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The weathering of crude oil at sea has been researched for nearly half a century. However, there have been relatively few opportunities to validate laboratory-based predictions about the rates, relative importance, and controls of oil weathering processes (e.g., evaporation, photo-oxidation, and emulsification) under natural field conditions. The 2010 Deepwater Horizon (DWH) spill in the Gulf of Mexico provided the oil spill science community with a unique opportunity to evaluate our laboratory-based predictions in nature. selleck inhibitor With a focus on photochemical weathering, we review what we knew prior to the DWH spill, what we learned from the DWH spill, and what priority gaps in knowledge remain. Three key findings from the DWH spill are discussed. First, the rate and extent of photochemical weathering was much greater for the floating surface oil than expected based on early conceptual models of oil weathering. Second, indirect photochemical processes played a major role in the partial oxidation of the floating surface oil. Third, the extensive and rapid changes to the physical and chemical properties of oil by sunlight may influence oil fate, transport, and the selection of response tools. This review also highlights findings and predictions about photochemical weathering of oil from several decades ago that appear to have escaped the broader scientific narrative and ultimately proved true for the DWH spill. By focusing on these early predictions and synthesizing the numerous findings from the DWH spill, we expect this review will better prepare the oil spill science community to respond to the next big spill in the ocean.In this paper, we report a fluorescent sensor array approach for the urinary detection of a prohibited substance in sports, meldonium. Four chemosensors with ethidium bromide scaffolds were employed in this method. The interaction between meldonium and chemosensors was investigated by different techniques, such as ultraviolet-visible absorption and fluorescence spectroscopy, nuclear magnetic resonance, and mass spectrometry. Molecular dynamics simulation was also used to elucidate and support the interaction mechanisms between meldonium and the chemosensors. Differential responses obtained from the sensor array enabled the qualitative and quantitative analyses of meldonium with low error values. This method was able to detect and quantify meldonium at the nM level, fulfilling the requirements of minimum performance defined by the World Anti-Doping Agency.Developing food protein structures with the freedom to tune their internal molecular arrangements is a fascinating aspect for serving the demands of multifunctional food components. However, a protein’s conformation is highly submissive to its amino acid sequences, posing a great limitation on controlling its structural rearrangements. In this study, based on simply co-dissolving scallop muscle proteins (SMPs, water-insoluble) and soya proteins (SPs) at pH 12 prior to neutralization, the unfolding-folding pathways of both proteins were altered. Structural characterizations evidenced the complexation of SMPs and SPs using their secondary structures as the building blocks. Due to hydrophobic coalition between the α-helix (from SMPs) and β-sheet (from SPs), the co-assembled structures obtained considerable resistance against folding triggered by the hydrophobic effect. In addition, the kinetics by which the SMPs and SPs folded together was tailor-made by the compositional differences of the two proteins, resulting in the formation of well-defined, water-dispersible nanospheres with a tunable size and internal arrangements of the backbones. This study would enrich our choice of manipulated protein structures and enlarge the available protein sources with tailorable functions when applied in specific scenarios.Lactobacillus plantarum FZU3013, a probiotic previously isolated from the traditional brewing process of Hongqu rice wine, may have the beneficial effect of improving the disorders of lipid metabolism. This study aimed to investigate the role of L. plantarum FZU3013 in improving non-alcoholic fatty liver (NAFL) associated with hyperlipidemia in mice fed a high-fat diet. The results indicated that L. plantarum FZU3013 intervention significantly reduced the HFD-induced body weight gain and the abnormal levels of serum total triglycerides (TG), total cholesterol (TC) and low-density lipoprotein (LDL-C), and inhibited the excessive accumulation of liver lipids. In addition, L. plantarum FZU3013 also promoted the excretion of bile acids through feces. Metagenomic and multivariate statistical analysis revealed that L. plantarum FZU3013 made significant structural changes in the intestinal microbiome of the mice fed with HFD, in particular by modulating the relative abundance of some function related microbial phylough modulating specific intestinal microbial phylotypes and regulating hepatic lipid metabolism related genes, therefore it could be used as a potential functional food for the prevention of NAFL and hyperlipidemia.Tissue-engineered heart valves are a promising alternative to current valve substitutes. As the main scaffold of tissue-engineered heart valves, the decellularized heart valve (DHV) has problems such as biomechanical property damage and rapid degradation. In this study, we applied a photo-crosslinking reaction induced by riboflavin and ultraviolet light A (UVA) in the DHV for improving its biomechanical properties and stability. The results showed that the biomechanical properties of the DHV significantly improved following riboflavin-UVA (R-UVA) crosslinking. Moreover, the R-UVA-crosslinked DHV (R-UV-DHV) showed better resistance to enzymatic degradation in vitro, with significantly higher thermal denaturation temperature compared to that of the untreated DHV, indicating that the stability of the R-UV-DHV improved. Histological staining and scanning electron microscopy showed that the leaflet ultrastructure was preserved better after R-UVA crosslinking compared to a glutaraldehyde-crosslinked DHV. In addition, we found that the R-UV-DHV exhibited excellent human umbilical vein endothelial cell adhesion and cells could readily grow on its surface. In an in vitro anti-calcification experiment, the R-UV-DHV demonstrated non-calcifying properties in a simulated body fluid. Furthermore, the R-UV-DHV showed characteristics of slow degradation, non-calcification, and reduced pro-inflammatory response through a rat subcutaneous implantation model. As a result, R-UVA can effectively crosslink the DHV and the R-UV-DHV possessed satisfactory biocompatibility. R-UVA crosslinking can be a new approach for improving the performance of the DHV to prepare a better scaffold for tissue-engineered valves.