Length of poly IC molecule also influence IFNβ expression in response of RLR pathway. Short (LMW) poly IC induce stronger IFN-β expression in myeloid (macrophage and monocyte) cells. In contrast long (HMW) poly IC preferably elicit higher IFNβ expression in non-myeloid (fibroblast) cell. Therefore, MDA5 and RIG-1 plays an indispensable role in eliciting antiviral response in non- immune (fibroblast) host cell. Thus, stimulation of RLR pathway with suitable and potentially cell-type specific agonist molecules successfully elicit antiviral state in the host animal, with fibroblasts conferring a stronger antiviral state compared with the monocytes and macrophages. Consumption of fermentable dietary fibres, such as inulin, or administration of helminth products (e.g. Trichuris suis ova) have independently been shown to alleviate inflammation in vivo. We recently found that dietary inulin and T. suis infection in pigs co-operatively suppressed type-1 inflammatory responses in the gut, suggesting the potential of dietary components to augment anti-inflammatory responses induced by certain helminths. Here, we explored whether T. suis antigens and inulin could directly suppress inflammatory responses in vitro in a cooperative manner. T. suis soluble products (TsSP) strongly suppressed lipopolysaccharide (LPS)-induced IL-6 and TNF-α secretion from murine macrophages and induced an anti-inflammatory phenotype as evidenced by transcriptomic and gene pathway analyses. Inulin regulated the expression of a small number of genes and transcriptional pathways in macrophages after exposure to LPS, but did not enhance the suppressive activity of TsSP, either directly or in co-culture experiments with intestinal epithelial cells. Culture of macrophages with short-chain fatty acids, the products of microbial fermentation of inulin, did however appear to enhance TsSP-mediated inhibition of TNF-α production. Our results confirm a direct role for helminth products in suppressing inflammatory responses in macrophages. In contrast, inulin had little capacity to directly modulate LPS-induced responses. Our results suggest distinct mode-of-actions of T. suis and inulin in regulating inflammatory responses, and that the role of inulin in modulating the response to helminth infection may be dependent on other factors such as production of metabolites by the gut microbiota. Antibacterial polymer nanocomposite fibre meshes containing graphene oxide (GO) nanosheets were successfully prepared by pressurised gyration. The morphological and chemical composition of the resulting fibre meshes were determined using Scanning Electron Microscopy (SEM), Raman spectroscopy, Raman mapping and Fourier-Transform Infrared Spectroscopy (FT-IR). SEM showed the fibres to have an average diameter increasing from ~1-4 µm as the GO loading increased. FT-IR and Raman spectroscopy confirmed the inclusion of GO nanosheets on the fibre surface. The antibacterial potential of GO nanocomposite fibres were investigated using Escherichia coli K12. Average bacterial reduction ranged from 46 to 85 % with results favouring the strongest bioactivities of the nanocomposite containing 8 wt% of GO. Finally, bacterial toxicity of the nanocomposites was evaluated by reactive oxygen species (ROS) formation. A mechanism for the antibacterial behaviour of the nanocomposite fibres is presented. Stimulated Raman scattering imaging and spectra of the fibres post antibacterial studies showed flakes of GO distributed across the surface of the poly(methyl 2-methylpropenoate) (PMMA) fibres, which contribute to the high killing efficacy of the composites towards E. coli. GO nanosheets embedded in a polymer matrix have demonstrated the ability to retain their antibacterial properties, thus offering themselves as a promising antibacterial agent. HYPOTHESIS Colloids at fluid interfaces organize according to inter-particle interactions. The main contributions to an effective interaction potential are expected to be electrostatic dipole-dipole repulsion and capillary attraction due to fluid interface deformation. When these interactions are weak, a secondary minimum in the particle pair interaction potential is expected. EXPERIMENTS Clean bare silica particles were deposited at an oil/water interface and their organization as well as dynamics were observed under a light microscope and analyzed in terms of radial distribution function and mean squared displacement. FINDINGS Weak long-range competing interactions between colloids at an oil/water interface result in cluster formation. The clusters have a liquid-like structure and grow with increasing particle packing fraction. System 'ergodicity' suggests near-equilibrium assembly, which is confirmed by free particle dynamics outside the clusters. The interplay between dipole-dipole repulsion and capillary attraction responsible for the cluster formation is reflected in a secondary minimum of the effective interaction potential predicted theoretically but inaccessible experimentally from collective particle properties prior to this work. During fossil oil extraction, a complex water stream known as produced water (PW), is co-extracted. Membrane treatment makes PW re-use possible, but fouling and oil permeation remain major challenges. In this work, membrane fouling and oil retention of Synthetic PW stabilized with a cationic, anionic, zwitterionic or nonionic surfactant, were studied at various surfactant and salt concentrations. We discuss our results in the framework of the Young-Laplace (YL) equation, which predicts for a given membrane, pressure and oil-membrane contact angle, a critical interfacial tension (IFT) below which oil permeation should occur. https://www.selleckchem.com/products/BIRB-796-(Doramapimod).html We observe such a transition from high to low oil retention with decreasing IFT for the anionic (SDS), cationic (CTAB) and non-ionic (TX) surfactant, but at significantly higher critical IFTs than predicted by YL. On the other side, for the zwitterionic DDAPS we do not observe a drop in oil retention, even at the lowest IFT. The discrepancy between our findings and the critical IFT predicted by YL can be explained by the difference between the measured contact angle and the effective contact angle at the wall of the membrane pores. This leads to a surfactant-dependent critical IFT. Additionally, our results point out that zwitterionic surfactants even at the lowest IFT did not present a critical IFT and exhibited low fouling and low oil permeation.
Length of poly IC molecule also influence IFNβ expression in response of RLR pathway. Short (LMW) poly IC induce stronger IFN-β expression in myeloid (macrophage and monocyte) cells. In contrast long (HMW) poly IC preferably elicit higher IFNβ expression in non-myeloid (fibroblast) cell. Therefore, MDA5 and RIG-1 plays an indispensable role in eliciting antiviral response in non- immune (fibroblast) host cell. Thus, stimulation of RLR pathway with suitable and potentially cell-type specific agonist molecules successfully elicit antiviral state in the host animal, with fibroblasts conferring a stronger antiviral state compared with the monocytes and macrophages. Consumption of fermentable dietary fibres, such as inulin, or administration of helminth products (e.g. Trichuris suis ova) have independently been shown to alleviate inflammation in vivo. We recently found that dietary inulin and T. suis infection in pigs co-operatively suppressed type-1 inflammatory responses in the gut, suggesting the potential of dietary components to augment anti-inflammatory responses induced by certain helminths. Here, we explored whether T. suis antigens and inulin could directly suppress inflammatory responses in vitro in a cooperative manner. T. suis soluble products (TsSP) strongly suppressed lipopolysaccharide (LPS)-induced IL-6 and TNF-α secretion from murine macrophages and induced an anti-inflammatory phenotype as evidenced by transcriptomic and gene pathway analyses. Inulin regulated the expression of a small number of genes and transcriptional pathways in macrophages after exposure to LPS, but did not enhance the suppressive activity of TsSP, either directly or in co-culture experiments with intestinal epithelial cells. Culture of macrophages with short-chain fatty acids, the products of microbial fermentation of inulin, did however appear to enhance TsSP-mediated inhibition of TNF-α production. Our results confirm a direct role for helminth products in suppressing inflammatory responses in macrophages. In contrast, inulin had little capacity to directly modulate LPS-induced responses. Our results suggest distinct mode-of-actions of T. suis and inulin in regulating inflammatory responses, and that the role of inulin in modulating the response to helminth infection may be dependent on other factors such as production of metabolites by the gut microbiota. Antibacterial polymer nanocomposite fibre meshes containing graphene oxide (GO) nanosheets were successfully prepared by pressurised gyration. The morphological and chemical composition of the resulting fibre meshes were determined using Scanning Electron Microscopy (SEM), Raman spectroscopy, Raman mapping and Fourier-Transform Infrared Spectroscopy (FT-IR). SEM showed the fibres to have an average diameter increasing from ~1-4 µm as the GO loading increased. FT-IR and Raman spectroscopy confirmed the inclusion of GO nanosheets on the fibre surface. The antibacterial potential of GO nanocomposite fibres were investigated using Escherichia coli K12. Average bacterial reduction ranged from 46 to 85 % with results favouring the strongest bioactivities of the nanocomposite containing 8 wt% of GO. Finally, bacterial toxicity of the nanocomposites was evaluated by reactive oxygen species (ROS) formation. A mechanism for the antibacterial behaviour of the nanocomposite fibres is presented. Stimulated Raman scattering imaging and spectra of the fibres post antibacterial studies showed flakes of GO distributed across the surface of the poly(methyl 2-methylpropenoate) (PMMA) fibres, which contribute to the high killing efficacy of the composites towards E. coli. GO nanosheets embedded in a polymer matrix have demonstrated the ability to retain their antibacterial properties, thus offering themselves as a promising antibacterial agent. HYPOTHESIS Colloids at fluid interfaces organize according to inter-particle interactions. The main contributions to an effective interaction potential are expected to be electrostatic dipole-dipole repulsion and capillary attraction due to fluid interface deformation. When these interactions are weak, a secondary minimum in the particle pair interaction potential is expected. EXPERIMENTS Clean bare silica particles were deposited at an oil/water interface and their organization as well as dynamics were observed under a light microscope and analyzed in terms of radial distribution function and mean squared displacement. FINDINGS Weak long-range competing interactions between colloids at an oil/water interface result in cluster formation. The clusters have a liquid-like structure and grow with increasing particle packing fraction. System 'ergodicity' suggests near-equilibrium assembly, which is confirmed by free particle dynamics outside the clusters. The interplay between dipole-dipole repulsion and capillary attraction responsible for the cluster formation is reflected in a secondary minimum of the effective interaction potential predicted theoretically but inaccessible experimentally from collective particle properties prior to this work. During fossil oil extraction, a complex water stream known as produced water (PW), is co-extracted. Membrane treatment makes PW re-use possible, but fouling and oil permeation remain major challenges. In this work, membrane fouling and oil retention of Synthetic PW stabilized with a cationic, anionic, zwitterionic or nonionic surfactant, were studied at various surfactant and salt concentrations. We discuss our results in the framework of the Young-Laplace (YL) equation, which predicts for a given membrane, pressure and oil-membrane contact angle, a critical interfacial tension (IFT) below which oil permeation should occur. https://www.selleckchem.com/products/BIRB-796-(Doramapimod).html We observe such a transition from high to low oil retention with decreasing IFT for the anionic (SDS), cationic (CTAB) and non-ionic (TX) surfactant, but at significantly higher critical IFTs than predicted by YL. On the other side, for the zwitterionic DDAPS we do not observe a drop in oil retention, even at the lowest IFT. The discrepancy between our findings and the critical IFT predicted by YL can be explained by the difference between the measured contact angle and the effective contact angle at the wall of the membrane pores. This leads to a surfactant-dependent critical IFT. Additionally, our results point out that zwitterionic surfactants even at the lowest IFT did not present a critical IFT and exhibited low fouling and low oil permeation.
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