Kombucha: A review of substrates, regulations, composition, and biological properties.

Kombucha has been gaining prominence around the world and becoming popular due to its good health benefits. This beverage is historically obtained by the tea fermentation of Camellia sinensis and by a biofilm of cellulose containing the symbiotic culture of bacteria and yeast (SCOBY). The other substrates added to the C. sinensis tea have also been reported to help kombucha production. The type as well as the amount of sugar substrate, which is the origin of SCOBY, in addition to time and temperature of fermentation influence the content of organic acids, vitamins, total phenolics, and alcoholic content of kombucha. The route involved in the metabolite biotransformation identified in kombucha so far and the microorganisms involved in the process need to be further studied. Some nutritional properties and benefits related to the beverage have already been reported. Antioxidant and antimicrobial activities and antidiabetic and anticarcinogenic effects are some of the beneficial effects attributed to kombucha. Nevertheless, scientific literature needs clinical studies to evaluate these benefits in human beings. The toxic effects associated with the consumption of kombucha are still unclear, but due to the possibility of adverse reactions occurring, its consumption is contraindicated in infants and pregnant women, children under 4-years-old, patients with kidney failure, and patients with HIV. The regulations in place for kombucha address a number of criteria, mainly for the pH and alcohol content, in order to guarantee the quality and safety of the beverage as well as to ensure transparency of information for consumers.

Catalytic and physical features of a naturally immobilized Yarrowia lipolytica lipase in cell debris (LipImDebri) displaying high thermostability.

Lipase activity (337 U/g dry weight of cell debris) was detected in cell debris after ultrasound treatment of Yarrowia lipolytica cells cultivated in residual frying palm oil. It is a naturally immobilized lipase with protein content of 47%, herein called LipImDebri. This immobilized biocatalyst presents low hydrophobicity (8%), that can be increased adjusting pH and buffer type. Despite apparent intact cells, electron microscopy showed a shapeless and flat surface for LipImDebri and optical microscopy revealed no cell viability. Besides, an inferior mean diameter (3.4 mm) in relation to whole cells reveals structure modification. A high negative zeta potential value (- 33.86 mV) for pH 6 and 25 °C suggests that LipImDebri is a stable suspension in aqueous solution. Fourier Transform Infrared Spectra (FTIR) expose differences between LipImDebri and extracellular lipase extract signaling a physical interaction between enzyme and cell debris, which is possibly the reason for the high thermostability (k d = 0.246 h-1; t 1/2 = 2.82 h at 50 °C, pH 7.0). A good adjustment of LipImDebri kinetic data with Hill equation (R 2 = 0.95) exposes an allosteric behavior related to the presence of more than one lipase isoform. These features reveal that LipImDebri can be a good catalyst for industrial applications.

Green (Detox) juice physicochemical properties and stabilization effect of naturals emulsifiers / Propriedades físico-químicas do suco verde (detox) e efeito de estabilização de emulsificantes naturais

ABSTRACT: Green or "detox" juice is a mixture of fruit juice with vegetables, which has been used intensively by consumers seeking for healthy food. Physicochemical properties of Green juice were accessed in the present research, which brings new insights for the use of this beverage in human diet. A total phenolic content of 2833.60 mg GAE (Gallic acid equivalent)/ g of juice and a Total Antioxidant Capacity by FRAP of 323.62 µM Fe2SO4 / g of juice and by ABTS•+ of 333.11 µM Trolox/ g of juice, indicated good antioxidant properties. Low energy and reducing sugar content indicate its use for low calorie diet, but low carbohydrate and protein content prove that Green juice cannot be used as meal replacement. The addition of a microbial biosurfactant (YlBio) and chia gel as bioemulsifiers was tested in the Green juice formulation to reduce solid decantation and increase consistency. YlBio and chia gel were able to change the Newtonian behavior of the Green juice to a Pseudoplastic behavior due to stabilization properties and also increase consistency, without the need to add synthetic stabilizers.

RESUMO: O suco verde ou "detox" é uma mistura de suco de frutas com vegetais que tem sido intensamente utilizado por consumidores que buscam alimentos saudáveis. As propriedades físico-químicas do suco verde foram avaliadas no presente trabalho, o que traz novas perspectivas para o uso dessa bebida na dieta humana. Um conteúdo fenólico total de 2833,60 mg de EAG (equivalente em ácido gálico) / g de suco) e uma capacidade antioxidante total por FRAP de 323,62 µM de Fe2SO4 / g de suco e por ABTS•+ de 333,11 µM de Trolox / g de suco, indicam boas propriedades antioxidantes. Um baixo teor de energia e açúcar redutor indica seu uso em dietas de baixa caloria, mas o baixo teor de carboidratos e proteínas prova que o suco verde não pode ser usado como substituto de refeição. A adição de um biossurfactante microbiano (YlBio) e do gel de chia no suco foi testada na formulação do suco verde, para reduzir a decantação de sólidos e aumentar a consistência. YlBio e o gel de chia foram capazes de mudar o comportamento do suco de fluido Newtoniano para um fluido pseudoplástico devido às propriedades estabilizantes, e também aumentaram a consistência do suco, sem a necessidade de adição de estabilizantes sintéticos.

Blueberry Residue Encapsulation by Ionotropic Gelation.

In the processing of fruits such as blueberry (Vaccinium sp), that has high levels of phenolic acid, the food industry produces tons of organic waste that causes harm to the environment. Encapsulation is a technique used to take advantage of these wastes. Several methods are used to encapsulate substances, among them ionotropic gelation proves to be a simple, precise, efficient and economical method for obtaining particles with encapsulated bioactives. In this manner, the aim of this study was to test sodium alginate as wall material to encapsulate blueberry residue by ionotropic gelation. The microbeads were characterized by scanning electron microscopy (SEM), x-ray diffraction (XRD), total phenolic compounds, antioxidant capacity and in vitro dissolution. The results showed that the microbeads had surface invagination; retention of 67.01% of the phenolic compounds after encapsulation and 68.2%, phenolic release 120 min after in vitro dissolution. The results suggest that the tested matrix was suitable for encapsulation. The produced microbeads are promising for applications in food products, once the phenolic compounds present in the blueberry residues were maintained after encapsulation.