Dantrolene sodium in vitro inhibited the ATP-dependent efflux of calcium from human Fed cells, the Ca++-ATPase activity of red blood cell membrane fragments (RBCMF) and passive calcium binding to RBCMF. These effects were obtained With concentrations of dantrolene sodium between 2.5 and 20 uM. However the passive influx of Ca++ was measured at 37 degrees C in cells pretreated to abolish Ca++ pumping and was not influenced by dantrolene sodium. From these results, it was concluded that dantrolene sodium inhibits an active Ca++ extrusion across the red cell membrane by inhibiting Ca++-ATPase activity which is intimately involved with the Ca++ transport mechanism in the red cell membrane.
Calcium/metabolism* ; Dantrolene/pharmacology* ; Erythrocyte Membrane/drug effects* ; Erythrocyte Membrane/metabolism ; Human ; Ion Channels/drug effects* ; Ion Channels/metabolism

This study was purposed to evaluate the effect of trehalose-loading on physiological and biochemistry properties of red blood cell (RBC) membrane. The samples were divided into the control group (RBC without trehalose loading) and the test group (RBC with trehalose loading). Osmotic fragility reaction was used to determine the osmotic fragility change of loaded RBC membrane in NaCl solution of different osmotic concentration. Flow cytometry and deformeter were used to assay the integrality and deformability of the RBC, respectively. The results showed that the NaCl solution osmotic concentrations were 160 mOsm and 121.4 mOsm, respectively when the haemolysis rate was 50% of the control group and the test group. Flow cytometry data demonstrated that incubation of RBC in a hypertonic trehalose solution resulted in a fraction of cells with different complexity that attached to little Annexin V-FITC, and that it could be removed by washing and resuspending the RBC in an iso-osmotic (300 mOsm PBS) medium. The deformability of the loaded RBC descend, the statistical difference was significant between control and test groups (P < 0.01). It is concluded that the membrane physiological and biochemistry stability and membrane integrality of RBC in a hyper osmotic pressure can be retained after trehalose loading.
Blood Preservation ; methods ; Cryopreservation ; methods ; Erythrocyte Membrane ; drug effects ; Erythrocytes ; drug effects ; Humans ; Osmotic Fragility ; drug effects ; Trehalose ; pharmacology

This study was aimed to investigate various factors influencing the proceduction of Cu(II) crossing human erythrocyte membrane, including concentration of Cu²⁺, pH value of the medium, temperature and time of incubation, and to derive kinetic equation of Cu(II) crossing human erythrocyte membrane. Suspension red blood cells were incubated by Cu²⁺, then content of Cu²⁺ crossed human erythrocyte membrane was determined by atomic absorption spectrometry under various conditions after digestion. The results showed that content of Cu²⁺ crossed human erythrocyte membrane increased with the increase of extracellular Cu²⁺ and enhancement of incubation temperature, and the content of Cu²⁺ crossed human erythrocyte membrane showed a increasing tendency when pH reached to 6.2-7.4, and to maximum at pH 7.4, then gradually decreased at range of pH 7.4-9.2. It is concluded that the Cu²⁺ crossing human erythrocyte has been confirmed to be the first order kinetics characteristics within 120 min, and the linear equation is 10³ × Y = 0.0497t +6.5992.
Copper ; pharmacology ; Erythrocyte Membrane ; drug effects ; Humans ; Hydrogen-Ion Concentration ; Kinetics ; Temperature

Lyophilization of human red blood cells has important significance in clinical application. Some sugars, especially trehalose, can be more tolerant of some organism or cells to dry environments, But, how to bring sugars into cells is a challenge. This study was aimed to investigate the regularity of sugar-uptake in human red blood cells. The absorption rate of trehalose and glucose in red blood cells, free hemoglobin level and erythrocyte deformation index were determined at different incubation temperature (4, 25 and 37 degrees C), different sugar concentration (0, 0.2, 0.4, 0.6, 0.8 and 1 mol/L) and different incubation time (1, 3, 5, 7 and 9 hours). The results showed that with increase of temperature and extracellular sugar concentration, the uptake of sugar in red blood cells also increased, the intracellular trehalose and glucose concentrations were over 30 mmol/L and 40 mmol/L respectively. The effects of incubation time on uptake of trehalose and glucose were different. With prolonging of incubation time, the uptake of trehalose showed firstly increase and then decrease, however, the uptake of glucose showed a constant increase. But the loading process had side-effect on free hemoglobin and maximum deformation index (MAXDI) of red blood cells, especially for trehalose, which mainly come from high osmotic pressure. It is concluded that the uptake of sugars in red blood cells is closely dependent on incubation temperature, extracellular sugar concentration and incubation time. In certain condition, the efficiency of sugar uptake is very high, but this process also damages red blood cells so as to affect the application of sugars in lyophilization of red blood cells. The research in the future should focus on how to deal with the relation between cell injury and uptake efficiency of sugar in red blood cells.
Blood Preservation ; adverse effects ; Cryoprotective Agents ; pharmacokinetics ; Erythrocyte Membrane ; drug effects ; Erythrocytes ; metabolism ; Freeze Drying ; Glucose ; pharmacokinetics ; Humans ; Trehalose ; pharmacokinetics

Lyophilization is the best method for preservation of blood cells at present. Lyophilized blood cells could be stored at room temperature for long periods of time, while maintaining a high degree of viability. Lyophilized blood cells facilitates transportation and the costs are low. However, the membrane of blood cells is damaged and viability of blood cells is decreased in lyophilization. Trehalose has been shown to protect membrane, proteins and nucleic acids during freezing and desiccation. Now, researchers present a methor for loading blood cells with trehalose. In this paper, damage effect of lyophilization on blood cells, the mechanism of trehalose protection and the experimental studies on trehalose were reviewed.
Blood Preservation ; methods ; Cryopreservation ; methods ; Cryoprotective Agents ; pharmacology ; Erythrocyte Membrane ; metabolism ; Erythrocytes ; drug effects ; Freeze Drying ; methods ; Humans ; Trehalose ; pharmacology

This study was aimed to evaluate the effect of benzyl alcohol on trehalose-loading red blood cells (RBCs). The RBCs were incubated in 10, 30, 50 and 100 mmol/L concentrations of benzyl alcohol-trehaloe solution at 4 degrees C for 24 hours. The hemolysis rate of loaded RBCs was detected by using cyanohemoglobin kit, the intracellular trehalose level were assayed by sulfate anthrone method. The results showed that the intracellular trehalose concentration in group with 100 mmol/L benzyl alcohol was 72 +/- 12.98 mmol/L, compared with that in groups of 10, 30 and 50 mmol/L, the statistical difference were significant (p = 0.000); the hemolysis rate of loaded RBCs in group with 100 mmol/L of benzyl alcohol was 17.99 +/- 3.75%, as compared with groups of 10, 30 and 50 mmol/L, the statistical difference was significant (p = 0.000). It is concluded that benzyl alcohol can enhance the intracellular trehalose concentration. As concentration of benzyl alcohol ascends, the intracellular trehalose concentration increases. 100 mmol/L benzyl alcohol may be proper for loading RBCs.
Benzyl Alcohol ; pharmacology ; Blood Preservation ; methods ; Erythrocyte Membrane ; metabolism ; Erythrocytes ; drug effects ; metabolism ; Freeze Drying ; methods ; Humans ; Trehalose ; metabolism ; pharmacology

Though high concentration of glucose can benefit the survival of lyophilized human red blood cells, the high concentration of glucose can result in serious damage of red blood cells. This study was aimed to investigate the inhibitory effect of trehalose on damage of red blood cells induced by high concentration of glucose. After incubation with the high concentration of glucose buffer containing different concentrations of trehalose for three hours at 37 degrees C, the phosphatidylserine exposure and the osmotic fragility of cells were analyzed by flow cytometry and the lipid peroxidation of membrane was evaluated by TBA method. The results showed that the high concentration of glucose could lead to phosphatidylserine exposure, osmotic fragility increase, and lipid peroxidation damage which were dependent on the glucose concentrations and incubation temperature. However, trehalose could effectively prevent the phosphatidylserine exposure, osmotic fragility increase, and lipid peroxidation damage induced by high concentration glucose. With increase of the trehalose concentrations. As the trehalose concentration increases, the phosphatidylserine exposure, maloni-aldehyde concentration and cell debris rate decreased gradually. In conclusion, the high concentration of glucose can lead to phosphatidylserine exposure, osmotic fragility increase, and lipid peroxidation damage of red blood cells. However, trehalose can inhibit the damaging effects of high concentration of glucose on red blood cells, which may be useful for the application of sugars to lyophilization of red blood cells.
Blood Preservation ; methods ; Erythrocyte Membrane ; drug effects ; metabolism ; Erythrocytes ; drug effects ; Flow Cytometry ; Glucose ; adverse effects ; Humans ; Lipid Peroxidation ; drug effects ; Membrane Lipids ; metabolism ; Osmotic Fragility ; drug effects ; Phosphatidylserines ; pharmacology ; Trehalose ; pharmacology

The present paper was aimed to explore the effect of Shuxuetong on the membrane viscoelasticity of erythrocyte taken from the acute phase patients suffering from chronic pulmonary heart disease. The membrane viscoelasticity of erythrocyte was taken from the acute phase patients suffering from chronic pulmonary heart disease. The changes of membrane viscoelasticity of erythrocyte after treated with shuxuetong were detected by micropipette aspiration technique. The results showed that the Shuxuetong of certain concentration could cause the decrease of membrane elastic modulus and viscous coefficients in acute phase patients suffering from chronic pulmonary heart disease. The study offers experimental evidences that the comprehensive treatment of pulmonary heart disease should involve the drug or measure to improve the erythrocyte deformability.
Aged ; Blood Viscosity ; drug effects ; Chronic Disease ; Drugs, Chinese Herbal ; therapeutic use ; Elasticity ; drug effects ; Erythrocyte Deformability ; physiology ; Erythrocyte Membrane ; physiology ; Erythrocytes ; physiology ; Female ; Humans ; Male ; Middle Aged ; Phytotherapy ; Pulmonary Heart Disease ; blood ; drug therapy

OBJECTIVETo study the toxicity of methomyl to acetylcholinesterase (AChE) in different regions.

METHODSThe optimal temperature and time for measurement of AChE activity were determined in vitro. The dose- and time-response relationships of methomyl with AChE activity in human erythrocyte membrane, rat erythrocyte membrane, cortical synapses, cerebellar synapses, hippocampal synapses, and striatal synapses were evaluated. The half maximal inhibitory concentration (IC50) and bimolecular rate constant (K) of methomyl for AChE activity in different regions were calculated, and the type of inhibition of AChE activity by methomyl was determined.

RESULTSAChE achieved the maximum activity at 370 °C, and the optimal time to determine initial reaction velocity was 0-17 min. There were dose- and time-response relationships between methomyl and AChE activity in the erythrocyte membrane and various brain areas. The IC50 value of methomyl for AChE activity in human erythrocyte membrane was higher than that in rat erythrocyte membrane, while the Ki value of methomyl for AChE activity in rat erythrocyte membrane was higher than that in human erythrocyte membrane. Among synapses in various brain areas, the striatum had the highest IC50 value, followed by the cerebellum, cerebral cortex, and hippocampus, while the cerebral cortex had the highest Ki value, followed by the hippocampus, striatum, and cerebellum. Lineweaver-Burk diagram demonstrated that with increasing concentration of methomyl, the maximum reaction velocity (Vmax) of AChE decreased, and the Michaelis constant (Km) remained the same.

CONCLUSIONMethomyl is a reversible non-competitive inhibitor of AChE. AChE of rat erythrocyte membrane is more sensitive to methomyl than that of human erythrocyte membrane; the cerebral cortical synapses have the most sensitive AChE to methomyl among synapses in various brain areas.

Acetylcholinesterase ; metabolism ; Animals ; Cerebellum ; drug effects ; Cerebral Cortex ; drug effects ; Erythrocyte Membrane ; drug effects ; enzymology ; Hippocampus ; drug effects ; Humans ; Inhibitory Concentration 50 ; Methomyl ; toxicity ; Rats ; Synapses ; drug effects ; Toxicity Tests

This study was aimed to investigate the feasibility of cryopreserving red blood cells (RBCs) by loading with trehalose and to evaluate the effect of trehalose on lyophilized RBCs. Based on the thermal properties of RBC plasma membrane, the RBCs were incubated in 0.8 mol/L trehalose solution at 37 degrees C for 7 hours, and RBCs incubated in phosphate-buffered saline were used as control. The morphology of RBCs was observed by light and scanning electron microscopy, the hemolysis rate of loaded RBCs was detected by using cyanohemoglobin kit, the intracellular trehalose levels were assayed by sulfate anthrone method, the intracellular ATP and 2, 3-DPG levels were determined by bioluminescence assay and 2, 3-DPG kit respectively, meanwhile the deformation and osmotic fragility of RBCs were measured. The results showed that the intracellular trehalose concentration was 36.56 +/- 7.95 mmol/L, the electronical microscopic images of trehalose-loaded RBCs showed the membrane integrity, the hemolysis rate in trehalose-loaded RBCs was 15.663 +/- 3.848%, while hemolysis rate in controlled RBC was 5.03 +/- 1.85% (P < 0.05). Maximum index of deformation in trehalose-loaded RBC was 0.0289 +/- 0.00738, while maximum index of deformation in control group was 0.1200 +/- 0.0121 (P < 0.05), The level of ATP in trehalose-loaded RBC was 2.67 +/- 0.54 micromol/gHb, while the level of ATP in control group was 5.22 +/- 1.10 micromol/gHb (P > 0.05). Osmotic fragility data showed that trehalose exerted osmotic protection on RBC. During loading period the level of 2, 3-DPG in trehalose-loaded RBC was maintained close to the level in control. When trehalose-loaded RBCs were lyophilized and rehydrated, the recovery rate of hemoglobin was about 46.44 +/- 4.14% and that in control was 8.33 +/- 2.34% (P < 0.001). The recovery rate of hemoglobin of trehalose-loaded RBC was higher than that of control. It is concluded that trehalose can be integrated in the membrane of RBC in lyophilization state, maintain the integrity of RBC membrane, and significantly enhance the recovery rate of hemoglobin of cryopreserved RBCs. Cryopreserving RBCs by loading with trehalose is feasible.
Blood Preservation ; methods ; Cells, Cultured ; Cryoprotective Agents ; pharmacology ; Erythrocyte Membrane ; metabolism ; Erythrocytes ; metabolism ; Freeze Drying ; methods ; Hemolysis ; drug effects ; Humans ; Trehalose ; pharmacology