Microsoft Word - Ondas NB 9-2.doc Nova Biotechnologica 9-2 (2009) 183 CONVERSION OF CORN FIBER INTO FUEL ETHANOL VLADIMÍR ONDÁŠ, HANA NOVANSKÁ, VIERA HORVÁTHOVÁ Department of Biotechnology, University of SS. Cyril and Methodius, J. Herdu 2, Trnava, SK-917 01, Slovak Republic (vladimir.ondas@gmail.com) Abstract: Corn fiber due to its chemical composition (up to 20% starch, 50 - 60% non-starch polysaccharides) and availability has potential to serve as a substrate for manufacture of various products, including fuel ethanol. This paper deals with assessment of fiber-to-ethanol conversion. The water/dry fiber ratio in suspensions was 10/1. Enzyme liquefaction and saccharification of residual starch in corn fiber was carried out in two steps with thermostable α-amylase (20 min, 120°C) and mixture of pullulanase and glucomalyse (24 hours, 60°C). Procedures resulted in release of 57.7±1.6 mg of glucose per gram of dry fiber basis. It responds to the dextrose equivalent expression to 96.7±2.2%. By fermentation of the starch hydrolysates by yeasts Saccharomyces cerevisiae CCY-11-3 (5% v/v inoculum, 28°C, 72 hours) 0.48 g of ethanol per gram of glucose in hydrolysates was obtained. The solids after starch hydrolysis were separated by filtration and processed by acid pretreatment (0.1 g of conc. HCl/g of biomass/5 ml of water, 120°C, 20 min) with subsequent enzyme hydrolysis (24 hours, 60°C) by the multienzyme preparations containing cellulases and hemicellulases. Overall yield of reducing sugars after these two steps was 740.7±3.9 mg/gram of dry corn fiber basis. Fermentation of lignocellulosic hydrolysates by yeasts Pichia stipitis CCY-39-50-1 and Candida shehatea CCY-29-68-4 (in both cases 5% v/v inoculum, 28°C, 72 hours) resulted in 0.38 and 0.12 g of ethanol per gram of reducing sugars. The results indicate that applied pretreatment methods and used microorganisms are able to produce ethanol from corn fiber. Key words: corn fiber, enzyme hydrolysis, acid pretreatment, pentose- and hexose-fermenting yeasts 1. Introduction Corn fiber is a potential raw material for the production of various products, including fuel ethanol, because it is available in countries in which corn grains are processed (MOSIER et al., 2005; ATKIN, et al., 2008; NOUREDDINI et al., 2009). It is obtained in the process of wet milling of corn. Corn fiber, similar to other lignocellulosic materials is the complex of polysaccharides (35% hemicelluloses, 20% cellulose, up to 20% starch) and lignin. The main component of corn fiber is the outer corn grain layer – pericarp and residual part of starchy endosperm (GÁSPÁR et al., 2007). The first step of bioethanol production is enzymatic saccharification, in which polysaccharides are converted to monomeric sugars. In contrast to starch or cellulose, containing only hexose – glucose, hemicelluloses contain also pentoses, like xylose and arabinose. In the second step yeasts are used for the fermentation of these sugars (RÉCZEY et al., 1996, BALLESTEROS et al., 2004; PALMAROLA-ADRADOS et al., 2005). The most used pentose-fermenting microorganisms are various yeasts like Pichia stipitis, Candida shehatea, Pachysolen tannophilus, but also other strains of this species are able to ferment xylose (ZHAO et al., 2005; MARIS et al., 2006). Beside naturally occurring pentose-ferment yeasts, also genetically improved E. coli strains or Zymomonas mobilis strains are able to convert pentose to ethanol (JARBOE et al., 2007). 184 Ondáš, V. et al. Conversion of the starch along with the lignocellulosic components in the corn fiber would increase ethanol yields from corn wet mill by 13% (GROHMANN and BOTHAST, 1997) and is promising if the value of the corn fiber as an animal feed product is not severely affected (SCHELL et al., 2004). The aim of this study was to investigate the possibility of corn fiber to ethanol conversion by traditional methods of lignocellulose substrate processing. 2. Materials and methods 2.1 Materials Microbial strains Saccharomyces cerevisiae CCY-11-3, Pichia stipitis CCY 39-50-1 and Candida shehatea CCY 29-68-4 were obtained from The Culture Collection of Yeasts at Institute of Chemistry (Slovak Academy of Sciences, Slovakia), subcultured on slant agar media and stored in a refrigerator at a temperature about 4 °C. Corn fiber was received from Amylum Slovakia s.r.o (Boleráz, Slovakia) and stored at – 20°C. The following commercial enzymes were used: thermostable α- amylase (Termamyl 120L), glucoamylase (AMG 300L), thermostable pullulanase (Promozyme D2), cellulose (Celluclast 1,5L) and β-glucosidase (Viscozyme L). All enzymes were obtained from Novozymes (Denmark). 2.2 Corn fiber destarching A 10% (w/w) non-ground corn fiber dry matter aqueous solution was prepared. Thermostable α-amylase for starch liquefaction (0.3 µl/g starch) was added in two steps and the mixture was boiled at up to 120°C for 20 min. After cooling to about 60°C was glucoamylase (0.8 µl/g starch) and thermostable pullulanase (7.2 µl/ g starch) added and incubated at 60°C for 24 hours. The solids were recovered by filtration. Schematic view of this process in the context of other processes is depicted in Fig. 1. 2.3 Pretreating of destarched corn fiber with hydrochloric acid Solids after destarching were mixed with 5 ml of water and 0.1 g of concentrated hydrochloric acid. Mixture was heated in a pressure device at 120°C for 20 minutes. After cooling to room temperature, the solids were recovered by filtration. Schematic view of this process in the context of other processes is illustrated in Fig. 1. 2.4 Enzymatic hydrolysis of cellulose in pretreated corn fiber The mixture of cellulolytic enzymes (119 µl/g dry matter of lignocellulose) and β- glucosidase (595 µl/g dry matter of lignocellulose) was inoculated to 5% acetate buffer solution of destarched and pretreated solids of corn fiber. The reaction was allowed to proceed for 24 hours at 60°C and stirring at speed rate 120 rpm. Schematic view of this process in the context of other processes is shown in Fig. 1. Nova Biotechnologica 9-2 (2009) 185 Fig. 1. Schematic view of processes involved in the processing of corn fiber to ethanol. 2.5 Fermentation Liquid hydrolysate from corn fiber destarching was inoculated with 5% inoculum of yeasts Saccharomyces cerevisiae, fermentation medium components were added and pH was adjusted to 5.0. Liquid hydrolysate from enzyme hydrolysis of destarched and pretreated corn fiber was inoculated with 5% inoculum of yeasts Pichia stipitis or Candida shehatea, fermentation medium components were added and pH was adjusted to 5.0. Fermentation was carried out at 28°C and lasts 72 hours. Schematic view of this process in the context of other processes is depicted in Fig. 1. 2.6 Analytical procedures The dry matter content of corn fiber, destarched corn fiber and pretreated corn fiber was determined by drying of the sample at 105°C. Glucose content was determined 186 Ondáš, V. et al. using BIOLA TEST GLUKOSA GOD 1500 (Lachema, Czech Republic) and reducing sugars were determined using dinitrosalicylic acid (DNS). Analyses of glucose, maltose, maltotriose and oligosaccharides were performed by high performance liquid chromatography (HPLC) with an HPX-87C column (Bio-Rad Laboratories, Hercules, USA) at 80°C with water as the mobile phase at a flow rate of 0.5 ml/min. 3. Results and discussion Destarching of corn fiber with enzymes was carried out in two steps using thermostable α-amylase for liquefaction and mixture of pullulanase and glucoamylase for saccharification. Kinetics of saccharification is shown in Table 1. Results are averages of three determinations Table 1. Saccharification kinetics of liquefied starch in suspension with 10% content of corn fiber dry matter. Reducing sugars Glucose Hour mg/ml hydrolysate mg/g dry matter mg/ml hydrolysate mg/g dry matter DE (%) 0 3.0±0.2 24.4±1.6 0.6±0.05 5.2±0.4 8.7±0.3 2 5.1±0.1 41.8±0.8 4.4±0.1 35.8±0.8 59.9±1.5 4 5.8±0.2 47.2±1.6 4.6±0.1 37.8±0.8 63.3±1.6 6 6.1±0.1 50.0±0.8 5.5±0.2 44.5±1.6 74.5±1.6 8 6.6±0.1 53.8±0.8 6.4±0.1 52.3±0.8 90.0±1.9 24 9.6±0.1 78.5±0.8 7.1±0.2 57.7±1.6 96.7±2.2 DE (%) = dextrose equivalent In the first eight hours the dextrose equivalent achieved 90%, and in the next sixteen hours it rose to almost 97%. Similar time course of saccharification is described in the work of LEATHERS (2003). Glucose represents about 64.6% of all sugars in hydrolysate, maltotriose 17.2% and last 18% other oligosaccharides. We supposed that lower proportion of glucose was caused by reduced availability of starch as a result of the particle size of substrate. Destarching of corn fiber leads to better access of pretreatment or hydrolysing agents to non-starch polysaccharides or other substrates. Because corn fiber contains about 35% of hemicelluloses, 18% of cellulose and 8% of lignin, it is necessary to pretreat it before enzymatic hydrolysis of polysaccharides to achieve the maximum release of fermentable sugars. Acid hydrolysis is one of the possible pretreatment ways (SHIBANUMA et al., 1999; SAHA, 2003; NOUREDDINI et al., 2009). In our experiments 1 g of destarched corn fiber was supplemented with 0.1 g of concentrate hydrochloric acid and 5 ml of water. The mixture was heated in a pressure device at up to 120°C for 20 minutes. After heating the device was Nova Biotechnologica 9-2 (2009) 187 allowed to cool to room temperature and solids were separated from liquid hydrolysate by filtration. Obtained results are listed in Table 2. Results are averages of three determinations. Table 2. Concentration of reducing sugars and glucose after pretreatment of destarched corn fiber with hydrochloric acid. Reducing sugars Glucose mg/ml hydrolysates mg/ml hydrolysates mg/ml hydrolysates mg/g dry matter Hydrochloric acid 35.2 ± 1.3 587 ± 3 7.0 ± 0.4 117 ± 1 Because most of the pretreatment strategies do not lead to complete hydrolysis of polysaccharides, an important step in processing any lignocellulosic material is the enzymatic hydrolysis of cellulose or hemicelluloses or both polysaccharides. In addition, enzymatic processes are carried out under mild conditions and thus lower consumption of energy. The risk of fermentation inhibitors creation is also minimal. Processing of destarched corn fiber with cellulytic and hemicellulytic enzymes in our experiments lasts 24 hours and temperature was maintained at 60°C. The results are summarized in Table 3 and are averages of three determinations. Table 3. Concentration of reducing sugars and glucose after enzymatic hydrolysis of destarched corn fiber and destarched and pretreated corn fiber. Reducing sugars Glucose Substrate mg/ml hydrolysates mg/ml hydrolysates mg/ml hydrolysates mg/g dry matter Destarched corn fiber 3.7 ± 0.1 61.7 ± 2.2 1.5 ± 0.1 25.8 ± 0.9 Destarched and pretreated corn fiber 8.2 ± 0.3 154 ± 1 2.81 ± 0.1 52.9 ± 0.3 By HPLC (results provided by Amylum Slovakia s.r.o., Boleráz) was determined that oligosaccharides represent more than 60% of all sugars in enzyme hydrolysates of destarched and pretreated corn fiber. Other saccharides were maltose and maltotriose. In next part of the research fermentation of starch and lignocellulosic hydrolysates prepared from corn fiber was carried out. For the fermentation of starch hydrolysates yeasts Saccharomyces cerevisiae were used and for lignocellulosic hydrolysates yeasts Pichia stipitis and Candida shehatea were used. Fermentation conditions were the same for all three yeast strains – pH 5.0, 5% inoculum, 28°C, 72 hours. Results are shown in Table 4 (starch hydrolysates), Table 5 and Table 6 (lignocellulosic hydrolysates). 188 Ondáš, V. et al. Table 4. Yield of ethanol after fermentation by Saccharomyces cerevisiae of starch hydrolysates with 10% content of corn fiber dry matter. Amount of waterless ethanol Substrate g/ 100 ml fermentation medium g/g glucose g/g dry matter Conversion [%]* Corn fiber 0.56 0.48 0.03 94.2 * The degree of conversion is value relative to the maximum theoretical yield of ethanol (0.51 g ethanol from 1 g of glucose) (BALLESTEROS et al., 2004). BURA et al. (2002), for the fermentation of starch from corn fiber also used yeasts Saccharomyces cerevisiae, but with substrate pretreated by SO2 steam explosion. In those conditions yeasts Saccharomyces cerevisiae converted saccharides in hydrolysates with efficiency from 90 to 96%. Also our conversion efficiency falls within this range. Table 5. Yield of ethanol after fermentation by Pichia stipitis and Candida shehatae of lignocellulosic hydrolysate of destarched corn fiber pretreated with hydrochloric acid. Amount of waterless ethanol Conversion [%]* Microorganism g/ 100 ml fermentation medium g/g reducing sugars g/g dry matter Pichia stipitis 0.16 0.44 0.02 84.2 Candida shehatae 0.05 0.14 0.01 28.4 * The degree of conversion is value relative to the maximum theoretical yield of ethanol (0.51 g ethanol from 1 g of glucose) (BALLESTEROS et al., 2004). Table 6. Yield of ethanol after fermentation by Pichia stipitis and Candida shehatea of hydrolysate of corn fiber pretreated by acid prehydrolysis and enzymatic hydrolysis. Amount of waterless ethanol Conversion [%]* Microorganism g/ 100 ml fermentation medium g/g reducing sugars g/g dry matter Pichia stipitis 0.85 0.38 0.09 73.9 Candida shehatea 0.27 0.12 0.03 22.9 * The degree of conversion is value relative to the maximum theoretical yield of ethanol (0.51 g ethanol from 1 g of glucose) (BALLESTEROS et al., 2004). Nova Biotechnologica 9-2 (2009) 189 We have to state that fermentation of destarched corn fiber hydrolysates by Candida shehatea was efficient not enough. One of the problems causing such low values may also be poor adaptation of yeast strain Candida shehatea CCY 29-68-4 to the fermentation conditions such as temperature, pH, presence of inhibitors, the composition of the fermentation medium or the need for aeration. 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