Academic literature on the topic 'Microsoft Expression Blend 2'

Abstract Background A Mediterranean diet (MD) has been proven efficacious in reducing inflammation in many chronic conditions, mediated by the interaction between diet, the gut microbiota and the immune system. The role of the MD as a dietary management strategy in the management of colitis requires further elucidation. While high fat diets have been shown to result in dysbiosis, our lab has clarified that the type of fat, not total calories derived from fat, predict gut dysbiosis and immunity in murine models of colitis. The n-6 polyunsaturated fatty acids (PUFA) promote colitis, however monounsaturated fatty acids (MUFA) protect against colitis. We hypothesize that a blend of fats, similar to the MD (high MUFA, low n-6 PUFA) will promote gut health beneficial to colitis. Aims Using a murine model of chronic intestinal inflammation, the aim of this study was to investigate the effects of dietary fatty acids on colitis by studying dietary fats in isolation from each other, as well as in a fatty acid profile similar to the blend contained in the MD. Methods Mice lacking the mucin 2 gene (Muc 2-/-) were weaned on to a 9-week, high fat (41%), isocaloric, isonitrogenous diet where the fat was derived from corn oil, olive oil, milk fat or a MD fat blend (28% MUFA, 8% SFA, 4% n-6 PUFA, 1% n-3 PUFA). The MD fat blend mimicked the fat profile consumed in the human diet. Disease activity, colon histology, cytokines (serum and colonic expression), cecal short chain fatty acids, intestinal permeability, glucose tolerance and gut microbiota (16S rRNA) were analyzed. Results Muc 2-/- fed the MD were protected from developing the most severe form of colitis, showing significantly lower disease activity and the absence of rectal prolapse. Histological damage was more severe in the corn oil and milk fat groups which coincided with an increase in infiltrating inflammatory cells and increased mucosal ulcerations. MD and milk fat diets exhibited enhanced intestinal permeability, glucose tolerance, intestinal alkaline phosphatase compared to the corn oil diet. Lower colonic mRNA levels of pro-inflammatory RELM-ß and IL-6 were also seen in the MD and MF diet in comparison to corn oil diet with the milk fat eliciting unique protective immune responses as evidenced by increased expression of IL-22 and Reg3-γ. Differences in alpha-diversity were seen between the MD and milk fat diets, beta-diversity revealed differences in taxa between diet groups. Conclusions The fatty acid profile of the MD protects against the development of spontaneous colitis in the Muc2-/- mouse model. In summary, not all dietary fats aggravate colitis, and some may be beneficial during colitis. A diet low in n-6 PUFA and high in MUFA is recommended. Funding Agencies CCCCFDR

Bioactive compounds, such as organic acids (OA) and nature-identical compounds (NIC), can exert a role in the protection of intestinal mucosa functionality due to their biological properties. The aim of this study was to understand the role of 2 OA (citric and sorbic acid) and 2 NIC (thymol and vanillin), alone or combined in a blend (OA + NIC), on intestinal barrier functionality, either during homeostatic condition or during an inflammatory challenge performed with pro-inflammatory cytokines and lipopolysaccharides (LPS). The study was performed on the human epithelial cell line Caco-2, a well-known model of the intestinal epithelial barrier. The results showed how OA and NIC alone can improve transepithelial electrical resistance (TEER) and mRNA levels of tight junction (TJ) components, but OA + NIC showed stronger efficacy compared to the single molecules. When an inflammatory challenge occurred, OA + NIC blend was able both to ameliorate, and prevent, damage caused by the pro-inflammatory stimulus, reducing or preventing the drop in TEER and improving the TJ mRNA expression. The data support the role of OA + NIC in modulating gut barrier functionality and reducing the negative effects of inflammation in intestinal epithelial cells, thereby supporting the gut barrier functionality.

Coccidia are protozoal parasites which compromise mucosal integrity of the intestine, potentiating poultry morbidity. The host's Zn status influences the course of infection. Therefore, two experiments were designed to determine how supplemental Zn regimens impacted jejunal and caecal immune status and Zn transporter expression. Coccivac®-B was administered weekly at ten times the recommended dose as a mild coccidial challenge (10CV). Zn was provided through a basal diet, supplemental zinc sulfate (ZnSO4), or a supplemental 1:1 blend of ZnSO4 and Availa®-Zn (Blend). Mucosal jejunum (Expt 1) and caecal tonsils (Expt 2) were evaluated for intracellular Zn concentrations and phagocytic capacity. Messenger expression of Zn transporters ZnT5, ZnT7, Zip9 and Zip13 were investigated to determine Zn trafficking. With 10CV, phagocytic capacity was decreased in jejunal cells by 2 %. In the caecal tonsils, however, phagocytic capacity increased with challenge, with the magnitude of increase being more pronounced with higher dietary Zn (10CV × Zn interaction; P= 0·04). Intracellular Zn within caecal tonsils was found significantly reduced with 10CV (27 %, P= 0·0001). 10CV also resulted in an overall increase in the ratio of Zip:ZnT transporters. With the exception of Zip13 transporter expression, dietary Zn source had little impact on any of the measured cellular parameters. Thus, intestinal mucosal tissues had reductions in intracellular free Zn during coccidial challenge, which was coupled with an upregulation of measured Zip transporters. This suggests that under coccidial challenge, intestinal cells attempt to compensate for the drop in intracellular Zn.

Replacing dietary fishmeal (FM) and fish oil (FO) with plant ingredients in Atlantic salmon (Salmo salarL.) diets decreases dietary cholesterol and introduces phytosterols. The aim of the present study was to assess the effect of dietary sterol composition on cholesterol metabolism in Atlantic salmon. For this purpose, two dietary trials were performed, in which Atlantic salmon were fed either 100 % FM and FO (FM-FO) diet or one of the three diets with either high (80 %) or medium (40 %) plant protein (PP) and a high (70 %) or medium (35 %) vegetable oil (VO) blend (trial 1); or 70 % PP with either 100 % FO or 80 % of the FO replaced with olive, rapeseed or soyabean oil (trial 2). Replacing ≥ 70 % of FM with PP and ≥ 70 % of FO with either a VO blend or rapeseed oil increased plasma and liver TAG concentrations. These diets contained high levels of phytosterols and low levels of cholesterol. Fish fed low-cholesterol diets, but with less phytosterols, exhibited an increased expression of genes encoding proteins involved in cholesterol uptake and synthesis. The expression of these genes was, however, partially inhibited in rapeseed oil-fed fish possibly due to the high dietary and tissue phytosterol:cholesterol ratio. Atlantic salmon tissue and plasma cholesterol concentrations were maintained stable independent of the dietary sterol content.