Modification of Antibiotic Activity by Fixed Oil of the Artocarpus heterophyllus Almond against Standard and Multidrug-Resistant Bacteria Strains.

Artocarpus heterophyllus (jackfruit) is an evergreen tree distributed in tropical regions and is among the most studied species of the genus Artocarpus. The jackfruit almond has been highlighted in relation to phytochemical studies, biological properties, and application in the development of food products. This study aimed to analyze jackfruit fixed oil regarding chemical components, antibacterial property alone, and in association with antibiotics against standard and MDR bacteria strains. In the analysis of the oil by gas chromatography coupled to a flame ionization detector (GC-FID), a high content of saturated fatty acids (78.51%) was identified in relation to unsaturated fatty acids (17.07%). The main fatty acids identified were lauric acid (43.01%), myristic acid (11.10%), palmitic acid (6.95%), and oleic acid (15.32%). In the antibacterial analysis, broth microdilution assays were used. The oil presented minimum inhibitory concentration (MIC) ≥ 1024 µg/mL in antibacterial analysis for standard and MDR bacterial strains. The oil showed synergistic effects in the association with gentamicin, ofloxacin, and penicillin against MDR strains, with significant reductions in the MIC of antibiotics. The results suggest that the fixed oil of A. heterophyllus has fatty acids with the potential to synergistically modify antibiotic activity.

Synbiotic Amazonian palm berry (açai, Euterpe oleracea Mart.) ice cream improved Lactobacillus rhamnosus GG survival to simulated gastrointestinal stress.

The effect of açai pulp ice cream and of its supplementation with inulin (I), whey protein concentrate (WC), and/or whey protein isolate (WI) on the viability and resistance to simulated gastrointestinal stress of the probiotic Lactobacillus (Lb.) rhamnosus GG strain throughout storage at -18 °C for up to 112 days was evaluated and morphological changes during stress were monitored. Lb. rhamnosus GG viability was stable in all formulations for up to 112 days of storage, preserving populations around 9 log CFU g-1. Compared to the fresh culture, Lb. rhamnosus GG showed higher survival under simulated gastrointestinal conditions when incorporated into açai ice cream, indicating that the presence of the food matrix contributed to the microorganism survival. A reduction of at least 5 log cycles of Lb. rhamnosus GG was observed in all formulations after the gastrointestinal simulation in all storage periods assessed. The addition of I, WC, and/or WI did not show any significant effect on the probiotic survival under simulated gastrointestinal stress (p < 0.05). Compared to the fresh culture, fewer morphological changes were observed when the probiotic was added to ice cream. Thus, the açai pulp ice cream was shown to be a suitable matrix for Lb. rhamnosus GG, improving its survival under in vitro simulated gastrointestinal conditions.

A prebiotic mixture improved Lactobacillus acidophilus and Bifidobacterium animalis gastrointestinal in vitro resistance in petit-suisse.

The survival of two probiotic strains -Lactobacillus acidophilus La-5 and Bifidobacterium animalis Bb-12 - incorporated into probiotic (PC) and into synbiotic (SC, with inulin + fructooligosaccharides, respectively, at 7.5 and at 2.5 g per 100 g) petit-suisse cheese was investigated in the beginning (day 1) and at the end (28 days) of storage at 4 °C when the food products were subjected to in vitro gastrointestinal simulated assays. Species-specific quantitative real time PCR (qPCR) combined with propidium monoazide (PMA-qPCR) was employed to quantify the strains. Initial La-5 and Bb-12 populations were always above 7 log CFU g(-1). The presence of the prebiotic ingredients in SC improved the Bb-12 and La-5 resistance after the 6 h assay, with higher populations in all the in vitro stages and throughout the storage period (p < 0.05), leading to equal or superior survival rates (SR) in SC of both probiotic strains, in the beginning as well as at the end of storage. The mean La-5 SR were 58% (PC) and 67% (SC), whereas the mean Bb-12 SR were 60% (PC) and 79% (SC). Our findings suggest that the addition of a prebiotic mixture in petit-suisse cheese was advantageous, since it improved both the Bb-12 and La-5 viability and tolerance under in vitro gastrointestinal simulated conditions, both in the fresh product and in the product refrigerated for 28 days.

Desenvolvimento de sorvete simbiótico de açaí (Euterpe oleracea) com Lactobacillus rhamnosus GG e resistência do probiótico em um modelo de digestão gastrintestinal in vitro / Development of synbiotic açaí (Euterpe oleracea Mart. ) ice cream with Lactobacillus rhamnosus GG and probiotic resistance in an in vitro digestion gastrointestinal model

O objetivo do presente trabalho foi avaliar o efeito da adição de inulina (I-X1), concentrado proteico de soro de leite (WC-X2) e/ou isolado proteico de soro de leite (WI-X3) em sorvete simbiótico de açaí (Euterpe oleracea Mart.) sobre a viabilidade do probiótico L. rhamnosus GG e a sua sobrevivência frente às condições encontradas no trato gastrintestinal simuladas in vitro, bem como sobre as características tecnológicas e a aceitabilidade sensorial dos produtos resultantes, ao longo de seu armazenamento a -18°C por até 112 dias. Adicionalmente, os sorvetes de açaí foram caracterizados quanto à sua composição centesimal, ácidos graxos insaturados e potencial antioxidante. Por último, objetivou-se a otimização do sorvete simbiótico de açaí a partir dos parâmetros de dureza instrumental e fração de derretimento. Para este fim, foi empregado um delineamento experimental para misturas simples (centroid simplex) incluindo um ponto axial, utilizando diferentes proporções dos fatores X1, X2 e X3. No total, 9 formulações foram avaliadas por um período de até 112 dias de armazenamento congelado. As populações de L. rhamnosus GG permaneceram estáveis e entre 8 e 9 log ufc/g para todas as formulações e ao longo de todo o período de armazenamento. Entretanto, houve redução em, pelo menos, 5 ciclos logaritmos da população do probiótico, após 6 horas de simulação gastrintestinal em todos os períodos estudados, com uma recuperação de L. rhamnosus GG próxima a 4 log ufc/g. Apenas ao 7º dia de armazenamento, a resistência in vitro do probiótico nas formulações contendo inulina, WC e WI superou em até 0,93 log ufc/g a formulação controle. A composição de ácidos graxos revelou que o ácido oleico esteve em maior quantidade nas formulações (teor médio 46,47%), seguido do ácido palmitoleico (teor médio 42,12%). Os sorvetes apresentaram atividade antioxidante na faixa de 302,03 a 505,41 µmol TE/g. A maior atividade antioxidante foi observada para a formulação controle, seguida das formulações WC (4% de WC) e WI (4% de WI). As formulações WC (4% WC) e WI (4% WI) apresentaram os maiores valores de dureza, revelando que os fatores WC e WI exerceram forte influência na dureza dos produtos (p<0,05). As menores taxas de derretimento foram observadas nas formulações WI (4% de WI) e WC-WI (2% de WC; 2% de WI). Exceto para a formulação I-WC-WI (p<0,05), a presença de inulina nas demais formulações não alterou de forma significativa a velocidade de derretimento quando comprada à amostra controle. As formulações I-WI (2% de inulina; 2% de WI) e I-WC-WI (1,33% de inulina; 1,33% WC; 1,33 WI), apresentaram os maiores valores de overrun (37,95% e 39,18%, respectivamente). Os escores de aceitabilidade sensorial variaram de 5,83 a 7,63. Apenas as formulações WI (4% WI) e WC-WI (2% WC; 2% WI) aumentaram seus escores médios de aceitabilidade durante os 84 dias de armazenamento (p<0,05). De acordo com os modelos obtidos, WC foi o fator que mais contribuiu tanto para o aumento de dureza como para a velocidade de derretimento das formulações. A partir da otimização simultânea, considerando as respostas avaliadas (textura e fração de derretimento), é desejável que a formulação de sorvete simbiótico açaí seja produzida contendo 1,33% de inulina, 1,33% de WC e 1,33% de WI. Os resultados obtidos sugerem que a utilização dos três ingredientes (inulina, WC e WI) pode ser vantajosa no desenvolvimento de um sorvete probiótico de açaí, uma vez que a presença desses ingredientes contribuiu com o valor nutricional das formulações e também melhorou as características tecnológicas de overrun, derretimento e textura

The aimed of the present study was to evaluate the effect of inulin (I-X1), whey protein concentrate (WC-X2) and whey protein isolate (WI-X3) addition on the viability and in vitro survival of L. rhamnosus GG through in vitro simulated gastrointestinal tract (GIT), technological properties and sensory acceptance of symbiotic açai ice cream. Additionally, açai ice cream were characterized for their chemical composition, unsaturated fatty acids and antioxidant activity. Finally, we aimed to optimized the symbiotic açai ice cream using parameters of hardness and melting rate. For this purpose, an experimental design was used for simple mixture (simplex centroid) including an axial point, using different proportions of X1, X2 and X3, nine formulations of synbiotic açai ice cream were studied during frozen storage up to 112 days. A reduction of at least 5 log cycles of L. rhamnosus GG was observed in all formulations after 6 hours of the in vitro assays for all storage period evaluated. However, L. rhamnosus GG recovery was close to 4 log cfu/g for all formulations studied in evaluated periods. Nevertheless, on the 7th day of storage, the probiotic in vitro resistance in formulations supplemented with inulin, WC, and WI exceeded up to 0.93 log cfu/g the control formulation. The fatty acids composition showed that oleic acid was the highest fatty acid in synbiotic açai ice cream (mean content 46.47%), followed by palmitoleic acid (mean content 42.12%). The antioxidant activity of ice creams ranged from 302.03 to 505.41 µmol TE/g. Formulation C showed the highest antioxidant activity, followed by the formulations WC (WC 4%) and WI (WI 4%). Formulations WC (4% of WC) and WI (4% of WI) showed the highest hardness values, revealing that WC and WI exerted a strong influence on the product firmness. The lowest melting rate values were observed in formulation WI (4% of WI) and WC-WI (2% of WC, 2% of WI). However, the presence of inulin and WC showed strong influence on the melting rate of the ice creams, resulting in higher melting down of these products. I-WI and I-WC-WI formulations presented the highest overrun (37.95 and 39.18%, respectively). The sensory acceptability scores ranged from 5.83 to 7.63. WI and WC-WI formulations increased their mean acceptability scores significantly during 84 days of storage, whereas no significant differences were observed in acceptability throughout storage for the other formulations. According to the obtained models, WC was the factor that most contributed to increase both hardness and melting rate. From the simultaneous optimization, considering the responses evaluated (hardness and melting rate), it is desirable a symbiotic acai ice cream containing 1.33% of inulin, 1.33% of WC and 1.33% of WI. The results suggest that the use of the three ingredients (inulin, WC and WI) may be advantageous in the development of a synbiotic açai ice cream, since the presence of these ingredients contributed to the nutritional value of the formulations and also improved the technological characteristics of overrun, melting rate and texture

Sonicated pineapple juice as substrate for L. casei cultivation for probiotic beverage development: process optimisation and product stability.

The aim of this study was to evaluate the use of sonicated pineapple juice as substrate for producing a probiotic beverage by Lactobacillus casei NRRL B442. Maximal microbial viability was found by cultivating L. casei at 31°C and pH 5.8 (optimised conditions). After fermentation, samples of sweetened and non-sweetened juice were stored. After 42 days of storage under refrigeration (4°C), the microbial viability was 6.03 Log CFU/mL in the non-sweetened sample and 4.77 Log CFU/mL in the sweetened sample. The pH of both samples decreased during storage due to lactic acid production (post acidification). The characteristic colour of the juice was maintained throughout the shelf life and no browning was observed. Sonicated pineapple juice was shown to be a suitable substrate for L. casei cultivation and for the development of an alternative non-dairy probiotic beverage.