Dietary trans-Fatty Acid Induced NASH is Normalized Following Loss of trans-Fatty Acids from Hepatic Lipid Pools

Previous experiments in mice showed that dietary trans-fats could play a role in non-alcoholic steatohepatitis (NASH) yet little is known about the accumulation trans-fats in hepatic lipid pools in relationship to liver injury. NASH is also associated with obesity yet improves with only modest weight loss. To distinguish the role of obesity versus sustained consumption of a trans-fat containing diet in causing NASH, mice with obesity and NASH induced by consuming a high trans-fat diet for 16?weeks were subsequently fed standard chow or maintained on trans-fat chow for another 8?weeks. The accumulation, partitioning and loss of trans-fats in the major hepatic lipid pools during and after trans-fat consumption were determined. Obese mice switched to standard chow remained obese but steatohepatitis improved. trans-fats were differentially incorporated into the major hepatic lipid pools and the loss of trans-fats after crossover to control chow was greatest in the cholesteryl ester pool. In summary, dietary changes can improve the biochemical and histopathological changes of NASH despite persistent obesity in mice. Analysis of hepatic lipids confirmed that dietary trans-fats accumulate in the major lipid pools and are released differentially with diet normalization. The substantial loss of trans-fats from the cholesteryl ester pool in parallel with improvement in NASH suggests that this pool of trans-fats could play a role in the pathogenesis of NASH.     

Air‐dried 3D‐collagen–chitosan biocomposite scaffold for tissue engineering application

Collagen–chitosan scaffolds of different compositions were developed using emulsion air‐drying method. The scaffolds prepared adding 10–30 wt% of chitosan to collagen improved the mechanical properties of the composite scaffold, and 7:3 ratio (collagen :chitosan) was found to be a better composite having a tensile strength of 13.57 MPa with 9% elongation at break. The water‐uptake characteristics were performed at different pH and found to be ameliorated for the composite scaffolds compared to pure collagen and chitosan scaffold, respectively. The pores ranging from 100 to 300 μm were well interconnected, and their distribution was fairly homogeneous in the scaffold as observed through scanning electron microscopy. Furthermore, the scaffold decreased the bacterial counts and supported fibroblasts attachment and proliferation, thus demonstrating this composite to be a good substrate for biomedical application.POLYM. COMPOS., 33:2029–2035, 2012. © 2012 Society of Plastics Engineers