利用金属-酚醛网络保护厌氧微生物免受加工胁迫。

Protection of Anaerobic Microbes from Processing Stressors Using Metal-Phenolic Networks.

机构信息

Department of Chemical Engineering, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, United States.

Department of Chemical Engineering, University of Puerto Rico, Mayagüez 00681, Puerto Rico.

出版信息

J Am Chem Soc. 2022 Feb 16;144(6):2438-2443. doi: 10.1021/jacs.1c09018. Epub 2021 Dec 9.

DOI:10.1021/jacs.1c09018

PMID:34886663

Abstract

The gut microbiome is essential to maintain overall health and prevent disease, which can occur when these microbes are not in homeostasis. Microbial biotherapeutics are important to combat these issues, but they must be alive at the time of delivery for efficacy. Many potentially therapeutic species are anaerobes and thus are difficult to manufacture because of the limited efficacy of existing protective methods, making their production nearly impossible. We have developed a self-assembling cellular coating to improve the viability and stability of the next-generation biotherapeutic . We show protection from both harsh processing conditions and oxygen exposure, even in the absence of canonical cryoprotectants. This advance will increase the range of microbes that can be stably manufactured and facilitate the development of emerging strains of interest by ensuring their postproduction viability.

摘要

肠道微生物组对于维持整体健康和预防疾病至关重要，而当这些微生物失去平衡时，就会发生疾病。微生物生物治疗剂对于应对这些问题非常重要，但为了发挥疗效，它们必须在交付时保持存活状态。许多潜在的治疗性微生物是厌氧菌，因此由于现有保护方法的效果有限，它们很难制造，这使得它们的生产几乎不可能。我们已经开发出一种自组装细胞涂层，以提高下一代生物治疗剂的存活率和稳定性。我们展示了对恶劣加工条件和氧气暴露的保护作用，即使在没有典型冷冻保护剂的情况下也是如此。这一进展将增加可稳定制造的微生物种类，并通过确保其生产后的存活能力，促进新兴相关菌株的开发。

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利用金属-酚醛网络保护厌氧微生物免受加工胁迫。

Protection of Anaerobic Microbes from Processing Stressors Using Metal-Phenolic Networks.

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