Princess Requiso scite author profile

Biosurfactants are considered a good alternative to highly-polluting petroleum-based surfactants that are toxic and non-biodegradable in nature. However, the high production cost of biosurfactants limits its potential for commercialization. The use of a highly efficient biosurfactant-producing actinomycetes isolate, combined with the utilization of low-cost substrates such as agro- industrial wastes, may aid in lowering the overall production cost. In this study, twenty-eight (28) actinomycetes isolated from distillery wastes and soil samples were screened for the production of extracellular biosurfactants. Based on the preliminary screening experiment, isolate CGS B11 – molecularly identified as Streptomyces angustmyceticus – produced the biosurfactant with the highest emulsification activity (E24). Subsequently, the best alternative carbon and nitrogen sources, salt supplement, and pH level were determined using one-factor-at-a-time (OFAT) experiments. The highest measured biosurfactant activity was observed in the medium containing molasses, spent yeast autolysate, and NaCl, and a pH level ranging from 6.0–7.0. Biosurfactant production was observed to be growth associated with maximum emulsification activity achieved after 4 d of fermentation (late log phase). FTIR (Fourier transform infrared) spectra and biochemical composition analyses of the S. angustmyceticus CGS B11 biosurfactant suggest that it belongs to the lipopeptide type of biosurfactants. S. angustmyceticus CGS B11 biosurfactant also showed resistance and high stability on a wide range of temperature, pH, and salinity, and the ability to form stable and dense emulsions with various oils tested. It has great potential for various applications such as in the food and pharmaceutical industries, and in oil recovery and bioremediation. The results of this study will hopefully serve as a basis for large-scale production of biosurfactants utilizing agro-industrial wastes in the country.

Optimization of Fermentation Factors for Polyhydroxybutyrate (PHB) Production Using Bacillus megaterium PNCM 1890 in Simulated Glucose-Xylose Hydrolysates from Agricultural Residues

Dañez¹,

Requiso²,

Alfafara³

et al. 2020

The polyhydroxybutyrate (PHB) production performance of Bacillus megaterium PNCM 1890 in multiple carbon sources was assessed in a model system of simulated glucose-xylose hydrolysates from several agricultural residues (corn stover, sugarcane bagasse, and banana pseudostem). Factors investigated were the type of nitrogen source, carbon-to-nitrogen (C/N) ratio, carbon-to-phosphorus (C/P) ratio, and amount of trace elements in the fermentation medium. Results show that the type of nitrogen source had a significant effect on bacterial growth and PHB production, with urea as the most preferred nitrogen source. In contrast, the type of simulated hydrolysate had no significant effect on the behavior of the bacteria, implying that the microorganism can potentially utilize hydrolysates from various agricultural residues. However, considering conversion efficiency and operating cost, simulated corn stover hydrolysate was selected as the best carbon source. A fermentation time of 28 h was found sufficient to completely utilize both glucose and xylose from the simulated hydrolysate. PHB was also confirmed as a growth-associated product of the bacteria, with observable patterns of catabolite repression and diauxic growth. Optimum conditions that maximize biomass concentration (7.3 g/L), PHB concentration (3.91 g/L), and substrate consumption (98.77% for glucose; 93.76% for xylose) were 14.3 g/g C/N ratio, 21.4 g/g C/P ratio, and 8 mL of trace elements solution (TES) per L of fermentation medium. Nonetheless, PHB was successfully produced using simulated corn stover hydrolysate and urea as carbon and nitrogen sources, respectively. The study provides baseline information on the use of actual hydrolysate, efficient fermentation, and upscaled production of bioplastics from agricultural residues.

Sustainable Polyhydroxyalkanoates (PHA) Extraction Protocol Selection Using AHP-GRA

Requiso

Nayve

Ventura

2021

Preprint

In this study, a sustainable protocol for PHA extraction was methodically selected using two (2) multi-criteria decision analysis (MCDA) tools, the analytic hierarchy process (AHP) and grey relational analysis (GRA). AHP was first used to evaluate the proposed criteria categorized into technical, economic, and environmental aspects using a collected survey of pairwise comparisons. Based on the results of AHP, it was identified that both environmental and economic aspects were given higher priorities. Among the criteria, hazards and risks has the highest overall importance, followed by extraction cost and purity. Using GRA, twelve (12) protocol alternatives categorized into solvent extraction and precipitation, non-PHA cell mass (NPCM) digestion, and assisted extraction methods were graded according to the criteria. Overall, the highest priority weights were given to NPCM digestion protocols including sodium hydroxide, sodium hydroxide + sodium dodecyl sulfate, and ammonia water. The reagents involved in these protocols are ecologically benign and cheaper compared to other solvents; hence, the higher grades in the environmental and economic aspect. Sensitivity analysis also proved that these protocols are excellent, particularly if extraction cost is given a higher priority. However, if hazards and risks and purity were given more importance, butyl acetate is preferable than sodium hydroxide. Further investigations such as the validation and optimization of protocols, together with feasibility studies and life cycle analyses may be integrated with the results of this study to comprehensively determine a sustainable PHA extraction protocol.

Steam Explosion and Sequential Steam Explosion – Dilute Acid Pretreatment Optimization of Banana Pseudostem for Polyhydroxybutyrate (PHB) Production

Mabazza¹,

Requiso²,

Alfafara³

et al. 2020

Polyhydroxybutyrate (PHB) is a suitable biodegradable alternative to non-renewable petroleum-based plastics. Readily available agricultural lignocellulosic residues such as banana pseudostem can be utilized as a substrate to reduce the production cost of PHB and improve its feasibility for commercialization. Accordingly, pretreatment of banana pseudostem is needed to efficiently convert the substrate to PHB. In this study, optimization of two pretreatment methods for banana pseudostem – namely, steam explosion and sequential steam explosion – dilute acid pretreatment – were optimized to improve the digestibility of the biomass and consequently increase the production of reducing sugars in the hydrolysate during enzymatic saccharification. Response surface methodology (RSM)-designed experiments showed that among all factors investigated, for both pretreatment methods, the steam explosion temperature had the strongest positive impact on reducing sugar production. Optimum conditions of steam explosion pretreatment were 219.31 °C steam explosion temperature and 10 min of pretreatment time, producing 7.33 g/L (48.87% yield) of reducing sugars in the enzymatic hydrolysate. For sequential pretreatment, optimum conditions were 220 °C steam explosion temperature, 135 °C dilute acid temperature, 44 min of dilute acid reaction time, and 1.57% w/v H2SO4, with a corresponding reducing sugar concentration of 13.02 g/L (86.79% yield). A 90% increase in reducing sugar yield was observed after dilute acid pretreatment of steam-exploded banana pseudostem. Using the hydrolysate from sequentially-pretreated banana pseudostem, PHB (2.64 g/L) was successfully synthesized after 12 h of bacterial fermentation. Hence, sequential pretreatment was proven effective in producing enzymatic hydrolysates from banana pseudostem for PHB production.

Polyhydroxyalkanoates (PHA) Extraction Protocol Selection Using AHP-GRA

Requiso¹,

Ventura²,

Nayve³

et al. 2022

In this study, a sustainable protocol for PHA extraction was methodically selected using two multi-criteria decision analysis (MCDA) tools, the analytic hierarchy process (AHP), and grey relational analysis (GRA). AHP was first used to evaluate the proposed criteria categorized into technical, economic, and environmental aspects using a collected survey of pairwise comparisons. Based on the results of AHP, it was identified that both environmental and economic aspects were given higher priorities. Among the criteria, hazards and risks had the highest overall importance, followed by extraction cost and purity. Using GRA, 12 protocol alternatives categorized into solvent extraction and precipitation, non-PHA cell mass (NPCM) digestion, and assisted extraction methods were graded according to the criteria. Overall, the highest priority weights were given to NPCM digestion protocols including sodium hydroxide, sodium hydroxide + sodium dodecyl sulfate (SDS), and ammonia water. The reagents involved in these protocols are ecologically benign and cheaper compared to other solvents, hence the higher grades in the environmental and economic aspects. Sensitivity analysis also proved that these protocols are excellent, particularly if extraction cost is given a higher priority. However, if hazards and risks and purity were given more importance, butyl acetate is preferable to sodium hydroxide. Further investigations such as the validation and optimization of protocols, together with feasibility studies and life cycle analyses, may be integrated with the results of this study to comprehensively determine a sustainable PHA extraction protocol.