Efeitos da farinha de folhas de mandioca sobre a atividade das enzimas AST, ALT, FA e lipídios hepáticos de ratos Wistar

Folhas de mandioca possuem substâncias como ligninas e saponinas que podem apresentar efeito hipolipidêmico. Todavia, um estudo recente relatou aumento no peso do fígado de ratos alimentados com dietas contendo farinha de folhas de mandioca (FFM - Manihot esculenta Crantz cv. Cacao), tornando-se necessário um estudo mais aprofundado dos efeitos desta farinha sobre os parâmetros hepáticos. Para este estudo, um ensaio biológico com 32 ratos machos Wistar foi conduzido por um período de 7 semanas, sendo os tratamentos: dieta controle e dietas contendo 5, 10 e 15% de FFM. As dietas contendo FFM não apresentaram efeitos sobre as atividades das enzimas Aspartato Aminotransferase (AST) e Fosfatase Alcalina (FA), mas aumentaram significativamente a atividade da enzima alanina aminotransferase (ALT). O estudo histopatológico revelou vacuolização do citoplasma dos hepatócitos para todos os grupos. No entanto, a freqüência de animais com vacuolização acentuada foi superior nos grupos que receberam dietas com FFM, apresentando também maiores teores de lipídios e colesterol total hepáticos e maior relação peso fígado/peso corporal. Estes resultados indicam que os antinutrientes presentes nas folhas de mandioca, como taninos, cianeto e saponinas, podem ser responsáveis pela redução da função hepática nos animais alimentados com FFM.

Comparison of total phenolic content and antiradical capacity of powders and "chocolates" from cocoa and cupuassu

Polyphenolic compounds seem to be related to the health benefits produced by the cocoa due to their antioxidant properties. Cupuassu powder, prepared from Theobroma grandiflorum seeds, is a very promising cocoa powder substitute. In order to assess the potential health benefits of the cupuassu powder, a comparison was performed between cocoa, chocolate, and cupuassu powders in relation to the content of total phenolic compounds, flavonoids and DPPH scavenging capacity of methanolic extracts. Cupuassu "chocolates" (milk, dark, and white) were also analyzed. Mineral, lipid, protein, and moisture determinations were made in cocoa and cupuassu powders and in cupuassu "chocolates". Results showed that the phenolic contents of cocoa and chocolate powders are more than three times higher than those of cupuassu powder; however, flavonoid contents were significantly lower. The DPPH scavenging capacity varied hugely among the different samples, from 0.5 (white cupuassu "chocolate") to 120 (cocoa powder) μg of Trolox equivalent per 100 g (FW), and presented a significant correlation (r = 0.977) with the total phenolic contents but not with the flavonoid contents (r = -0.035).

Correlation, by multivariate statistical analysis, between the scavenging capacity against reactive oxygen species and the bioactive compounds from frozen fruit pulps

The contents of total phenolic compounds (TPC), total flavonoids (TF), and ascorbic acid (AA) of 18 frozen fruit pulps and their scavenging capacities against peroxyl radical (ROO•), hydrogen peroxide (H2O2), and hydroxyl radical (•OH) were determined. Principal Component Analysis (PCA) showed that TPC (total phenolic compounds) and AA (ascorbic acid) presented positive correlation with the scavenging capacity against ROO•, and TF (total flavonoids) showed positive correlation with the scavenging capacity against •OH and ROO• However, the scavenging capacity against H2O2 presented low correlation with TF (total flavonoids), TPC (total phenolic compounds), and AA (ascorbic acid). The Hierarchical Cluster Analysis (HCA) allowed the classification of the fruit pulps into three groups: one group was formed by the açai pulp with high TF, total flavonoids, content (134.02 mg CE/100 g pulp) and the highest scavenging capacity against ROO•, •OH and H2O2; the second group was formed by the acerola pulp with high TPC, total phenolic compounds, (658.40 mg GAE/100 g pulp) and AA , ascorbic acid, (506.27 mg/100 g pulp) contents; and the third group was formed by pineapple, cacao, caja, cashew-apple, coconut, cupuaçu, guava, orange, lemon, mango, passion fruit, watermelon, pitanga, tamarind, tangerine, and umbu pulps, which could not be separated considering only the contents of bioactive compounds and the scavenging properties.