Kiran Kuruvinashetti, Soroush Rahimi, Shanmugasundaram Pakkiriswami, Muthukumaran Packirisamy
{"title":"Simple, Economical Methods for the Culture of Green Algae for Energy Harvesting from Photosynthesis in a Microfluidic Environment.","authors":"Kiran Kuruvinashetti, Soroush Rahimi, Shanmugasundaram Pakkiriswami, Muthukumaran Packirisamy","doi":"10.1002/cpz1.322","DOIUrl":null,"url":null,"abstract":"<p><p>Ongoing technological advancements continually increase the demand for energy. Among various types of energy harvesting systems, biologically based systems have been an area of increasing interest for the past couple of decades. Such systems provide clean, safe power solutions, mainly for low- and ultra-low-power applications. The microphotosynthetic power cell (μPSC) is one such system that make use of photosynthetic living cells or organisms to generate power. For strong performance, μPSC technology, because of its interdisciplinary nature, requires optimal engineering of both electrochemical cell design and the culture conditions of the photosynthetic microorganisms. We present here a simple, economical culture method for the photosynthetic microorganism Chlamydomonas reinhardtii suitable for the application of this biologically based power system in any geographical location. This article provides a series of protocols for preparing materials and culture medium designed to facilitate the culture of a suitable C. reinhardtii strain even in a non-biological laboratory. Possible challenges and methods to overcome them are also discussed. Cultured C. reinhardtii perform sufficiently well that they have already been successfully utilized to generate power from a μPSC, generating a peak power of 200 μW from just 2 ml of exponential-phase algal culture in a μPSC with an active electrode surface area of 4.84 cm<sup>2</sup> . The μPSC thus has potentially broad applications in low- and ultra-low-power devices and sensors. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Algal growth conditions and algal growth chamber fabrication Basic Protocol 2: Preparation of Tris-acetate-phosphate (TAP) nutrient medium Basic Protocol 3: Preparation of suspension algal culture from algal strain Basic Protocol 4: Preparation of stock culture plates (algal strain) from suspension algal culture.</p>","PeriodicalId":11174,"journal":{"name":"Current Protocols","volume":" ","pages":"e322"},"PeriodicalIF":0.0000,"publicationDate":"2021-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Current Protocols","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1002/cpz1.322","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 1
Abstract
Ongoing technological advancements continually increase the demand for energy. Among various types of energy harvesting systems, biologically based systems have been an area of increasing interest for the past couple of decades. Such systems provide clean, safe power solutions, mainly for low- and ultra-low-power applications. The microphotosynthetic power cell (μPSC) is one such system that make use of photosynthetic living cells or organisms to generate power. For strong performance, μPSC technology, because of its interdisciplinary nature, requires optimal engineering of both electrochemical cell design and the culture conditions of the photosynthetic microorganisms. We present here a simple, economical culture method for the photosynthetic microorganism Chlamydomonas reinhardtii suitable for the application of this biologically based power system in any geographical location. This article provides a series of protocols for preparing materials and culture medium designed to facilitate the culture of a suitable C. reinhardtii strain even in a non-biological laboratory. Possible challenges and methods to overcome them are also discussed. Cultured C. reinhardtii perform sufficiently well that they have already been successfully utilized to generate power from a μPSC, generating a peak power of 200 μW from just 2 ml of exponential-phase algal culture in a μPSC with an active electrode surface area of 4.84 cm2 . The μPSC thus has potentially broad applications in low- and ultra-low-power devices and sensors. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Algal growth conditions and algal growth chamber fabrication Basic Protocol 2: Preparation of Tris-acetate-phosphate (TAP) nutrient medium Basic Protocol 3: Preparation of suspension algal culture from algal strain Basic Protocol 4: Preparation of stock culture plates (algal strain) from suspension algal culture.
在微流体环境中培养从光合作用中获取能量的绿藻的简单、经济的方法。
持续的技术进步不断增加对能源的需求。在各种类型的能量收集系统中,基于生物的系统在过去的几十年里一直是一个越来越受关注的领域。这些系统提供清洁,安全的电源解决方案,主要用于低功耗和超低功耗应用。微光合作用发电电池(μPSC)就是利用光合作用活细胞或生物体发电的一种系统。由于μPSC技术具有跨学科性质,因此需要对电化学电池设计和光合微生物培养条件进行优化。本文提出了一种简单、经济的光合微生物莱茵衣藻的培养方法,适用于这种生物动力系统在任何地理位置的应用。本文提供了一系列制备材料和培养基的方案,旨在促进在非生物实验室中培养合适的莱茵哈氏杆菌菌株。文中还讨论了可能面临的挑战和克服这些挑战的方法。培养的莱因哈蒂菌表现良好,已经成功地利用μPSC产生功率,在活性电极表面积为4.84 cm2的μPSC中,仅用2 ml指数相藻类培养物就能产生200 μW的峰值功率。因此,μPSC在低功耗和超低功耗器件和传感器中具有潜在的广泛应用。©2021 Wiley期刊有限责任公司基本方案1:藻类生长条件和藻类生长室制造基本方案2:制备三乙酸-磷酸(TAP)营养培养基基本方案3:从藻类菌株制备悬浮藻培养基本方案4:从悬浮藻培养中制备基质培养板(藻类菌株)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。