程解决方案带来创新性进步。
Statistical optimization of cell-hydrogel interactions for green microbiology - a tutorial review.
In this tutorial mini-review, we explore the application of Design of Experiments (DOE) as a powerful statistical tool in biotechnology. Specifically, we review the optimization of hydrogel materials for diverse microbial applications related to green microbiology, the use of microbes to promote sustainability. Hydrogels, three-dimensional polymers networks with high water retention capabilities, are pivotal in the immobilization of microorganisms and provide a customizable environment essential for directing microbial fate. We focus on the application of DOE to precisely tailor hydrogel compositions for a range of fungi and bacteria either used for the sustainable production of chemical compounds, or the elimination of hazardous substances. We examine a variety of DOE design strategies such as central composite designs, Box-Behnken designs, and optimal designs, and discuss their strategic implementation across diverse hydrogel formulations. Our analysis explores the integral role of DOE in refining hydrogels derived from a spectrum of polymers, including natural and synthetic polymers. We illustrate how DOE facilitates nuanced control over hydrogel properties that cannot be achieved using a standard one factor at a time approach. Furthermore, this review reveals a conserved finding across different materials and applications: there are significant interactions between hydrogel parameters and cell behavior. This highlights the intricacies of cell-hydrogel interactions and the impact on hydrogel material properties and cellular functions. Lastly, this review not only highlights DOE's efficacy in streamlining the optimization of cell-hydrogel processes but also positions it as a critical tool in advancing our understanding of cell-hydrogel dynamics, potentially leading to innovative advancements in biotechnological applications and bioengineering solutions.