RESUMO

Ten probiotic cultures were screened for the ability to hydrolyze soy proteins and bile salt deconjugation (BSD) to select one lactobacilli and one bifidobacteria strain to produce fermented soy beverages (FSBs) containing acerola byproduct (ABP). Next, the effect of the strains and the ABP on the technological and sensory characteristics of these beverages was evaluated during refrigerated storage for up to 28 days. None of the tested strains presented any proteolytic activity against soy proteins. Among the probiotic strains, the best BSD activities were observed for Lactobacillus acidophilus LA-5 and Bifidobacterium longum BB-46, which were further employed, individually or combined, to produce FSB supplemented or not with ABP, using Streptococcus thermophilus TH-4 as a starter, and the effect of these strains and ABP on the technological and sensory acceptability of FSB was evaluated. The probiotic strains did not influence FBS texture parameters, but ABP increased firmness in the ready product. BB-46 increased acidity, therefore decreasing acceptance, whereas the presence of LA-5 and/or ABP increased acceptance, even though the appearance was negatively affected by ABP after 21 days of storage. Thus, the presence of LA-5 and ABP contributed for the sensory acceptance of the FSBs without affecting their technological features. PRACTICAL APPLICATION: Lactobacillus acidophilus LA-5, Bifidobacterium longum BB-46, and/or acerola byproduct (ABP) were applied in the production of fermented soy beverages (FSBs). Principal components analysis was used to evaluate the formulations of the 23 factorial design and the sensory attributes and the effect of storage independently and covariance was the matrix type used for mapping purposes. LA-5 and ABP contributed for the sensory acceptance of FSB, without affecting their technological features, and could be used by food processing companies after scaling up, also reducing the environmental impact by decreasing discarding byproducts, which are sources of bioactive compounds.

Assuntos

RESUMO

This study aimed to evaluate the influence of passion fruit by-product (PFBP) and fructooligosaccharides (FOS) on the viability of Streptococcus thermophilus TH-4 and Lactobacillus rhamnosus LGG in folate bio-enriched fermented soy products and their effect on probiotic survival and folate bio-accessibility under in vitro simulated gastrointestinal conditions during storage of the products at 4 °C for up to 28 days (at days 1, 14, and 28). Kinetic parameters and folate contents before and after fermentation were also evaluated. Four different bio-enriched soy products in which the two microorganisms were used in co-cultures were studied and PFBP and/or FOS were added at 1 g/100 g, except for the control product. No differences (p < 0.05) between the fermented soy products (FSP) were observed for the maximum acidification rate (Vmax) and the time to reach the Vmax (Tmax) or pH 5.5 (Tf), indicating that the use of PFBP and/or FOS did not affect the fermentation kinetic parameters. Only Lb. rhamnosus LGG retained the desired viability (>8 log CFU/mL) during storage, whereas St. thermophilus TH-4 populations decreased by day 14 reaching counts between 6.4 and 5.5 log CFU/mL by day 28. The folate content of all FSP increased after fermentation and the simultaneous presence of PFBP and FOS stimulated the co-culture to increase folate production. Folate content in all FSP decreased during storage. Lb. rhamnosus LGG was recovered at the end of the simulated digestion, but PFBP and/or FOS did not affect recovery. The folate content increased during the gastrointestinal assay for all FSP, especially for FSP without supplementation, suggesting an in vitro increase of folate bio-accessibility. Therefore, the bio-enriched probiotic FSP presented a great potential as an innovative functional food by delivering probiotic microorganisms and providing 14% of the recommended daily folate intake. The folate content of the FSP might be increased during gastrointestinal stress conditions, which could contribute to increase the folate bio-accessibility in the gut.

Assuntos

RESUMO

However, folate production was strain-dependent and also dependent on the environmental conditions and on the vegetable substrate used. Passion fruit by-product presented the lowest folate concentration and was selected for the following experiments. Thus, the impact of the supplementation of soymilk with passion fruit by-product and/or commercial prebiotic fructooligosaccharides FOS P95 on the folate production by three St. thermophilus strains, as well as four probiotic Lactobacillus strains (LA-5, LGG, PCC, and RC-14) were evaluated. St. thermophilus ST-M6 and TH-4 produced the highest amounts of folate in all fermented soymilks. The concentration of the vitamin was also high when these strains grew in co-culture with LA-5 and LGG. Soymilk supplemented with both passion fruit by-product and FOS together presented the highest concentration of folate when fermented by the co-culture TH-4+LGG. This co-culture was selected to produce four fermented soy products (FSP). All FSP were bio-enriched with folate produced by the co-culture and the probiotic strain LGG remained always above 8 log CFU/mL until the end of the storage period (28 days at 4ºC). In contrast, the concentration of the vitamin was stable until day 14 then a slight decrease was observed at the end of the storage period. The FSP supplemented with both passion fruit by-product and FOS together may contribute with around 14% of the recommended daily intake for folate if consumed until day 14 of storage. During the in vitro simulated gastrointestinal conditions, the folate content of the digested FSP increased from 1.3 to 3.6-fold, especially at the small and large intestinal in vitro phases and the strain LGG was recovered. In contrast, St. thermophilus TH-4 was not recovered during the assay. Finally, the prebiotic potential of the bioactive compounds present in the fruit by-products was characterized. Fruit by-product water extracts (FWE) containing soluble fibres from fruit by-products were obtained through a hot-water extraction and were associated to phenolic compounds and showed antioxidant activity. The FWE (especially, orange and mango water extracts) presented an anti-inflammatory potential by decreasing the nitric oxide concentration produced in vitro by macrophages stimulated with lipopolisaccharides (LPS) from Salmonella Thyphymurium. The FWE (especially from mango) were able to stimulate the growth of the strains TH-4 and LGG, as well the folate production by these microorganisms when tested individually and in co-culture. The FWE also increased the adhesion of TH-4 and LGG to Caco-2 cells in an in vitro model. These results suggest a prebiotic potential of the fruit by-products evaluated and their potential towards increased folate production by the selected microorganisms. Therefore, the bio-enrichment of fermented soy products with folate produced by beneficial microorganisms is an alternative for the development of functional foods with high folate content. Additionally, fermentable bioactive compounds with functional and/or biological activity, such as soluble fibres associated to phenolic compounds with antioxidant activity, present in the fruit by-products, may act as potential prebiotic ingredients. These bioactive molecules may represent a potential natural alternative to synthetic drugs for the treatment of inflammatory processes

O objetivo deste trabalho foi avaliar o efeito de subprodutos vegetais, incluindo subprodutos do processamento de fruta (maracujá, laranja, acerola e manga) e de soja (okara) na produção de folatos de novo por microrganismos strater e probióticos para bioenriquecer um produto de soja fermentado. Na primeira etapa deste trabalho, o impacto da farinha de amaranto na produção de folatos pelos microrganismos também foi avaliado. Neste sentido, primeiramente, verificou-se o efeito desses subprodutos vegetais e da farinha de amaranto na capacidade de três cepas starter - Streptococcus thermophilus (ST-M6, TH-4 e TA-40) e 10 cepas probióticas (Lactobacillus (Lb.) acidophilus LA-5, Lb. fermentum PCC, Lb. reuteri RC-14, Lb. paracasei subsp. paracasei Lb. casei 431, Lb. paracasei subsp. paracasei F19, Lb. rhamnosus GR-1, and Lb. rhamnosus LGG, Bifidobacterium (B.) animalis subsp. lactis BB-12, B. longum subsp. longum BB-46, e B. longum subsp. infantis BB-02) em produzir folato utilizando um caldo MRS modificado. A maior parte dos microrganismos testados foi capaz de produzir folato. Entretanto, a produção foi considerada cepa-dependente e, também, dependente das condições ambientais e do tipo de subproduto vegetal empregado. O subproduto de maracujá apresentou a menor concentração de folato e, por isso, foi selecionado para os testes seguintes. Neste sentido, o impacto da suplementação do leite de soja com subproduto de maracujá e/ou com o prebiótico comercial fruto-oligosacarídeo FOS P95 na produção de folato pelas três cepas de St. thermophilus, bem como quarto cepas probióticas do gênero Lactobacillus (LA-5, LGG, PCC e RC-14), também foi avaliado. Em cultura pura, as cepas de St. thermophilus ST-M6 e TH-4 produziram grande quantidade de folato nas formulações de extrato de soja fermentados. A concentração da vitamina foi maior quando tais cepas se desenvolveram em co-cultura com LA-5 e LGG. Observou-se que o extrato de soja suplementado concomitantemente com subproduto de maracujá e FOS apresentou a maior quantidade de folato quando fermentado pela co-cultura TH-4+LGG. Esta co-cultura, portanto, foi selecionada para desenvolver os produtos fermentados de soja (PFS). Todas as formulações foram bioenriquecidas e a cepa LGG manteve-se viável por todo o período de armazenamento (28 dias a 4ºC). Entretanto, a concentração da vitamina manteve-se estável apenas até o dia 14, observando-se uma diminuição da quantidade de folato ao final do período de armazenamento. Constatou-se que o produto fermentado de soja suplementado concomitantemente com subproduto de maracujá e FOS pode contribuir com cerca de 14% da ingestão diária recomendada para folato se consumido até o dia 14 do armazenamento. Além disso, durante a simulação gastrointestinal in vitro, observou-se que a digestão aumentou de 1,3 a 3,6 vezes a concentração da vitamina incrementando, consideravelmente, a bioacessibilidade do folato, principalmente nas porções simuladas do intestino delgado e grosso do intestino e a cepa LGG foi recuperada. Entretanto, a cepa St. thermophilus TH-4 não foi recuperada durante o ensaio. Por fim, o potencial prebiótico de componentes bioativos presentes nos subprodutos de fruta foi caracterizado. Uma extração Hot Water foi conduzida, a fim de obter extratos aquosos de subprodutos de fruta ricos em fibras solúveis associadas a compostos fenólicos com atividade antioxidante. Observou-se, ainda, que tais extratos aquosos de subprodutos de fruta (laranja e manga) apresentaram potencial anti-inflamatório constatado pela diminuição da concentração de óxido nítrico produzido por macrófagos estimulados com lipopolissacarideo (LPS) de Salmonella Typhymurium in vitro. Além disso, os extratos aquosos de subprodutos de fruta (principalmente o extrato aquoso de subproduto de manga) foram capazes de estimular a multiplicação das cepas TH-4 e LGG, bem como a produção de folatos por estes microrganismos quando avaliados individualmente e em co-cultura. Adicionalmente, esses extratos aquosos de subprodutos de fruta aumentaram a adesao do TH-4 e do LGG a células Caco-2 em modelo in vitro. Neste sentido, os resultados sugerem um potencial prebiótico dos subprodutos de fruta testados, de modo a estimular, não somente o desenvolvimento dos microrganismos avaliados mas, principalmente, o potencial destes em produzir folatos na presença dos substratos vegetais testados. O bioenriquecimento dos produtos fermentados de soja com folatos produzidos por microrganismos benéficos emerge como alternativa de alimento potencialmente funcional com alto teor de folato. Adicionalmente, compostos bioativos fermentescíveis e com atividade biológica como, por exemplo, as fibras solúveis associadas a compostos fenólicos com atividade antioxidante, presentes nos subprodutos de fruta testados podem constituir potenciais ingredientes prebióticos, além de representarem uma possível alternativa natural para o tratamento de processos inflamatórios

Assuntos

RESUMO

Two starter cultures (Streptococcus (St.) thermophilus ST-M6 and TA-40) and five probiotic strains (St. thermophilus TH-4, Lactobacillus (Lb.) acidophilus LA-5, Lb. rhamnosus LGG, Lb. fermentum PCC, and Lb. reuteri RC-14) were used to ferment different soymilk formulations supplemented with passion fruit by-product and/or fructo-oligosaccharides (FOS) with the aim of increasing folate concentrations. Growth and folate production of individual strains were evaluated and the results used to select co-cultures. Both St. thermophilus ST-M6 and TH-4 were the best folate producers and were able to increase the folate content of all soymilk formulations when used alone or in co-culture with lactobacilli strains, especially in the presence of both passion fruit by-product and FOS. Thus, passion fruit by-product and FOS could be used as dietary ingredients to stimulate the folate production by selected bacterial strains during the fermentation of soymilk. It was also shown that vitamin production by microorganisms is strain-dependent and may also be influenced by nutritional and environmental conditions.

Assuntos

RESUMO

The ability of two starter cultures (Streptococcus (S.) thermophilus ST-M6 and St. thermophilus TA-40) and eleven probiotic cultures (St. thermophilus TH-4, Lactobacillus (Lb.) acidophilus LA-5, Lb. fermentum PCC, Lb. reuteri RC-14, Lb. paracasei subsp. paracasei, Lb. casei 431, Lb. paracasei subsp. paracasei F19, Lb. rhamnosus GR-1, and Lb. rhamnosus LGG, Bifidobacterium (B.) animalis subsp. lactis BB-12, B. longum subsp. longum BB-46, and B. longum subsp. infantis BB-02) to produce folate in a modified MRS broth (mMRS) supplemented with different fruit (passion fruit, acerola, orange, and mango) and okara soybean by-products and amaranth flour was investigated. Initially, the folate content of each vegetable substrate was determined: passion fruit by-product showed the lowest folate content (8±2ng/mL) and okara the highest (457±22ng/mL). When the orange by-product and amaranth flour were added to mMRS, all strains were able to increase folate production after 24h of fermentation. B. longum subsp infantis BB-02 produced the highest concentrations (1223±116ng/mL) in amaranth flour. Okara was the substrate that had the lowest impact on the folate production by all strains evaluated. Lb. acidophilus LA-5 (297±36ng/mL) and B. animalis subsp. lactis BB-12 (237±23ng/mL) were also able to produce folate after growth in mMRS containing acerola and orange by-products, respectively. The results of this study demonstrate that folate production is not only strain-dependent but also influenced by the addition of different substrates in the growth media.

Assuntos