Center for Systems Biology, University of Iceland, 101 Reykjavik, Iceland.
J Biotechnol. 2012 Oct 31;161(3):242-9. doi: 10.1016/j.jbiotec.2012.07.004. Epub 2012 Jul 14.
Green microalgae have recently drawn attention as promising organisms for biofuel production; however, the question is whether they can grow sufficient biomass relative to limiting input factors to be economically feasible. We have explored this question by determining how much biomass the green microalga Chlorella vulgaris can produce in photobioreactors based on highly efficient light-emitting diodes (LEDs). First, growth results were improved under the less expensive light of 660 nm LEDs, developing them in the laboratory to meet the performance levels of the traditional but more expensive 680 nm LEDs by adaptive laboratory evolution (ALE). We then optimized several other key parameters, including input superficial gas velocity, CO(2) concentration, light distribution, and growth media in reference to nutrient stoichiometry. Biomass density thereby rose to approximately 20 g dry-cell-weight (gDCW) per liter (L). Since the light supply was recognized as a limiting factor, illumination was augmented by optimization at systematic level, providing for a biomass productivity of up to 2.11 gDCW/L/day, with a light yield of 0.81 gDCW/Einstein. These figures, which represent the best results ever reported, point to new dimensions in the photoautotrophic performance of microalgal cultures.
绿色微藻最近作为生物燃料生产有前途的生物受到关注; 然而,问题是它们相对于限制输入因素能否生长足够的生物量,从而具有经济可行性。我们通过确定绿藻小球藻在基于高效发光二极管 (LED) 的光生物反应器中可以生产多少生物量来探讨这个问题。首先,在更便宜的 660nm LED 光下提高了生长效果,通过适应性实验室进化 (ALE) 将其在实验室中开发,以达到传统但更昂贵的 680nm LED 的性能水平。然后,我们针对其他几个关键参数进行了优化,包括输入表面气体速度、CO2 浓度、光分布和生长介质,参考营养化学计量学。生物量密度因此上升到每升约 20 克干细胞重量 (gDCW)。由于光供应被认为是一个限制因素,通过系统水平的优化增加了光照,提供了高达 2.11gDCW/L/天的生物质生产力,光产率为 0.81gDCW/爱因斯坦。这些数字代表了迄今为止报告的最佳结果,为微藻培养的光自养性能开辟了新的维度。
