脂质体荧光衰减技术预测10种中药单体的被动吸收

制备了DPH荧光脂质体,选用10种药理活性较好的中药单体,测定了这些中药单体进入荧光脂质体后引起的荧光衰减百分率,评估中药单体的细胞膜通透性。采用大鼠在体肠单向灌流实验测定了中药单体的小肠有效透皮系数(Peff),与中药单体引起的脂质体荧光衰减数据对比,两者相关性良好,从而证明荧光脂质体模型可以应用来预测中药单体的被动吸收。用DPH标记红细胞膜,测定了以上10种中药单体对荧光标记的红细胞膜的荧光衰减百分率,发现荧光脂质体与红细胞膜相关性良好,荧光脂质体模型的确可以一定程度上替代制备繁琐的红细胞膜,用来研究中药单体在真实细胞膜中的通透性。综合而言,荧光脂质体模型简单易行、重现性好、所需样品量少,适合于中药早期研究的高通量筛选。     

Permeability of glycosides through human erythrocyte membrane

The permeability of glycosides (arbutin, salicin, glycyrritin, p-nitrophenyl-beta-D-glucopyranoside, p-nitrophenyl-beta-D-galactopyranoside, p-nitrophenyl-beta-D-lactopyranoside, p-nitrophenyl-beta-D-maltopyranoside) and their aglycons through human erythrocyte membrane was investigated. The glycosides permeated slowly, compared with their aglycons. Glycoside having disaccharide did not permeate the erythrocyte membrane. This suggested that the introduction of disaccharide to a drug significantly depresses the permeability of glycoside through erythrocyte membrane. The drug entrapped in erythrocytes was not released into the outer medium.     

Effect of phenylhydrazine-induced structural alterations of human erythrocytes on basic drug penetration

The phospholipid organization, lipid fluidity and spectrin degradation were measured in human erythrocytes oxidized with phenylhydrazine, and the contribution of these structural alterations to the penetration of perazine and promethazine into the membrane was estimated. It was found that exposure of erythrocytes to phenylhydrazine (0.2--0.4 mg/ml) produced a 35--40% decrease in the amount of spectrin, with resultant gross morphological changes to the echinocyte conformation. The phosphatidylethanolamine content in the treated erythrocytes was greatly lowered compared with that in the untreated cells. Treatment with phenylhydrazine (0.05--0.2 mg/ml) dramatically diminished the lipid fluidity of the membrane, as estimated by electron spin resonance (ESR) spectrometry, and the ESR study revealed increased restriction of the molecular motion of the hydrophobic core in the treated membrane. These results suggest a drastic alteration of the erythrocyte membrane structure. The amount of drugs which penetrated into the treated erythrocytes increased markedly with increasing phenylhydrazine concentration, suggesting enhanced membrane permeability and facilitated localization of the drugs in the hydrophobic regions due to the structural changes and partial disturbance of the lipid organization.     

Detection of erythrocyte membrane structural abnormalities in lecithin: cholesterol acyltransferase deficiency using a spin label approach.

The membrane fluidity of erythrocytes from patients with Lecithin: cholesterol acyltransferase (LCAT) deficiency was studied by means of electron spin resonance. The temperature dependence of the separation of the outer extrema of the spectra of 2-(3-carboxy-propyl)-4,4-dimethyl, 2-tridecyl-3-oxazolidinyloxyl spin probe was monitored for normal, presumed carrier and clinically affected subjects. The temperature profile of controls was significantly different from that of the presumed carriers and the clinically affected individuals. The results show that the compositional abnormalities previously noted in erythrocyte membranes from patients with LCAT deficiency are associated with alterations in the physiocochemical state of the membrane. An investigation of the spectral lineshapes below 10 degrees C allowed a distinction to be made at the membrane level between clinically affected subjects and clinically normal heterozygous carriers. Alterations in the temperature dependence of elec-ron spin resonance parameters may provide a sensitive index of red cell membrane alterations in pathological states of generalized membrane involvement.     

Gd络阴离子进入人红细胞并影响CI^—内流的机制

用质子诱导Ｘ射线发射法测定人红细胞与Ｇｄ柠檬酸和乳酸络合物温育时,胞浆,细胞膜膜脂和膜蛋白上Ｇｄ含量随时间的变化及阴离子通道抑剂对Ｇｄ进入细胞的影响。     

Hypochlorous acid-induced oxidative damage of human red blood cells: effects of tert-butyl hydroperoxide and nitrite on the HOCl reaction with erythrocytes

Hypochlorous acid, one of the most powerful biological oxidants, is believed to be important in the pathogenesis of some diseases. The purpose of this study was to further characterise the membrane and intracellular events which resulted in HOCl-induced oxidative impairments and haemolysis of human erythrocytes and interaction of different oxidative agents, which accumulated during respiratory burst, in the process of RBS oxidation. The sequence of cellular events after red blood cell exposure to HOCl: cell morphological transformations, oxidation of cellular constituents, enzyme modifications, and haemolysis have been evaluated. It was shown that HOCl-treated cells underwent colloid-osmotic haemolysis, preceded by rapid morphological transformations and membrane structural transitions. The activation energy of the process of haemolysis (after removal of the excess of oxidative agent) was estimated to be 146+/-22 kJ/mol at temperatures above the break point of Arrhenius plot (31-32 degrees C). This value corresponds to the activation energy of the process of protein denaturation. Modification of erythrocytes by HOCl inhibited membrane acetylcholinesterase (uncompetitive type of inhibition), depleted intracellular glutathione, activated intracellular glutathione peroxidase, but did not induce membrane lipid peroxidation. The presence of other oxidants, nitrite or tert-butyl hydroperoxide (t-BHP), promoted the oxidative damage induced by HOCl and led to new oxidative reactions.     

Permeability of rat and rabbit erythrocyte membranes for a series of amides

Permeability coefficients of rat and rabbit erythrocyte membranes for a series of amides, as well as for erythrocytes treated with p-chloromercuribenzenesulfonic acid monosodium salt (pCMBS) have been determined at 25 and 37 degrees C. Directly proportional dependence of the pCMBS treated erythrocyte permeability for investigated substances and their partition coefficients between the hydrophobic phase and water as well as the values of activation energy of this process indicate that penetration of small hydrophilic molecules is realized by passive diffusion through the lipid bilayer. The results obtained indicate that penetration of small hydrophilic molecules of formamide through lipids is determined by the existence of a free space between hydrocarbon chains that arises from kink formation. The differences in permeability between rat and rabbit erythrocyte membranes could arise in particular as a result of the differences in lipid composition.     

Na-nitroprusside and HgCl2 modify the water permeability and volume of human erythrocytes

The passage of water through the aquaporin-1 (AQP1) transmembrane channel protein of the human erythrocyte is known to be inhibited by organic mercurials such as p-chloromercuribenzoate (pCMB), which react with the free SH-group of the critical cysteine (Cys189) located near the constriction of the AQP1 water-specific channel. Sodium nitroprusside (SNP), which is known as a nitric oxide (NO) donor in interactions with SH-containing molecules, is shown here to suppress the diffusional water permeability (P(d)) of the erythrocyte membrane, presumably as a result of reaction with the Cys189 of the human erythrocyte AQP1 water channels. Further, treatment of erythrocytes with HgCl(2) is found to result in a cell volume decrease that can be related to activation of membrane K(+)-selective Gárdos channels and subsequent loss of intracellular K(+) and cell shrinkage. The variations in P(d) and volume of the erythrocyte were deduced from induced variations in the measured proton ((1)H) nuclear magnetic resonance (NMR) transverse (T(2)) relaxation functions of water exchanging between diamagnetic intracellular and paramagnetic extracellular compartments of the 20-25% hematocrit samples. The extracellular solvent contained 10 mM membrane-impermeable paramagnetic Mn(2+) ions. The (1)H-T(2) NMR technique allows determination of the time constant tau(exch) (for exchange of the erythrocyte intracellular water) that is inversely proportional to the permeability coefficient P(d) when the intracellular water volume is left unmodified, as in the case of SNP-treated erythrocytes. However, for HgCl(2)-treated erythrocytes, this technique showed simultaneous variation of both tau(exch) and the volume ratio V(in)/V(out) of intracellular and extracellular water in proportions suggesting that P(d) was left unmodified. The HgCl(2) effect has been found to be partly reversible by the reducing activity of added mercaptoethanol.     

Interaction of pentoxifylline with human erythrocytes. I. Interaction of xanthine derivatives with human erythrocyte ghosts

The interaction of pentoxifylline and other xanthine derivatives with human erythrocyte ghosts was studied. By fluorescence spectroscopy it was found that xanthine derivatives have two modes of binding to erythrocyte ghosts. One is a high-capacity binding to erythrocyte membranes. It seems that the 5-oxohexyl side chain of pentoxifylline is important for this. The second type may be a binding to proteins on the membranes and is specific for pentoxifylline and caffeine. From the circular dichroism spectra, it was presumed that the second binding mode of pentoxifylline occurs at hydrophobic regions of beta-structure of the membrane proteins. The relative high specificity in the interaction of pentoxifylline with erythrocytes should be related to its unique physiological activity on erythrocytes.     

Changes in Human Erythrocyte Membrane Exposed to Aqueous and Ethanolic Extracts from Uncaria tomentosa

Uncaria tomentosa (Willd.) DC is a woody climber species originating from South and Central America that has been used in the therapy of asthma, rheumatism, hypertension, and blood purification. Our previous study showed that U. tomentosa extracts altered human erythrocyte shape, which could be due to incorporation of the compounds contained in extracts into the erythrocyte membrane. The aim of the present study was to determine how the compounds contained in U. tomentosa extracts incorporate into the human erythrocyte membrane. The study has assessed the effect of aqueous and ethanolic extracts from leaves and bark of U. tomentosa on the osmotic resistance of the human erythrocyte, the viscosity of erythrocyte interior, and the fluidity of erythrocyte plasma membrane. Human erythrocytes were incubated with the studied extracts in the concentrations of 100, 250, and 500 µg/mL for 2, 5, and 24 h. All extracts tested caused a decrease in erythrocyte membrane fluidity and increased erythrocyte osmotic sensitivity. The ethanolic extracts from the bark and leaves increased viscosity of the erythrocytes. The largest changes in the studied parameters were observed in the cells incubated with bark ethanolic extract. We consider that the compounds from U. tomentosa extracts mainly build into the outer, hydrophilic monolayer of the erythrocyte membrane, thus protecting the erythrocytes against the adverse effects of oxidative stress.     

1-Naphthol as an excited state proton transfer fluorescent probe for erythrocyte membranes

The microenvironmental dependence of excited state prototropism of 1-naphthol and the corresponding changes in its fluorescence emission is utilized to monitor the acyl chain melting phase transition behavior of liposome membrane made from human erythrocyte lipids. A sharp increase in the ratio of neutral/anionic form fluorescence intensity is noticed at the phase transition temperature (19 degrees C). This provides a convenient method for obtaining phase transition temperature in lipid membranes. The membrane modifying effect of cholesterol on the erythrocyte liposome is successfully sensed by 1-naphthol fluorescence.     

Hypochlorous acid-induced membrane pore formation in red blood cells

The hyperproduction of hypochlorous acid (HOCl), an extremely toxic biological oxidant generated by neutrophils and monocytes, is involved in the pathogenesis of many diseases. In these studies, we attempted to determine the membrane and cellular events associated with HOCl-induced erythrocyte impairment and haemolysis. In vitro human erythrocyte exposure to HOCl (0.1-1.0 mM) resulted in rapid oxidation of reduced glutathione, an increase in cell osmotic fragility and the formation of transient membrane pores. The process of glutathione oxidation depended on the [oxidant]/[cell number] ratio. The HOCl-induced haemolysis observed was apparently mediated by pore formation and altered membrane electrolyte permeability. The estimated pore radius was approximately 0.7 nm and the average number per cell was 0.01. The rate constant of HOCl-produced haemolysis depended on pH. There were significant differences in haemolysis of HOCl-treated erythrocytes which had maximal stability at pH 7.2-7.3.     

Influence of saponin on the electric parameters and the electrophoretic mobility of erythrocytes

Structural changes in the membranes and charge changes on the cell surface of erythrocytes after saponin treatment were investigated by measuring the electric impedance of erythrocyte suspensions over the frequency range 0.5–20 MHz and the electrophoretic mobility of erythrocytes. From the characteristic time behaviour of the specific membrane capacitance calculated it can be concluded that two types of structure changes occur if saponin of a sufficiently high concentration acts. This is in good conformity with electron microscopic investigations. The electrophoretic mobility data show that the surface charge of erythrocytes decreases with saponin action. This effect allows a possible explanation for the observed increase in the conductivity inside and outside the cells.     

Effects of charged amphiphiles in depolarising solutions on potassium efflux and the osmotic fragility of human erythrocytes

The effect of the presence of charged amphiphiles during the incubation of human erythrocytes in a sucrose-substituted low-Cl(-) solution on the shift of the osmotic resistance profile and the net K+ efflux was investigated. Osmotic fragility was determined by fitting the complementary error function to the haemolysis resistance curve. K+ efflux was calculated from the increase in the K+ concentration in supernatant measured by inductively coupled plasma atomic emission spectrometry (ICP-AES). The cationic amphiphile hexadecyltrimethylammonium bromide (CTAB) at 14 microM decreases, whereas the anionic amphiphile sodium dodecyl sulfate (SDS) at 50 microM increases the shift of the haemolysis resistance curve of erythrocytes incubated in isotonic sucrose by 0.069 and 0.079 %NaCl, respectively. Both the positively and the negatively charged amphiphile caused a significant change in the K+ efflux into isotonic sucrose solution: CTAB decreased and SDS increased K+ efflux by about 40%. In view of the lack of effect of the investigated compounds on the haemolysis resistance curve and K+ efflux from human erythrocytes incubated in isotonic NaCl solution, these results suggest that the insertion of charged amphiphiles into the erythrocyte membrane modulates the properties of the K+ transport pathway which is activated under low ionic strength (LIS) conditions.     

Photohemolysis Sensitized by the Furocoumarin Derivative Alloimperatorin and its Hydroperoxide Photooxidation Product

The dark and photosensitized effects of alloimperatorin methyl ether 1 (hereafter simply alloimperatorin) and its photooxygenation product alloimperatorin hydroperoxide 2 were investigated on human erythrocytes. The results reveal that the furocoumarin 1 photosensitizes efficiently the hemolysis of erythrocytes. The rate of photohemolysis increases on raising the temperature of the postirradiated incubation from 4°C to 37°C. Thermal activation of the photohemolysis and inhibition by 2,6‐di‐tert‐butyl‐p‐cresol (BHT) suggest that the furocoumarin 1 photosensitizes lipid peroxidation, increasing permeability in the erythrocyte membrane. The hydroperoxide 2 induces dark and photosensitized hemolysis more efficiently than the furocoumarin 1. The rate of hemolysis induced by 2 increases with the incubation temperature and decreases in the presence of tert‐butanol and BHT. The hydroperoxide 2 photosensitizes the formation of lipid peroxidation products as shown by the reaction with thiobarbituric acid. This process is diminished by BHT. Our data imply that the photohemolysis sensitized by the furocoumarin 1 is caused by the in situ‐formed photooxygenation product 2. Such hydroperoxides are potent hemolytic agents in the dark and especially on photosensitization.     

Pore resealing inactivation in electroporated erythrocyte membrane irradiated with electrons.

The changes in the electroporation process of human erythrocytes membrane due to the direct action of high energy electron radiation were investigated. To avoid the indirect effects caused by radiolytic products of water, the irradiation was performed at liquid nitrogen temperature. The irradiated cells have been exposed to square-wave electric pulses at 4 degrees C in isotonic suspensions to induce membrane electropores. The pores resealing were quantified by monitoring the cell hemolysis. A significant decrease of the resealing process was found for irradiation doses higher than 100 Gy. The mass of molecular structures affected by the direct action of radiation was estimated using the target analysis method. We found a molecular weight Mm approximately 930 kDa roughly corresponding to spectrin tetramer of the cytoskeleton. This suggests that spectrin network plays an important role in the pores resealing of the electropermeabilized erythrocyte membrane.     

TEMPERATURE EFFECTED STRUCTURAL TRANSITIONS IN POLYURETHANES SATURATED WITH SOLVENTS STUDIED BY SAXS SYNCHROTRON METHOD

ABSTRACT

A set of segmented polyurethanes (PU) differing in the hard-segment structure was saturated with solvents and after the equilibrium saturation was reached, put to temperature-dependent SAXS investigations. The time-resolved mode of SAXS measurements with a linear increase of temperature from ?70°C to +70°C, i.e., within the temperature range between T_g of soft and hard segments, was applied. The order-order transition leading to a greater degree of order was found at higher temperatures for almost all systems investigated. Some of the PUs exhibit two kinds of microphase separated domains. The results obtained are discussed with respect to the mean-field theory of copolymers and Koberstein and Stein model for hard microdomain structure in PUs, and correlated with temperature dependence of membrane permeability in pervaporation process.     

Erythrocyte membrane permeability for a series of diols

Erythrocyte membrane permeability coefficients for a series of diols have been defined by the method developed. The method is based on the physical and mathematical modeling of hypotonic hemolysis process. There have been also determined membrane permeability coefficients for erythrocytes treated with p-chloromercuribenzenesulfonic acid monosodium salt (pCMBS), which is known to block aqueous protein channels. Permeating process is shown to be conditioned both by hydrophilic/hydrophobic properties of the molecules and their geometrical parameters. The obtained results propose that, when exceeding the molecules diameter over a value of 4 A, the permeability coefficient reduces due to decreasing of flow through the aqueous protein pores of a constant size. Permeability coefficients for comparatively hydrophobic molecules are almost directly proportional to the coefficients of partition between hydrophobic and hydrophilic phases, by pointing to a lipid way of permeation of these molecules through erythrocyte membranes.