RESUMO
The aim of the present study was to investigate the potential application of the biosurfactant from Candida lipolytica grown in low-cost substrates, which has previously been produced and characterized under optimized conditions as an adjunct material to enhance the remediation processes of hydrophobic pollutants and heavy metals generated by the oil industry and propose the formulation of a safe and stable remediation agent. In tests carried out with seawater, the crude biosurfactant demonstrated 80% oil spreading efficiency. The dispersion rate was 50% for the biosurfactant at a concentration twice that of the CMC. The biosurfactant removed 70% of motor oil from contaminated cotton cloth in detergency tests. The crude biosurfactant also removed 30-40% of Cu and Pb from standard sand, while the isolated biosurfactant removed ~30% of the heavy metals. The conductivity of solutions containing Cd and Pb was sharply reduced after biosurfactants' addition. A product was prepared through adding 0.2% potassium sorbate as preservative and tested over 120 days. The formulated biosurfactant was analyzed for emulsification and surface tension under different pH values, temperatures, and salt concentrations and tested for toxicity against the fish Poecilia vivipara. The results showed that the formulation had no toxicity and did not cause significant changes in the tensoactive capacity of the biomolecule while maintaining activity demonstrating suitability for potential future commercial product formulation.
RESUMO
Almost all oleaginous microorganisms are available for biodiesel production, and for the mechanism of oil accumulation, which is what makes a microbial approach economically competitive. This study investigated the potential that the yeast Candida lipolytica UCP0988, in an anamorphous state, has to produce simultaneously a bioemulsifier and to accumulate lipids using inexpensive and alternative substrates. Cultivation was carried out using waste soybean oil and corn steep liquor in accordance with 2² experimental designs with 1% inoculums (107 cells/mL). The bioemulsifier was produced in the cell-free metabolic liquid in the late exponential phase (96 h), at Assay 4 (corn steep liquor 5% and waste soybean oil 8%), with 6.704 UEA, IE24 of 96.66%, and showed an anionic profile. The emulsion formed consisted of compact small and stable droplets (size 0.2-5 µm), stable at all temperatures, at pH 2 and 4, and 2% salinity, and showed an ability to remove 93.74% of diesel oil from sand. The displacement oil (ODA) showed 45.34 cm² of dispersion (central point of the factorial design). The biomass obtained from Assay 4 was able to accumulate lipids of 0.425 g/g biomass (corresponding to 42.5%), which consisted of Palmitic acid (28.4%), Stearic acid (7.7%), Oleic acid (42.8%), Linoleic acid (19.0%), and γ-Linolenic acid (2.1%). The results showed the ability of C. lipopytica to produce both bioemulsifier and biodiesel using the metabolic conversion of waste soybean oil and corn steep liquor, which are economic renewable sources.
Assuntos
Biocombustíveis , Candida/metabolismo , Emulsificantes/metabolismo , Óleos Voláteis/metabolismo , Óleo de Soja/metabolismo , Biomassa , Candida/crescimento & desenvolvimento , Concentração de Íons de Hidrogênio , Resíduos Industriais , Óleos Voláteis/química , Ácido Oleico/metabolismo , Ácido Palmítico/metabolismo , Óleo de Soja/química , Ácidos Esteáricos/metabolismo , Especificidade por Substrato , Temperatura , Zea mays/química , Zea mays/metabolismoRESUMO
Background: Biotechnological processes are costly, especially for the production of biosurfactants. The successful production of a biosurfactant is dependent on the development of processes using low cost raw materials. Considering the importance of the characteristics of a biosurfactant to facilitate its industrial application, the properties of the biosurfactant produced by Candida lipolytica through previously optimized medium have been established. Results: The yeast was grown for 72 h to determine the kinetics of growth and production. The surface tension of the cell-free broth was reduced from 55 to 25 mN/m. The yield of biosurfactant was 8.0 g/l with a CMC of 0.03%. The biosurfactant was characterized as an anionic lipopeptide composed of 50% protein, 20% lipids, and 8% of carbohydrates. Conclusions: The isolated biosurfactant showed no toxicity against different vegetable seeds: Brassica oleracea, Solanum gilo and Lactuca sativa L. and the micro-crustacean Artemia salina. The properties of the biosurfactant produced suggest its potential application in industries that require the use of effective compounds at low cost.
Assuntos
Tensoativos/metabolismo , Tensoativos/química , Candida/metabolismo , Artemia , Tensoativos/toxicidade , Tensão Superficial , Cinética , Biomassa , Lipopeptídeos , Ácidos Graxos/análise , Fermentação , MicelasRESUMO
Candida lipolytica IA 1055 produced extracellular biosurfactants with emulsification activity by fermentation using babassu oil and D-glucose as carbon sources. Natural seawater diluted at 50% supplemented with urea, ammonium sulfate, and phosphate was used as economic basal medium. The best results were achieved with the YSW-B2 medium, which contained urea, ammonium sulfate, and babassu oil and with YSW-B3 medium, which contained urea, ammonium sulfate, phosphate, and babassu oil, kept under fed batch fermentation for 60 hours with 5% of babassu oil. For the two media, the maximum specific growth rates were 0.02 h-1 and 0.04 h-1; the generation times were 34.6 h-1 and 17.3 h-1, and the emulsification activities were 0.666 and 0.158 units, respectively. The molecules of these new bioemulsifiers were contituted of carbohydrates, proteins and lipids.
Candida lipolytica IA 1055 produziu biosurfactantes extracelulares com atividade de emulsificação, através de fermentação utilizando óleo de babaçu e D-glicose como fontes de carbono. A água do mar diluída a 50% suplementada com uréia, sulfato de amônio e fosfato foi usada como meio basal. Os melhores resultados foram atingidos com os meios YSW-B2 (contendo uréia, sulfato de amônio e óleo de babaçu)e YSW-B3 (contendo uréia, sulfato de amônio, fosfato e óleo de babaçu), através de fermentação em batelada alimentada com 5% de óleo de babaçu. A velocidade específica de crescimento foi de 0,02 h-1 e 0,04 h-1; tempo de geração de 34,6 h-1 e 17,3 h-1 e atividade de emulsificação igual a 0,666 e 0,158 unidades, respectivamente. As moléculas dos novos bioemulsificantes demonstraram ser constituídas por carboidratos, proteínas e lipídeos.
RESUMO
Carbohydrate-containing molecules were located on the surface of Candida lipolytica by using ruthenium red in a cytochemical study. The yeast was grown in media containing Tween 80. The surfactant, at 1.0% and 0.5%, was added to the culture medium in different intervals of time, correspondent to the beginning of exponential growth phase, mid of logarithimic phase and beginning of stationary growth phase. Control cultures were grown in a medium containing glucose. The growth of the yeast in media containing glucose and Tween 80 induced changes in the pattern of distribution and location of acid polyssacharides in the cell wall of the microorganism. In adition, the pattern also changed according to Tween 80 concentration. The influence of Tween 80 on cellular carbohydrate expression is discussed.
Moléculas contendo resíduos de açúcares foram localizadas sobre a superfície de Candida lipolytica utilizando-se o vermelho de rutênio como marcador citoquímico. A levedura foi semeada em meio contendo Tween 80. O surfactante, nas concentrações de 1,0% e 0,5%, foi adicionado ao meio de cultivo em diferentes intervalos de tempo, correspondentes ao início da fase exponencial de crescimento, meio da fase logarítmica e final da fase exponencial de crescimento, Culturas-controles foram cultivadas em meio contendo glicose como fonte de carbono. O crescimento da levedura em meios contendo glicose ou Tween 80 induziu o surgimento de alterações na distribuição e na localização de polissacarídeos ácidos na parede celular do organismo. Células crescidas em glicose ou Tween 80 exibiram variações citoquímicas em função de sua fase de crescimento. Adicionalmente, o padrão de marcação citoquímica também sofreu variações de acordo com a concentração do surfactante. A influência do surfactante na expressão de carboidratos é discutida.