Inhibition of Phosphotidylcholine Liposome Oxidation by Phenolics from Aloe Extracts: A. arborescens,A. pillansii,and A. squarrosa

Russian Journal of Bioorganic Chemistry - Various species from the genus Aloe, which there are more than 500 in the world, are considered to be important sources of biologically active compounds,...     

Initiated Oxidation of Phosphatidylcholine Liposomes with Some Functional Nutraceuticals

Russian Journal of Bioorganic Chemistry - Design and research of liposome structures on the basis of soy phosphatidylcholine (PC) as nanocontainers for delivery of various functional nutraceuticals...     

The mapping of three subfractions of endoplasmic reticulum membranes isolated from L-929 cells by the use of spin probes

Summary This paper concerns the estimation of microviscosity parameters in smooth, light rough and heavy rough endoplasmic reticulum subfractions isolated from L-929 cells. Electron spin resonance using three probes was utilized in order to make estimations of rotational correlation times. The highest microviscosity was found in the smooth fraction. The lipid bilayer is less viscous and the annular one more rigid in heavy rough compared to light rough membranes. The individual membrane subfractions differ with regard to their portrait of thermoinduced structural transitions. The highest number of such transitions was detected in smooth membranes. There were no low-temperature transitions (relative to physiological temperature) or common thermoinduced structural rearrangements of the lipids in the heavy rough subfraction, a membrane fraction characteristic of transformed cells. The results show that each membrane subfraction is characterized by an intrinsic series of thermoinduced structural transitions, which, in combination with an estimation of microviscosity, yields a portrait of the structural state of the membrane lipids.     

The Relationship between Lipid Peroxidation and Microviscosity in Phosphatidylcholine Liposomes. The Effects of a Plant Antioxidant and a Protein

Biophysics - Abstract—The influence of lipid peroxidation on the structure of biomembranes and liposomes has been studied for many years; however, there are still a number of unexplained...     

The Physico-Chemical Properties of Liposomes Made from Lipids of the Liver and Brain of Mice Receiving Nanolipid Complexes

Biophysics - We studied the physico-chemical properties of lipids of the most important organs (the liver and brain) of mice that received nanoliposomal complexes of different compositions in a...     

The Effect of the Composition of a Liposomal Nanocomplex on the Antioxidant Activity of Murine Blood Plasma and Lipids of the Liver and Brain

Much attention is given to research and development of efficient systems for the delivery of essential omega-3-polyunsaturated fatty acids and other nutraceuticals to the human body with food. Nanocomplexes, which are based on soybean phosphatidylcholine liposomes with nutraceuticals included, are among the efficient delivery systems. The prolonged use of these nanocomplexes may affect the antioxidant status in various organs and tissues. In this work, thermo-initiated chemiluminescence was used to study changes in the antioxidant activity of the blood plasma, liver, and brain lipids in mice divided into six groups depending on the composition of liposomal nanocomplexes introduced into drinks substituted for water in a long-term (3 month) diet. The components of six types of liposomal nanocomplexes, except for phosphatidylcholine, in different combinations were clove essential oil, fish oil, and sodium caseinate. The results of the study showed that nanocomplexes containing liposomes made of phosphatidylcholine with the addition of fish oil and clove essential oil and encapsulated in milk protein (sodium caseinate) proved to be the most effective in increasing the antioxidant activity of the blood plasma and brain lipids in mice compared to the control.

     

The identification of novel orally active mGluR5 antagonist GSK2210875

The identification of novel orally active mGluR5 antagonist GSK2210875 is described.     

Effect of dilute solutions of biologically active substances on cell membranes

The article presents data on changes in physicochemical properties of different biological membranes (plasmatic, microsomal, synaptosomes) under the action of biologically active substances, which are different in their chemical structure and the mechanism of action (natural and synthetic antioxidants, thyrotropin - releasing hormone, phorbol esters), in the wide range of concentrations (10^?22?10^?3 M). Dose dependences of the effect of biologically active substances on the activity of membrane-bound enzymes, lipid peroxidation, the structural state of the various regions of the lipid bilayer of membranes have been obtained and analyzed in terms of their formal generality of polymodality, number and position of the maxima, a sign change of the effect. An attempt to explain the mechanism of each of the observed peaks in these curves has been made. The maximum in the range of relatively high “physiological” concentrations (10^?3–10^?7 M) is associated with introduction of biologically active substances into biomembranes. In this study maxima in the range of ultra-low doses (10^?11–10^?16 M) and “apparent” concentrations (10^?18 M), where the presence of biologically active substance molecule in a reaction volume is probabilistic in nature, are explained by physicochemical properties of diluted biologically active substances solutions. This conclusion is based on our data on the changes in IR spectra of aqueous solutions of biologically active substances and the results obtained by academician A.I. Konovalov et al. concerning the physicochemical properties of dilute solutions of biologically active substances (conductivity, surface tension, charge), due to the formation of so-called “nanoassociates” from biologically active substance molecule and numerous number of water molecules. The nanoassociates formation and biological effect disappear if the low concentration solutions are kept in a special shielded permalloy container protecting its contents from external electromagnetic field. Thus, nanoassociates are the material carriers of the unique ability of the ultra-low doses of biologically active substances to exhibit biological effects.