Cultivos lácticos como potenciadores de compuestos bioactivos de avena / Lactic starter cultures to improve the oat bioactive compounds

RESUMEN El objetivo de este trabajo fue estudiar la fermentación láctica como bioestrategia para potenciar la actividad antioxidante de la avena. Se evaluó la capacidad de 31 cepas de bacterias lácticas (BL) para adaptarse a un sistema de avena/agua (SAA) mediante la determinación del crecimiento, la acidificación y la actividad fermentativa (método impedimétrico; tiempo de detección [DT], velocidad máxima de cambio de conductabilidad [VMCC] y porcentaje de cambio de conductabilidad [PCC]). Además, se determinó el contenido de compuestos fenólicos (CF) mediante el método de Folin-Ciocalteu (equivalentes de ácido gálico [EAG]), así como de péptidos, de aminoácidos libres y de actividad antirradicalaria (métodos DPPH•y ABTS•+) de los extractos metanólicos y acuosos obtenidos a partir de los SAA fermentados (SAAf). Seis cepas mostraron la mejor adaptabilidad al SAA y produjeron altos valores de VMCC (0,34-0,47 μS/min) y PCC (53,6-66,6%), con bajos valores de DT (≤ 3 h). Estos cambios fueron acompañados por modificaciones en la concentración de CF, péptidos y aminoácidos libres, los cuales fueron dependientes de la cepa. Se evidenció un incremento de la concentración de CF en los SAAf de las seis cepas (29,1-39,85 μg EAG/ml) con respecto al SAA control (17,1 μg EAG/ml). Además, hubo un incremento (9-25,5%) en la actividad antioxidante de los extractos metanólicos de SAAf medida por ambos métodos. Respecto del contenido en péptidos/aminoácidos libres de los SAAf y de su actividad antioxidante, se encontraron modificaciones de menor magnitud. Los resultados muestran que las BL son capaces de adaptarse a la avena como sustrato de fermentación e incrementar su contenido de compuestos antioxidantes.

ABSTRACT The objective of this work was to study lactic fermentation as a biostrategy to enhance the antioxidant activity of oats. The adaptability of 31 strains of lactic bacteria (LB) in an oats/water system (OWS/SAA) was evaluated, measuring growth, acidification and fermentation activity (impedimetric method; detection time [DT], maximum rate of conductance change [MRCC/VMCC] and percentage of conductance change [PCC]). Moreover, the content of phenolic compounds (PC) was determined using the Folin-Ciocalteu method (gallic acid equivalents [GAE]), free peptides and amino acids and free radical scavenging activity (DPPH•and ABTS•+methods) of methanolic and aqueous extracts obtained from fermented OWS/SAAs (fOWS/SAAf) were determined. Six strains have shown the best adaptability to SAA, with high values of VMCC (0.34-0.47 μS/min) and PCC (53.6-66.6%), and low values of DT (≤ 3 h). In these f/OWS/SAAf the chemical composition was also modified (PC concentration, peptides and free amino acids) with strain-dependent behavior. The PC content in f/OWS/SAAf using these six strains (29.1-36.9 μg GAE/ml) was higher than the control content in OWS/SAA control (17.1 ± 1.9 μg GAE/ml). An increase (9-25.5%) in antioxidant activity in f/OWS/SAAf methanolic extracts was detected using both methods. Minor modifications were observed in the peptide and free amino acid content of SAA and their antioxidant activity. Our results show LB ability to adapt to oat as fermentation substrate and increase the content of its antioxidant compounds.

[Lactic starter cultures to improve the oat bioactive compounds]. / Cultivos lácticos como potenciadores de compuestos bioactivos de avena.

The objective of this work was to study lactic fermentation as a biostrategy to enhance the antioxidant activity of oats. The adaptability of 31 strains of lactic bacteria (LB) in an oats/water system (OWS/SAA) was evaluated, measuring growth, acidification and fermentation activity (impedimetric method; detection time [DT], maximum rate of conductance change [MRCC/VMCC] and percentage of conductance change [PCC]). Moreover, the content of phenolic compounds (PC) was determined using the Folin-Ciocalteu method (gallic acid equivalents [GAE]), free peptides and amino acids and free radical scavenging activity (DPPH• and ABTS•+ methods) of methanolic and aqueous extracts obtained from fermented OWS/SAAs (fOWS/SAAf) were determined. Six strains have shown the best adaptability to SAA, with high values of VMCC (0.34-0.47 µS/min) and PCC (53.6-66.6%), and low values of DT (≤ 3 h). In these f/OWS/SAAf the chemical composition was also modified (PC concentration, peptides and free amino acids) with strain-dependent behavior. The PC content in f/OWS/SAAf using these six strains (29.1-36.9 µg GAE/ml) was higher than the control content in OWS/SAA control (17.1 ± 1.9 µg GAE/ml). An increase (9-25.5%) in antioxidant activity in f/OWS/SAAf methanolic extracts was detected using both methods. Minor modifications were observed in the peptide and free amino acid content of SAA and their antioxidant activity. Our results show LB ability to adapt to oat as fermentation substrate and increase the content of its antioxidant compounds.

Efecto antifúngico y antimicotoxigénico de Lactobacillus plantarum CRL 778 a diferentes valores de actividad de agua / Antifungal and antimycotoxigenic effect of Lactobacillus plantarum CRL 778 at different water activity values

Ochratoxin A (OTA) is a mycotoxin produced by filamentous fungi with high impact Lactic acid bacteria; in food safety due to its toxicity. In the last decade, the presence of OTA was widely reported in different foods. In this study, the ability of Lactobacillus (L.) plantarum CRL 778 to control growth and OTA production by Aspergillus (A.) niger 13D strain, at different water activity (a w) values (0.955, 0.964, 0.971, 0.982, and 0.995) was determined in vitro. Both parame ters were significantly (p<0.05) reduced by the lactobacilli and the effect depended on a w. Greatest growth rate inhibition (46.9%) was obtained at a w = 0.995, which is the most suitable value for growth and production of antifungal metabolites (lactic acid, acetic acid, phenyllac-tic and hydroxyl-phenyllactic acids) by L. plantarum CRL 778. Besides, morphological changes and inhibition of melanin synthesis were observed in colonies of A. niger 13D in presence of L. plantarum CRL 778 at a w ranged between 0.971 and 0.995. In addition, maximum reduction (90%) of OTA production took place at a w = 0.971, while inhibition of fungi growth was more evident at a w =0.995. These findings suggest that L. plantarum CRL 778 could be used for control of ochratoxigenic fungal growth and OTA contamination in different fermented foods with a w values between 0.971 and 0.995.

Ocratoxina A (OTA) es una micotoxina producida por hongos filamentosos con un alto impacto en la seguridad alimentaria debido a su toxicidad. En la última década se ha reportado ampliamente a nivel mundial, la presencia de OTA en diversos alimentos. En este estudio se evaluó in vitro, la capacidad de Lactobacillus (L.) plantarum CRL 778 de controlar el crecimiento y la producción de OTA por Aspergillus (A.) niger 13D, a diferentes valores de actividad de agua (a w): 0.955, 0.964, 0.971,0.982 y 0.995). La cepa láctica redujo significativamente (p <0.05) ambos parámetros, siendo el efecto dependiente del valor de a w. La mayor inhibición del crecimiento (46.9%) se obtuvo a a w =0.995, valor más adecuado para el crecimiento y producción de metabolitos antifúngicos (ácido láctico, ácido acético, ácidos fenil-láctico e hidroxi-fenil láctico) por la cepa láctica. Además, se observaron cambios morfológicos en las colonias de A. niger 13D, crecidas en presencia de L. plantarum CRL 778 a valores de a w de 0.971 y 0.995. El porcentaje máximo de reducción en la producción de OTA (90%) por la cepa láctica se observó a un valor de a w = 0.971, mientras la inhibición del crecimiento fúngico fue mayor cuando a w = 0.995. Estos hallazgos sugieren que L. plantarum CRL 778 podría emplearse para el control de la contaminación por hongos ocratoxigénicos en alimentos con valores de aw comprendidos entre 0.971-0.995.

Antifungal and antimycotoxigenic effect of Lactobacillus plantarum CRL 778 at different water activity values.

Ochratoxin A (OTA) is a mycotoxin produced by filamentous fungi with high impact in food safety due to its toxicity. In the last decade, the presence of OTA was widely reported in different foods. In this study, the ability of Lactobacillus (L.) plantarum CRL 778 to control growth and OTA production by Aspergillus (A.) niger 13D strain, at different water activity (aw) values (0.955, 0.964, 0.971, 0.982, and 0.995) was determined in vitro. Both parameters were significantly (p<0.05) reduced by the lactobacilli and the effect depended on aw. Greatest growth rate inhibition (46.9%) was obtained at aw=0.995, which is the most suitable value for growth and production of antifungal metabolites (lactic acid, acetic acid, phenyllactic and hydroxyl-phenyllactic acids) by L. plantarum CRL 778. Besides, morphological changes and inhibition of melanin synthesis were observed in colonies of A. niger 13D in presence of L. plantarum CRL 778 at aw ranged between 0.971 and 0.995. In addition, maximum reduction (90%) of OTA production took place at aw=0.971, while inhibition of fungi growth was more evident at aw=0.995. These findings suggest that L. plantarum CRL 778 could be used for control of ochratoxigenic fungal growth and OTA contamination in different fermented foods with aw values between 0.971 and 0.995.

Lactic Acid Fermentation Improved Textural Behaviour, Phenolic Compounds and Antioxidant Activity of Chia (Salvia hispanica L.) Dough.

In this work, autochthonous lactic acid bacteria (LAB) were isolated from chia (Salvia hispanica L.) dough and selected on the basis of the kinetics of acidification and proteolytic activity. Strain no. C8, identified as Lactobacillus plantarum C8, was selected and used as starter to obtain chia sourdough. Lactic acid fermentation increased the organic acid mass fractions (lactic, acetic and phenyl lactic acids to 12.3 g, 1.0 g and 23.8 µg per kg of dough respectively), and antioxidant activities, which increased by approx. 33-40% compared to unfermented chia flour dough. In addition, total phenolic content increased 25% and its composition was strongly modified after 24 h of fermentation by L. plantarum C8. Chlorogenic acid was only found in the fermented dough (2.5 mg/g), while ferulic acid was detected from the beginning of fermentation, being 32% higher in chia sourdough (5.6 mg/g). The use of fermented chia sourdough improved the overall characteristics of white bread, including physical (e.g. reduced hardness and chewiness of the crumb) and antioxidant properties (25% on average), compared to the white bread. These results indicate that the use of chia sourdough could be a promising alternative to improve the technological and antioxidant properties of wheat bread. In addition, this work has shown, for the first time, that lactic acid bacterium is able to ferment chia dough, improving its overall characteristics.

A combination of two lactic acid bacteria improves the hydrolysis of gliadin during wheat dough fermentation.

The evaluation of gliadin hydrolysis during dough fermentation by using two lactic acid bacteria, Lactobacillus plantarum CRL 775 and Pediococcus pentosaceus CRL 792, as pooled cell suspension (LAB) or cell free extract (CFE) was undertaken. The CFE pool produced a greater (121%) increase in amino acid concentration than the LAB pool (70-80%). These results were correlated with the decrease (76,100 and 64,300 ppm) in the gliadin concentration of doughs supplemented with CFE and LAB, respectively, compared to control doughs. The use of LAB peptidases seemed to be a viable technologic alternative to reduce the gliadin concentration in wheat dough without using living bacteria as starter.