用于部件特征描述和重构的 DBTL 生物工程周期

Q3 Engineering

IFAC-PapersOnLine Pub Date : 2024-01-01 DOI:10.1016/j.ifacol.2024.10.002

A. Arboleda-Garcia , M. Stiebritz , Y. Boada , J. Picó , A. Vignoni

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引用次数: 0

摘要

设计-构建-测试-学习（DBTL）循环是合成生物学中开发和优化生物系统的重要框架。然而，该周期的人工性质在时间和人力方面造成了限制。本文重点介绍自动化技术在 DBTL 循环中的应用，特别是在标准生物部件的测试和表征中的应用，标准生物部件是基因电路的重要组成部分。通过测试过程自动化，可以显著提高吞吐量、可靠性和可重复性。本文讨论了与人工测试方法相关的挑战，并探讨了可应对这些挑战的各种自动化策略和技术。高通量筛选方法、实验室机器人技术和数据分析算法是自动化流程的关键要素。作为一个案例研究，我们利用自动化 DBTL 循环重构一个生物传感器，旨在提高其性能。将自动化整合到 DBTL 循环中具有诸多优势，包括提高生物部件的效率、标准化和质量控制。它还能探索更大的设计空间，并快速制作复杂基因系统的原型。在这里，我们展示了使用 DBTL 循环重构生物传感器的优势，该传感器的性能得到了提高，并可随时用于更复杂的电路中。

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DBTL bioengineering cycle for part characterization and refactoring

The Design-Build-Test-Learn (DBTL) cycle is a crucial framework in Synthetic Biology for the development and optimization of biological systems. However, the manual nature of the cycle poses limitations in terms of time and labor. This paper focuses on the application of automation techniques to the DBTL cycle, specifically in the testing and characterization of standard bioparts, which are essential components of genetic circuits. By automating the testing process, throughput, reliability, and reproducibility can be significantly improved. This paper discusses the challenges associated with manual testing methods and explores various automation strategies and technologies that can address these challenges. High-throughput screening methods, laboratory robotics, and data analysis algorithms are key elements in the automation process. As a case study, we utilize the automated DBTL cycle to refactor a biosensor, aiming to enhance its performance. Integrating automation in the DBTL cycle offers numerous advantages, including increased efficiency, standardization, and quality control of bioparts. It also enables the exploration of larger design spaces and rapid prototyping of complex genetic systems. Here, we show the advantages of using the DBTL cycle to refactor a biosensor that presents improved performance and can be readily used in more complex circuits.

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来源期刊

IFAC-PapersOnLine Engineering-Control and Systems Engineering

CiteScore

1.70

自引率

0.00%

发文量

1122

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