Microbiome science of human excrement composting

Jeff Meilander, J Gregory Caporaso
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Abstract

Linear waste management systems are unsustainable and contribute to environmental degradation, economic inequity, and health disparities. Among the array of environmental challenges stemming from anthropogenic impacts, the management of human excrement (human feces and urine) stands as a significant concern. Over two billion people do not have access to adequate sanitation, signifying a global public health crisis. Composting is the microbial biotechnology aimed at cycling organic waste, including human excrement, for improved public health, agricultural productivity and safety, and environmental sustainability. Applications of modern microbiome -omics and related technologies have the capacity to support continued advances in composting science and praxis. In this article, we review literature focused on applications of microbiome technologies to study composting systems and reactions. The studies we survey generally fall into the categories of animal manure composting, biosolids composting, and human excrement composting. We review experiments utilizing microbiome technologies to investigate strategies for enhancing pathogen suppression and accelerating the biodegradation of organic matter. Additionally, we explore studies focused on the bioengineering potential of microbes as inoculants to facilitate degradation of toxins such as pharmaceuticals or per- and polyfluoroalkyl substances. The findings from these studies underscore the importance of advancing our understanding of composting processes through the integration of emerging microbiome -omics technologies. We conclude that work to-date has demonstrated exciting basic and applied science potential from studying compost microbiomes, with promising implications for enhancing global environmental sustainability and public health.
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人类排泄物堆肥的微生物组科学
线性废物管理系统是不可持续的,会导致环境退化、经济不公平和健康差异。在人类活动造成的一系列环境挑战中,人类排泄物(人类粪便和尿液)的管理是一个令人严重关切的问题。超过 20 亿人无法获得适当的卫生设施,这意味着一场全球性的公共卫生危机。堆肥是一种微生物生物技术,旨在循环利用包括人类排泄物在内的有机废物,以改善公共卫生、提高农业生产率和安全性,并实现环境的可持续发展。现代微生物组学和相关技术的应用能够支持堆肥科学和实践的不断进步。在本文中,我们回顾了有关应用微生物组技术研究堆肥系统和反应的文献。我们调查的研究一般分为动物粪便堆肥、生物固体堆肥和人类排泄物堆肥三类。我们回顾了利用微生物组技术研究加强病原体抑制和加速有机物生物降解策略的实验。此外,我们还探讨了微生物作为接种物的生物工程潜力,以促进药物或全氟和多氟烷基物质等毒素的降解。这些研究结果强调了通过整合新兴微生物组-组学技术来促进我们对堆肥过程的理解的重要性。我们的结论是,迄今为止的工作表明,堆肥微生物组的研究具有令人兴奋的基础和应用科学潜力,对提高全球环境可持续性和公众健康具有重要意义。
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