Abstract
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.
Highlights
Microalgae have significant advantages over traditional food crops as biofuel sources because of their high area yields, non-requirement for agricultural resources and their potential as a CO2 bio-sequestration platform to capture flue gas released from power plants [1]
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
This study investigated the use of sugar hydrolysate obtained from enzymatic saccharification of microalgal biomass (Chlorella sp. and Tetraselmis suecica) as a fermentation feedstock for the production of industrial chemicals
Summary
Microalgae have significant advantages over traditional food crops as biofuel sources because of their high area yields, non-requirement for agricultural resources (arable land and clean water) and their potential as a CO2 bio-sequestration platform to capture flue gas released from power plants [1]. Different types of biofuels (such as biodiesel and alcohol) can be produced from microalgal biomass depending of which component of the biomass is utilized [2]. Carbohydrate in microalgal cells is generally found as starch in the chloroplasts and cellulose or polysaccharides in the cell wall. Cultivation conditions, such as light intensity, temperature and salt concentration, have previously been shown to have a significant effect on microalgal carbohydrate content and composition [4] [5]
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