微藻生物燃料和生物制品的生物精馏生产:小球藻和水四角藻水解物发酵生产乙酸

M. A. Kassim, M. Rashid, R. Halim
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引用次数: 8

摘要

微藻生物产业的成功商业化需要设计一个集成的微藻生物精炼系统,以促进从生物质中联合生产生物燃料、高价值产品和工业化学品。在这项研究中,我们研究了利用微藻生物质(小球藻和T. suecica)酶法糖化所得的糖水解物作为发酵原料,生产工业上重要的化学品,特别是乙酸和丁酸。利用低糖水解物作为厌氧发酵底物(1.5 ~ 2.4 g/L),我们能够阻止C. saccharoperbutylacetonicum激活其溶剂生成途径。因此,发酵过程产生的产物流主要是有机酸(乙酸和丁酸),而不是溶剂(丁醇、乙醇和丙酮)。乙酸在小球藻发酵产物中占92%,在小球藻发酵产物中占80%。对于suecica,发酵几乎消耗了水解液中所有可用的糖(高达初始糖的92%),并产生了合理的发酵产物产量(0.08 g发酵产物/g糖)。Gompertz方程成功地用于预测醋酸和其他发酵产物在两个物种之间的形成动力学。研究结果表明,微藻糖发酵可以生产工业上重要的化学品,如乙酸和丁酸。研究中描述的过程可能被用作一个增值步骤,在集成的微藻生物精炼系统中从细胞碎片中产生生化物质。
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Towards Biorefinery Production of Microalgal Biofuels and Bioproducts: Production of Acetic Acid from the Fermentation of Chlorella sp. and Tetraselmis suecica Hydrolysates
Successful commercialization of microalgal bio-industry requires the design of an integrated microalgal biorefinery system that facilitates the co-production of biofuels, high-value products and industrial chemicals from the biomass. In this study, we investigated the use of sugar hydrolysate obtained from enzymatic saccharification of microalgal biomass (Chlorella sp. and T. suecica) as fermentation feedstock to produce industrially important chemicals, in particular acetic acid and butyric acid. By using hydrolysate with low sugar content as substrate for the anaerobic fermentation (1.5 - 2.4 g/L), we were able to prevent the bacterium C. saccharoperbutylacetonicum from activating its solventogenesis pathway. As a result, the fermentation process generated a product stream that was dominated by organic acids (acetic acid and butyric acid) rather than solvents (butanol, ethanol and acetone). Acetic acid constituted up to 92 wt% of Chlorella’s fermentation products and 80 wt% of T. suecica’s fermentation products. For T. suecica, the fermentation consumed almost all of the sugar available in the hydrolysate (up to 92% of initial sugar) and produced a reasonable yield of fermentation products (0.08 g fermentation products/g sugar). The Gompertz equation was successfully used to predict the formation kinetics of acetic acid and other fermentation products across both species. The results in the study demonstrate the production of industrially important chemicals, such as acetic acid and butyric acid, from the fermentation of microalgal sugar. The process described in the study can potentially be used as a value-adding step to generate biochemicals from cell debris in an integrated microalgal biorefinery system.
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