Utilização de bagaço de maçã como ingrediente alimentar em iogurte com potencial efeito benéfico para a saúde

O desenvolvimento de alimentos funcionais evoluiu consideravelmente ao longo dos anos e a capacidade tecnológica para produzir um alimento com compostos fisiologicamente ativos tem crescido significativamente. O presente trabalho teve como objetivo criar um novo alimento, utilizando um subproduto proveniente da indústria agroalimentar. O alimento seleccionado foi o iogurte natural, o qual foi enriquecido com um extrato de bagaço de maçã. O bagaço de maçã contém compostos fenólicos e fibra, mostrando atividade antioxidante significativa e por conseguinte apresenta um potencial efeito positivo na saúde. Avaliaram-se características químicas do bagaço de maçã e das farinhas obtidas a partir deste subproduto, designadamente: acidez, teor em açúcares totais e redutores, cinza, matéria gorda, humidade, proteína bruta, fibra dietética insolúvel e solúvel. O extrato aquoso obtido a partir do subproduto foi também caracterizado quanto ao seu conteúdo fenólico e atividade antioxidante. O iogurte produzido com incorporação do extrato de bagaço de maçã foi estudado do ponto de vista de parâmetros químicos tais como acidez, açúcares totais, cinza, humidade, proteína bruta, pH e fibra bruta, conteúdo em fenólicos totais e atividade antioxidante. O subproduto, os extratos e o iogurte foram também avaliados quanto à sua carga microbiológica. Na caracterização química do bagaço foram obtidos os seguintes valores, expressos em base seca: 2,0±0,01% de acidez (expressa em equivalentes de ácido málico); 15,96±1,53% de açúcares totais; 13,35±1,91% de açúcares redutores; 1,88±0,07% de cinza, 2,49±0,5% de matéria gorda, 81,17±1,98% de humidade e 5,01±0,01% de proteína bruta. Quanto ao seu conteúdo em fibra dietética, o bagaço contém na sua composição 65,80% de fibra dietética insolúvel e 4,90% de fibra dietética solúvel. A farinha obtida após secagem a 60 °C do bagaço de maçã apresentou, na base seca, 1,9±0,04% de acidez, 10,57±1,31% de açúcares totais; 8,50±1,00% de açúcares redutores; 2,22±0,04%de cinza, 4,73±0,11% de matéria gorda, 6,34±0,62% de humidade e 5,40±0,26% de proteína. A atividade antioxidante do extrato aquoso, (AQ_6X10) obtido do bagaço de maçã, utilizado para incorporação no iogurte, determinada através do método ABTS foi de 5,00±1,28µmol TE/g amostra e apresentou um teor em compostos fenólicos de 221,42±0,734 mg EAG/ 100g de extrato, na base seca. Ao nível microbiológico o extrato revelou parâmetros aceitáveis, de acordo com a tabela 13 (anexos 3), para utilização como ingrediente alimentar. Os iogurtes produzidos foram analisados quimicamente. O iogurte, com extrato aquoso de bagaço de maçã incorporado, apresentou 89,64±0,00% de humidade, 0,93±0,00% de acidez (expressa em equivalentes de ácido láctico); 6,42±0,26% de açúcares totais; 0,74%±0,00% de cinza, 3,83±0,00% de proteína bruta e 0,2±0,00% de fibra bruta. O seu conteúdo em compostos fenólicos foi de 12,41±1,69mg EAG/ 100g de iogurte, e a sua atividade antioxidante foi 54,84±4,40 µmol TE/g iogurte. Avaliou-se ainda o iogurte no que diz respeito ao crescimento de bactérias lácticas e constatou-se, por comparação com o iogurte de controlo, que estas se desenvolveram normalmente ao longo do processo de fabrico. A análise microbiológica revelou ainda que o iogurte é seguro do ponto de vista alimentar de acordo com a Tabela 15 (anexos 3). A análise sensorial realizada aos iogurtes demonstrou que o iogurte fortificado apresentou uma aceitação muito boa pelo painel de provadores. O presente estudo demonstrou que o bagaço de maçã, um subproduto das indústrias agroalimentares, é seguro do ponto de vista microbiológico, podendo ser utilizado na preparação de ingredientes alimentares para serem incorporados, por exemplo em iogurte, conferindo-lhe características que se destacam pelo maior teor em fibra e atividade antioxidante em relação ao iogurte não enriquecido, e atributos sensoriais apelativos em termos de textura e sabor.

Fiber, a component for health gastrointestinal endocrine system

Dietary fiber was classified according to its solubility in an attempt to relate physiological effects to chemical types of fiber. Soluble fibers (B-glucans, gums, wheat dextrin, psyllium, pectin, inulin) were considered to have benefits on serum lipids, while insoluble fibers (cellulose, lignin, pectins, hemicelluloses) were linked with laxation benefits. More important characteristics of fiber in terms of physiological benefits are viscosity and fermentability. Viscous fibers (pectins, B-glucans, gums, psyllium) are those that have gel-forming properties in the intestinal tract, and fermentable fibers (wheat dextrin, pectins, B-glucans, gum, inulin) are those that can be metabolized by colonic bacteria. Objective: To summarize the beneficial effects of dietary fiber, as nutraceuticals, in order to maintain a healthy gastrointestinal system. Methods: Our study is a systematic review. Electronic databases, including PubMed, Medline, with supplement of relevant websites, were searched. We included randomized and non-randomized clinical trials, epidemiological studies (cohort and case-control). We excluded case series, case reports, in vitro and animal studies. Results: The WHO, the U.S. Food and Drug Administration (FDA), the Heart Foundation and the Romanian Dietary Guidelines recommends that adults should aim to consume approximately 25–30 g fiber daily. Dietary fiber is found in the indigestible parts of cereals, fruits and vegetables. There are countries where people don’t eat enough food fibers, these people need to take some kind of fiber supplement. Evidence has been found that dietary fiber from whole foods or supplements may (1) reduce the risk of cardiovascular disease by improving serum lipids and reducing serum total and low-density lipoprotein (LDL) cholesterol concentrations, (2) decreases the glycaemic index of foods, which leads to an improvement in glycemic response, positive impact on diabetes, (3) protect against development of obesity by increasing satiety hormone leptin concentrations, (4) reduced risk of developing colorectal cancer by normalizes bowel movements, improve the integrity of the epithelial layer of the intestines, increase the resistance against pathogenic colonization, have favorable effects on the gut microbiome, wich is the second genomes of the microorganisms, (5) have a positive impact on the endocrine system by gastrointestinal polypeptide hormonal regulation of digestion, (6) have prebiotic effect by short-chain fatty acids (SCFA) production; butyrate acid is the preferred energy source for colonic epithelial cells, promotes normal cell differentiation and proliferation, and also help regulate sodium and water absorption, and can enhance absorption of calcium and other minerals. Although all prebiotics are fiber, not all fiber is prebiotic. This generally refers to the ability of a fiber to increase the growth of bifidobacteria and lactobacilli, which are beneficial to human health, and (7) play a role in improving immune function via production of SCFAs by increases T helper cells, macrophages, neutrophils, and increased cytotoxic activity of natural killer cells. Conclusion: Fiber consumption is associated with high nutritional value and antioxidant status of the diet, enhancing the effects on human health. Fibers with prebiotic properties can also be recommended as part of fiber intake. Due to the variability of fiber’s effects in the body, it is important to consume fiber from a variety of sources. Increasing fiber consumption for health promotion and disease prevention is a critical public health goal.

New trends in food science: the use of nutraceuticals as an antiinflammatory therapeutic tool in exercise

Prolonged high-intensity training seems to result in increased systemic inflammation, which might explain muscle injury, delayed onset muscle soreness, and overtraining syndrome in athletes. Furthermore, an impaired immune function caused by strenuous exercise leads to the development of upper respiratory tract infections in athletes. Nutraceuticals might help counteract these performance-lowering effects. The use of nanotechnology is an interesting alternative to supply athletes with nutraceuticals, as many of these substances are insoluble in water and are poorly absorbed in the digestive tract. The present chapter starts with a brief review of the effects of exercise on immunity, followed by an analysis on how nutraceuticals such as omega-3 fatty acids, glutamine, BCAAs, or phytochemicals can counteract negative effects of strenuous exercise in athletes. Finally, how nanostructured delivery systems can constitute a new trend in enhancing bioavailability and optimizing the action of nutraceuticals will be discussed, using the example of food beverages.

Wine phenolics: looking for a smooth mouthfeel

Each grape variety has its own phenolic profile. However, the concentration of the phenolic compounds present in wine mainly dependson winemaking processes. Phenolic compounds influence wine sensorial characteristics namely taste or mouthfeel, bitterness, astringency and color. Humans can perceive six basic tastes: sweet, salty; sour; umami; fat-taste and bitter taste. This last basic taste is considered as a defense mechanism against the ingestion of potential poisons. Some of the genes,encoding G-protein-coupled receptors - TAS2Rs, which translate for these distinct bitter compounds detectors have been identified. Different phenolic compounds activate distinguished combination of TAS2Rs. Astringency in wine is primarily driven by proanthocyanidins, soluble protein-proanthocyanidins complexes which diminish the protective salivary film and bind to the salivary pellicle; insoluble protein-proanthocyanidins complex and proanthocyanidins are rejected against salivary film and trigger astringency sensation via increasing friction. Thus, the aim of this review is to expand the knowledge about the role of wine phenolic compounds in wine sensorial properties, namely in bitterness and astringency phenomenon’s.