106 research outputs found
The Distribution of Liposomal-Methylprednisolone Palmitate (L-MPLP) in Several Organs in Mice After Intra-Peritoneal Injection
This study was to analyze the distribution of liposomal-methylprednisolone palmitate (L-MPLP) as a new drug formulation, in several organs of mice after intra-peritoneal injection. In a previous study, in vitro, the stability and the incorporation of methylprednisolone palmitate into liposome membranes were increased, from 70% to approximately 95% using tetra-ether lipid as a stabilizer of the liposome membrane. Based on this result, the stability of L-MPLP should also be proved, in vivo, that the drug, methylprednisolone palmitate, could be distributed into several organs more effective than in a control group (methylprednisolone palmitate and methylprednisolone as a standard of drug and liposome). Forty-two mice of C3H were divided into 5 study groups. Each group of animals was divided into 6 sub-groups of time from 10 minutes to 48 hours. Each drug was injected intra-peritoneal, blood was drawn from the vein of the tail and the organs i.e. liver, kidneys, spleen, thymus, and bone marrow were extirpated after sacrificing the mice using ether. The distribution of the drug or their metabolites was higher at the minute of 180 and tended to decrease at the time of 48 hours after injection. The higher distribution was shown in the liver and rather high in the spleen, thymus, kidney, and bone-marrow respectively
Optimization by thermal cycling
Thermal cycling is an heuristic optimization algorithm which consists of
cyclically heating and quenching by Metropolis and local search procedures,
respectively, where the amplitude slowly decreases. In recent years, it has
been successfully applied to two combinatorial optimization tasks, the
traveling salesman problem and the search for low-energy states of the Coulomb
glass. In these cases, the algorithm is far more efficient than usual simulated
annealing. In its original form the algorithm was designed only for the case of
discrete variables. Its basic ideas are applicable also to a problem with
continuous variables, the search for low-energy states of Lennard-Jones
clusters.Comment: Submitted to Proceedings of the Workshop "Complexity, Metastability
and Nonextensivity", held in Erice 20-26 July 2004. Latex, 7 pages, 3 figure
Status of the Superconducting Magnets for FAIR
Silicon microdosimetry measurements in Fast Neutron Therapy were simulated using the GEANT4 Monte Carlo toolkit. The possibility of using silicon microdosimeters for verification of Monte Carlo based treatment planning systems in hadron therapy is suggested
Detection of the SARS-CoV-2 Omicron Variant in COVID-19 Patients from South Tangerang Using SNP-Probes S371L and K417N
The COVID-19 pandemic caused by the SARS-CoV-2 virus has posed a global challenge. Experts from various branches of science have endeavoured to find solutions to control its spread, one of which has been the quick and precise detection of the virus and its variants in patients. This study aimed to detect the presence of SARS-CoV-2, notably the rapidly spreading Omicron variant, using the spike (S)-gene target failure (SGTF) and S-gene target positive (SGTP) with the principle of the single nucleotide polymorphism (SNP)-probe test. Our descriptive experimental approach detected Omicron variants with the SNP-probe technique using samples of SARS-CoV-2 patients and controls. The probes were designed to recognize the nucleotide code of the amino acids in positions 371 and 417 of SARS-CoV-2. The existence of variants was monitored by the presence or absence of a fluorescence signal, which was translated into a sigmoidal graph using a real-time (RT)-PCR machine. One hundred and twelve samples that had tested positive for SARS-CoV-2 and the Omicron variant using a registered commercial kit showed a similar result to our in-house-developed SNP-probe 371 and 417 assays. The results of this study indicate that the SNP-probe we designed can be used in the detection of the SARS-CoV-2 Omicron variant
Does dietary tocopherol level affect fatty acid metabolism in fish?
Fish are a rich source of the n-3 polyunsaturated fatty acids (PUFA), particularly the highly unsaturated fatty acids (HUFA), eicosapentaenoic (EPA; 20:5n-3) and docosahexaenoic (DHA; 22:6n-3) acids, which are vital constituents for cell membrane structure and function, but which are also highly susceptible to attack by oxygen and other organic radicals. Resultant damage to PUFA in membrane phospholipids can have serious consequences for cell membrane structure and function, with potential pathological effects on cells and tissues. Physiological antioxidant protection involves both endogenous components, such as free radical scavenging enzymes, and exogenous dietary micronutrients including tocopherols and tocotrienols, the vitamin E-type compounds, widely regarded as the primary lipid soluble antioxidants. The antioxidant activities of tocopherols are imparted by their ability to donate their phenolic hydrogen atoms to lipid (fatty acid) free radicals resulting in the stabilisation of the latter and the termination of the lipid peroxidation chain reaction. However, tocopherols can also prevent PUFA peroxidation by acting as quenchers of singlet oxygen. Recent studies on marine fish have shown correlations between dietary and tissue PUFA/tocopherol ratios and incidence of lipid peroxidation as indicated by the levels of TBARS and isoprostanes. These studies also showed that feeding diets containing oxidised oil significantly affected the activities of liver antioxidant defence enzymes and that dietary tocopherol partially attenuated these effects. However, there is evidence that dietary tocopherols can affect fatty acid metabolism in other ways. An increase in membrane PUFA was observed in rats deficient in vitamin E. This was suggested to be due to over production of PUFA arising from increased activity of the desaturation/elongation mechanisms responsible for the synthesis of PUFA. Consistent with this, increased desaturation of 18:3n-3 and 20:5n-3 in hepatocytes from salmon fed diets deficient in tocopherol and/or astaxanthin has been observed. Although the mechanism is unclear, tocopherols may influence biosynthesis of n-3PUFA through alteration of cellular oxidation potential or “peroxide tone”
The role of ascorbate in antioxidant protection of biomembranes: Interaction with vitamin E and coenzyme Q
One of the vital roles of ascorbic acid (vitamin C) is to act as an antioxidant to protect cellular components from free radical damage. Ascorbic acid has been shown to scavenge free radicals directly in the aqueous phases of cells and the circulatory system. Ascorbic acid has also been proven to protect membrane and other hydrophobic compartments from such damage by regenerating the antioxidant form of vitamin E. In addition, reduced coenzyme Q, also a resident of hydrophobic compartments, interacts with vitamin E to regenerate its antioxidant form. The mechanism of vitamin C antioxidant function, the myriad of pathologies resulting from its clinical deficiency, and the many health benefits it provides, are reviewed.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/44796/1/10863_2004_Article_BF00762775.pd
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