Enzymatic hidrollys of pulp sisal

This study corresponds to the enzymatic hydrolysis of previously mercerized pulp sisal (20g polpa.L-1 aqueous 20% NaOH) via mechanical agitation (50° C, 3h, M-AgMec-50°) and ultrasound (25° C, 1h) at 20% (M-US-20%) and 40% (-M-US 40%) of amplitude. The mercerized pulp had the following properties: M-AgMec-50° 97.4% of α-cellulose, 68% of crystallinity (Ic) and average viscometric molecular weight (MMvis) of 94618,0g.mol-1, M-US-20% 95% of α-cellulose, 68% of Ic and MMvis of 87581,6 g.mol-1, M-US-40% 91.2% α-cellulose, 66% of Ic and 81786,9g .mol-1 of MMvis. The hydrolysis reactions (48 h) were performed using commercial enzymes cellulase (Accellerase 1500) and enzymes obtained from the growth of the fungus Aspergillus sp. Aliquots constituted of unreacted pulp and liquor were taken from the medium during the reaction. The unreacted pulps were characterized with respect to Ic, MMvis, length and thickness and scanning electron microscopy (SEM). The liquors were analyzed by high performance liquid chromatography (HPLC) and by the Miller method (DNS). In the hydrolysis of the cellulose pulp sisal M-AgMec -50°, the amount of enzymes used was varied (0.5 (HE- SAG-0.5), 0.7 (HE-SAG-0.7) and 0.9 (HE-SAG-0.9) mL enzyme complex.g-1 pulp). The highest yield of glucose (98%), obtained via HPLC, corresponded to HE-SAG-0.9. This proportion of enzymes was used for the reactions using the pulps M-US-20% (HE-SU20-0,9) and M-US-40% (HE-SU40-0,9). Among all the considered pulps, the best performance for glucose was HE-SAG-0.9 as the presence of greater amounts of hemicellulose in pulps treated via ultrasonic (HE-HE-SU 20-0,9 SU40-0,9 ) made it difficult for the enzymes to access the cellulose chains. The analysis of unreacted pulps showed that, in general, cellulase enzymes act primarily on the non-crystalline region. Different behaviors were observed with respect to Ic and MMvis, depending on the time interval elapsed during the reaction. Considering the peak density of greater length for the fibers HE-SAG-0.5; HE-SAG-0.7 and HE-SAG-0.9, the variation during the reaction was [129-215] μm for [77-129] μm. The fibers of lengths greater than [359-599] μm became smaller, thus increasing the concentration of fibers with lengths smaller than 359μm in the medium. For HE-SAG-0.5; HE-SAG-0.7; HE-SAG-0.9 the peak of greater density of thickness varied from [28-39] to [11-23] μm and, for HE-SU20-0,9 and HE-SU40-0,9 that varied from [18-30] μm to [14-18] μm. The set of results indicated that the enzymes acted primarily from the fiber surfaces. Reactions using commercial cellulases and enzymes obtained from Aspergillus sp fungus were performed using other substrates in addition to M-AgMec-50°(HE-SAG-0,5; H-Aspergillus-SAG-1,5), which were microcrystalline cellulose (HE-MICRO-0,5; H-Aspergillus-MICRO-1,5) and filter paper (HE-PFT-0.5, H-Aspergillus-PFT-1,5). Out of the three substrates used, the filter paper showed a higher amount of hemicellulose, and therefore the highest concentration of reducing sugars (DNS) was observed in this sample for the two enzymes. For all the substrates, the fungal enzyme produced a much lower level of sugar than that obtained by using commercial enzyme. The enzymes were evaluated by electrophoresis of proteins. The bands of endoglucanases and exoglucanases were observed in the fungal enzymes, confirming that during the growth of the fungus there was the formation of cellulase enzymes. However, the respective bands of commercial cellulases showed that these enzymes are present in considerably higher concentration when compared to those obtained from the fungus Aspergillus sp. When comparing the results of Ic, MMvis, length and thickness for all the unreacted pulps using commercial and fungal enzymes under the conditions considered in this study, it was observed that fungal enzymes acted significantly less intensely than the commercial ones. Studies involving fungal enzymes need deepening. Among the obtained results, there is a high conversion of the glucose pulp AgMec-M50°, which indicated that the enzymatic hydrolysis of cellulosic pulps with features similar to the pulp used in the present study, has great potential for the production of sugars via enzymatic catalysis aiming at the production of ethanol. (AU)