Abstract
In this work, the production of xylitol from a hemicellulosic hydrolysate of exhausted olive pomace (EOP), a residue originated in the olive oil production process by Candida boidinii, was assessed. The hydrolysate was obtained by dilute acid pretreatment of EOP at 170 °C and 2% H2SO4 (w/v). A previous detoxification step of the hydrolysate was necessary, and its treatment with activated charcoal and ion-exchange resin was evaluated. Prior to fermentation of the hydrolysate, fermentation tests in synthetic media were performed to determine the maximum xylitol yield and productivity that could be obtained if inhibitory compounds were not present in the medium. In addition, the glucose existing in the media exerted a negative influence on xylitol production. A maximum xylitol yield of 0.52 g/g could be achieved in absence of inhibitor compounds. Fermentation of the hemicellulosic hydrolysate from EOP after detoxification with ion-exchange resin resulted in a xylitol yield of 0.43 g/g.
Highlights
Xylitol is a sugar alcohol with five carbon atoms and similar sweetening properties to sucrose.Xylitol is widely known for its various health benefits, including a great capacity to decrease the risk of dental caries
The composition in sugars and inhibitory compounds in the hydrolysates before and after detoxification were measured by high performance liquid chromatography (HPLC) using a Waters 2695 liquid chromatograph (Mildford, MA, USA) equipped with a refractive index detector (Waters 2414)
The most abundant one was xylose, accounting for 64% of the total sugars contained in the acid hydrolysate
Summary
Xylitol is a sugar alcohol with five carbon atoms and similar sweetening properties to sucrose.Xylitol is widely known for its various health benefits, including a great capacity to decrease the risk of dental caries. The use of xylitol has increasingly gained interest for food and medicine manufacturing in the past several years [2]. It has been produced using a chemical synthesis process, reducing pure xylose at very high temperatures and pressures. Due to the complexity of this chemical process, the need for pure xylose as feedstock and the associated high-energy requirements [3], novel biological processes, where xylitol is produced by xylose fermentation with microorganisms, have emerged. These alternative processes can be more environmentally friendly and lower energy consumption, making biological production of xylitol economically viable [4,5]
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