Engineering of complex adaptive microbial ecosystems

复杂适应性微生物生态系统工程

• 批准号: 339814-2009
• 负责人: Clark, Grant
• 金额: $ 1.38万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2013
• 资助国家: 加拿大
• 起止时间: 2013-01-01 至 2014-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=527191
• 关键词: Engineering; complex; adaptive; microbial; ecosystems

An ecosystem is a community of organisms that interact with each other and with their surroundings. Given an adequate understanding of these interactive processes, ecosystems can be created and managed to provide specific services. Some microbial ecosystems, for instance, provide useful services such as composting, and agricultural ecosystems are managed to provide food. Ecosystems that are engineered to incorporate natural processes are more sustainable because they are driven more by renewable inputs such as sunlight, and therefore depend less on nonrenewable inputs such as fossil fuels. The dynamics of natural ecosystems are extremely complex, however, and so the application of ecological theory to engineer ecosystems for specific purposes is still rudimentary. In this research, microbial ecosystems will be constructed in the form of pilot-scale compost vessels. The vessels will be instrumented to allow automated measurement of process parameters such as temperature, airflow, relative humidity, and the composition of inlet and exhaust gases. A computer interface will allow this information to be used in the development of advanced numerical models of the interrelated physical, chemical, and microbial aspects of the composting process. Finally, a feedback control system will use these models to control the process parameters and optimize the system for specific goals, such as reduced noxious or greenhouse gas emissions or increased processing rate. The ultimate objective in this research program is to use these pilot-scale systems to test ecological hypotheses, and to learn how to better apply ecological theory in the engineering of systems that include living organisms. The students that work on this research will become highly skilled in the real-time characterization, modeling, and control of microbial ecosystems. The knowledge that they gain will also be applicable to the understanding and engineering of other kinds of ecological systems, improving the sustainability of ecosystems of all scales that provide critical services to society, such as the production of food, fibre, and energy, and the cleansing of water and air.

生态系统是一个相互作用并与周围环境相互作用的生物群落。如果对这些相互作用的过程有充分的了解，就可以建立和管理生态系统，以提供具体的服务。例如，一些微生物生态系统提供有用的服务，如堆肥，农业生态系统被管理以提供食物。被设计成纳入自然过程的生态系统更可持续，因为它们更多地由阳光等可再生投入驱动，因此较少依赖化石燃料等不可再生投入。然而，自然生态系统的动力学是极其复杂的，因此将生态学理论应用于为特定目的而设计的生态系统仍然是初步的。在本研究中，微生物生态系统将以中试规模堆肥容器的形式构建。将对容器进行仪表化，以允许自动测量工艺参数，如温度、气流、相对湿度以及进气和排气的组成。一个计算机接口将允许这些信息被用于开发先进的数值模型的相互关联的物理，化学和微生物方面的堆肥过程。最后，反馈控制系统将使用这些模型来控制工艺参数，并针对特定目标优化系统，例如减少有毒气体或温室气体排放或增加处理速率。本研究计划的最终目标是使用这些中试规模的系统来测试生态假设，并学习如何更好地将生态理论应用于包括生物体的系统工程。从事这项研究的学生将在微生物生态系统的实时表征，建模和控制方面具有很高的技能。他们获得的知识也将适用于其他类型的生态系统的理解和工程，提高所有规模的生态系统的可持续性，为社会提供关键服务，如食品，纤维和能源的生产，以及水和空气的净化。