Antihemolytic Effect Research Articles

COMPARATIVE EVALUATION OF ANTIOXIDANT AND ANTIHEMOLYTIC CAPACITIES OF PLANTS OF INDIAN ORIGIN USING MULTIPLE ANTIOXIDANT ASSAYS

The present study is concerned with both in-vitro assessment of antioxidant activity and anti-hemolytic effects of Ficus bengalensis, Calendula officinalis and Juglans regia . Total flavonoids and phenolics also were determined by using aluminum nitrate and FolinCiocalteu colorimetric methods respectively. The antioxidant capacity of sample was assessed through reducing power assay, DPPH-scavenging effect,metal chelation assay and superoxide scavenging assay. The extract of Calendula officinalis was found to be more efficient in as antioxidant and anti-hemolytic agents using the in vitro assays as compared to Ficus bengalensis and Juglans regia.

Antihaemolytic and snake venom neutralizing effect of some Indian medicinal plants

Objective To validate traditional claims of usefulness of the Indian plants in management of poisonous snakebite and evaluate the antivenom properties displayed by the alcoholic extracts of Andrographis paniculata ( A. paniculata), Crateva magna ( C. magna), Gloriosa superba ( G. superba) and Hydrocotyle javanica ( H. javanica). Methods These plants were collected, identified and the extracts were prepared by using conventional Soxhlet ethanol extraction technique. The venom neutralization activity was accessed in mice (20-25g) and number of mortalities was observed against clinically important snake (Naja nigricollis) venom. Present study also deals with in vitro membrane stabilizing activity of these plants against hyposaline induced human red blood corpuscles (HRBC). Results Extracts of H. javanica and G. superba gave 80 % and 90 % protection to mice treated with minimum lethal dose of venom (LD 99). These two plants showed significant neutralization effect against the venoms of Naja nigricollis venom. H. javanica and G. superba (25-100 mg/mL) produced significant changes of membrane stabilization of human red blood cells (HRBC) exposed to hyposaline-induced haemolysis. Conclusions We conclude that probably due to presence of various phytochemicals plays an important role in the anti-venom potential of these Indian medicinal plants against Naja nigricollis venom. The above observations confirmed that A. paniculata, C. magna, G. superba and H. javanica plant extracts possess potent snake venom neutralizing capacity and could potentially be used as an adjuvants for antivenin therapy in case of snakebite envenomation, especially against the local effects of cobra venoms.

Anti-haemolytic effect of senicapoc and decrease in NT-proBNP in adults with sickle cell anaemia

Dear Editor: The Gardos channel inhibitor senicapoc is proven to diminish haemolytic anaemia in a Phase II study conducted in adults with sickle cell anaemia (Ataga, et al 2008), and later confirmed in a Phase III study in sickle cell disease subjects as reported in a recent article in the British Journal of Haematology (Ataga, et al 2011). Brain natriuretic peptide is a hormone secreted by ventricular cardiomyocytes in response to stretch (Levin, et al 1998). The plasma level of its propeptide (NT-proBNP) provides a convenient biomarker of cardiac stress, correlating in sickle cell subjects with pulmonary hypertension proven by pulmonary artery catheterization, or estimated by noninvasive Doppler echocardiography (Machado, et al 2006). Increased NT-proBNP in sickle cell adults is associated with lower haemoglobin, high serum lactate dehydrogenase (LDH) and other laboratory variables (Machado, et al 2006, Mekontso Dessap, et al 2008, Mokhtar, et al 2010, van Beers, et al 2008, Voskaridou, et al 2007). Because senicapoc is proven to increase haemoglobin and decrease LDH in sickle cell anaemia (Ataga, et al 2008), we hypothesized that NT-proBNP levels would fall in sickle cell anaemia subjects who respond to senicapoc treatment with increased haemoglobin level. We obtained local regulatory approval to study coded plasma samples from the 2008 Phase II senicapoc trial (Ataga, et al 2008). We procured archived plasma samples from that trial, and measured NT-proBNP by the same standard clinical laboratory assay we have previously reported in sickle cell anaemia (Machado, et al 2006). In the 53 treated subjects, NT-proBNP levels declined by a nonsignificant degree. However, when the analysis was restricted to the 35 subjects (66%) who responded to senicapoc with a rise in total Hb of at least 5 gm/L, significant changes were observed in NT-proBNP and other markers. Subjects who responded to 6mg daily or 10mg daily were analyzed together as a single group. Among these 35 senicapoc responders, baseline NT-proBNP fell by 26% (geometric mean 97 vs. 72 ng/l, p<0.01, paired t-test, log transformed values; Fig. 1). Haemoglobin levels increased by 13% (mean 79 ± 2 vs. 89 ± 2 gm/L, mean ± SEM, p<0.001, paired t-test; Fig. 2A), as expected in this group defined by senicapoc-induced rise in haemoglobin. Serum LDH levels fell 22% (geometric mean 466 vs. 365 iu/l, p<0.001, paired t-test, log transformed values; Fig. 2B), serum bilirubin levels dropped 35% (67.2 vs. 44.5 µmol/l, p<0.001; Fig. 2C), and percentage reticulocytes declined (12.5 vs. 8.6%, p<0.001; Fig. 2D). These results suggest that senicapoc simultaneously diminished both haemolysis and NT-proBNP in a subgroup of subjects. Figure 1 NT-proBNP levels before and after senicapoc therapy. White bar indicates baseline plasma NT-proBNP level prior to initiating oral senicapoc therapy in 35 adults with sickle cell anaemia. The black bar indicates plasma NT-proBNP level on day 85 of senicapoc ... Figure 2 Indicators of haemolytic severity before and after senicapoc therapy. White bars indicate baseline values prior to initiating oral senicapoc therapy in 35 adults with sickle cell anaemia. The black bars indicate values on day 85 of senicapoc therapy in ... A limitation in our study is that only two-thirds of these senicapoc subjects had a sufficient increase in haemoglobin to observe the linked decrease in NT-proBNP, and inclusion of the senicapoc nonresponders obscures this NT-proBNP change. This study was also not prospectively designed to determine the efficacy of senicapoc in reducing NT-proBNP, and the results should be interpreted with caution. However, the findings support important concepts linking haemolytic anaemia to elevated pulmonary arterial pressure. A similar decline in NT-proBNP also has been reported in patients with another chronic haemolytic anaemia, paroxysmal nocturnal hemoglobinuria, in whom hemolysis was reduced by use of the drug eculizumab (Hill, et al 2010). We also have reported downward trends in NT-proBNP and significant decline in pulmonary artery systolic pressure estimated by Doppler echocardiography in several sickle cell anaemia patients in whom hydroxycarbamide produced robust increase in foetal haemoglobin and significant reduction in serum LDH (Olnes, et al 2009). Severity of chronic haemolytic anaemia is linked to high levels of the functional cardiac marker NT-proBNP, and three mechanistically different pharmacological interventions that attenuate intravascular hemolysis also reduced NT-proBNP in these two pathologically distinct haemolytic anaemias. Our result suggests that reducing hemolysis in sickle cell anaemia results in lower NT-proBNP, previously shown to serve in this population more as a biomarker of mean pulmonary artery pressure than of left ventricular dysfunction (Machado, et al 2006). Additional research directed at reducing hemolysis is warranted as a potential means to reduce NT-proBNP and improve pulmonary hypertension in sickle cell disease.

Antioxidant Properties of Indigenous Raw and Fermented Salad Plants

This study evaluates the antioxidant potential of selected plant species by assessing three parameters: antioxidant inhibition of hydrogen peroxide induced hemolysis, free radical scavenging activity and presence of superoxide dismutase activity. Protection against hemolysis was assessed by the rabbit erythrocyte hemolysis assay while free radical scavenging activity was estimated spectophotometrically using 2,2–diphenyl-1-picrylhydrazil as the scavenger. Superoxide dismutase was assessed by measuring the inhibition by superoxide dismutase on the reaction of xanthine oxide generated superoxide radical with a tetrazolium salt. The best protection against hydrogen peroxide induced hemolysis was by extracts of lemon grass (Cymbopogon citratus) leaves. Hempedu bumi (Andrographis paniculata), garlic (Allium sativum) and turmeric (Curcuma domestica) also showed significant anti-hemolytic effect. Good free radical scavenging activity was shown by raw and fermented bean (Phaseolus vulgaris), hempedu bumi (Andrographis paniculata) and ulam raja (Cosmos caudatus). Ulam raja (Cosmos caudatus), lemon grass, hempedu bumi and turmeric showed significant superoxide dismutase activity. The antioxidant potential of Andrographis paniculata was good as evident by the three parameters assayed. However, neem (Azadirachta indica) has limited antioxidant potential. Plants with good antioxidant capabilities include lemon grass and garlic.

The antioxidant and membrane-stabilizing properties of 1-(4-substituted phenyl)-2h-(phenyl)-3-aminopropan-1-ol hydrochlorides in vitro

In vitro model systems were used to study the antioxidant and membrane-stabilizing properties of 1-(4-substituted phenyl)-2H-(phenyl)-3-aminopropan-1-ol hydrochlorides. These secondary aminopropanols, whose synthesis is first reported here, were found not to have any significant antioxidant or antiradical activity either in an ascorbate-dependent Fe(II)-stimulated peroxidation system, in a method based on the spectrophotometric monitoring of decreases in the concentration of the stable radical 1,1-diphenyl-2-picrylhydrazyl, or in the photochemiluminescence analysis method. However these compounds had marked antihemolytic effects in an erythrocyte oxidative stress model. It is suggested that the new 1-(4-substituted phenyl)-2H-(phenyl)-3-aminopropan-1-ol hydrochlorides are biologically active compounds with weak antioxidant properties, capable of membrane-stabilizing actions due to interaction with the structural components of cell membranes.

Inhibition of oxidative hemolysis by quercetin, but not other antioxidants

We previously reported that lipid-soluble quercetin, not water-soluble dihydroquercetin, protects human red blood cells against oxidative damage. The objectives of this study were to determine if an antihemolytic effect could be produced by other lipid-soluble antioxidants and if anti-inflammatory activity played a role in antihemolysis by quercetin. This study compared three lipid-soluble polyphenols, muscadine, curcumin and quercetin, and three lipid- (α-tocopherol and α-tocotrienol) or water-soluble (ascorbic acid) vitamins. Among the tested polyphenols, muscadine was the most potent in inhibiting superoxide and 2,2-azobis(2-amidinopropane) dihydrochloride (AAPH)-generated peroxyl radicals, whereas ascorbic acid was the most potent inhibitor of hydrogen peroxide. Activities of the polyphenols after lipid extractions showed that curcumin inhibited superoxide production to a greater extent than quercetin and muscadine. All blood cells were tested 20 min after incubation with the selected compounds. All the polyphenols caused inhibition of N-formyl- l-methionyl- l-leucyl- l-phenylalanine-induced neutrophil oxidative bursts. Quercetin, but not other polyphenols, significantly reduced AAPH-induced oxidative hemolysis. No significant effect on neutrophil oxidative burst or oxidative hemolysis was found with any of the tested vitamins. These results suggest that quercetin enhances the resistance of membrane to destruction by free radicals. This effect of quercetin is not directly mediated through antioxidative or anti-inflammatory actions. Antioxidant or anti-inflammatory potency may not be used as a simple criterion to select polyphenols for cell protection benefits.

Comparison of quercetin and dihydroquercetin: Antioxidant-independent actions on erythrocyte and platelet membrane

We investigated the effects of two flavonoids quercetin and dihydroquercetin (DHQ), which have different solubilities and antioxidant capacities, on hemolysis and platelet aggregation in human blood. Exposure of human red blood cells (RBCs) to free radicals generated by 2,2′-azobis(2-amidinopropane) dihydrochloride (AAPH) for 2 h resulted in 63.5 ± 3.9% hemolysis (vehicle: 0.3 ± 0.4%). Pre-incubation of RBCs with lipid-soluble quercetin and water-soluble DHQ for 30 min significantly reduced the AAPH-induced hemolysis to 3.6 ± 1.5% and 32.5 ± 5.6% respectively. In contrast, quercetin and DHQ were similarly effective in reducing phospholipase C-induced hemolysis (37.2 ± 9.1% and 45.4 ± 10.0% versus vehicle 75.7 ± 5.2%, P < 0.001). Pre-incubation with quercetin, but not DHQ, inhibited the aggregation of platelets by adenosine diphosphate. DHQ was more potent than quercetin in inhibiting superoxide produced by xanthine oxidase. These results suggest that the antihemolytic effects of flavonoids may not be directly mediated by removal of free radicals and may likely be due to their interaction with cell membrane.

Studies of the antioxidant and antihemolytic activity of quinoline derivatives in a model of oxidative damage to erythrocyte membranes

New benzo-substituted 4-(aminophenylamino)-2-methylquinolines, 3-substituted 4-hydroxy(chloro and mercapto)quinolines, and thienoquinolines were synthesized. A model system based on oxidative damage to erythrocyte membranes induced by the combined actions of hydrogen peroxide and ionizing radiation was used to study the antihemolytic effects of these compounds as a means of assessing their antiradical/antioxidant properties. In the absence of x-rays, substances of the 3-substituted 4-hydroxy(chloro and mercapto)quinoline and thienoquinoline series were found to have marked antihemolytic effects, associated with significant influences on the structural stability of erythrocytes. However, with irradiation, the membrane-protecting effects were more marked with benzo-substituted 4-(aminophenylamino)-2-methylquinoline derivatives.

Eculizumab Reduces Pulmonary Hypertension through Inhibition of Hemolysis-Associated Nitric Oxide Consumption in Patients with Paroxysmal Nocturnal Hemoglobinuria

The depletion of nitric oxide (NO) by cell-free plasma hemoglobin and arginase during intravascular hemolysis has been implicated in the dysregulation of vasomotor tone and the enhancement of procoagulant and prothrombotic activities. Pulmonary hypertension (PHT), an emerging common complication of hereditary hemolytic anemias, has been mechanistically and epidemiologically linked to intravascular hemolysis and NO depletion. Paroxysmal nocturnal hemoglobinuria (PNH) is a disease characterized by chronic and brisk hemolysis, as well as elevated cell-free plasma hemoglobin. We have previously reported that approximately 50% of PNH patients have PHT as measured by doppler echocardiograpy. Further, the level of N-terminal pro-B-type natriuretic peptide (NT-proBNP) has been generally demonstrated to be a sensitive and specific measure of right-sided cardiac stress due to PHT and has more recently been shown to be a strong predictor of pulmonary hypertension (PHT) and mortality in patients with hemolytic anemias (defined as NT-proBNP ≥ 160 pg/ml). Eculizumab, a terminal complement inhibitor, has been demonstrated to significantly and rapidly reduce hemolysis, thereby providing beneficial effects on regulation of smooth muscle tone and thrombosis in patients with PNH. To evaluate the efficacy of eculizumab in the regulation of cell-free plasma hemoglobin levels, nitric oxide depletion, and subsequent cardiovascular morbidities in patients with PNH. Levels of hemoglobinemia, arginase and nitric oxide depletion were assessed in 73 evaluable eculizumab- and placebo-treated PNH in the phase III randomized, placebo-controlled trial (TRIUMPH). In addition, levels of N-terminal pro-B-type natriuretic peptide (NT-proBNP) were assessed as a measure of PHT, and systolic and diastolic systemic arterial pressures were examined in eculizumab- and placebo-treated patients. At baseline, levels of lactate dehydrogenase (LDH), cell-free plasma hemoglobin, arginase 1 and arginase 1 enzyme activity were highly elevated compared to normal values. Levels of hemolysis and NO consumption were shown to be much greater in PNH (more than 6- and 10-fold, respectively) than in patients with other hemolytic diseases. There were substantial correlations between cell-free plasma hemoglobin levels and both LDH (R = 0.5094) and plasma consumption of nitric oxide (NO) (R = 0.9529). Strong correlations between arginase 1 and both cell-free plasma hemoglobin (R = 0.9367) and arginase 1 enzyme activity (R = 0.9081) were also demonstrated. Following eculizumab therapy, measures of hemolysis were significantly reduced from baseline, including LDH (2200 ± 158 to 327 ± 68 U/L) and cell-free plasma hemoglobin (98.8 ± 23.24 to 15.2 ± 5.05 mg/dL), while levels in placebo-treated patients remained unchanged; a concomitant reduction in NO consumption was also observed (see Figure). In addition, at baseline, 46.6% (34/73) of PNH patients in the TRIUMPH study had levels of NT-proBNP ≥ 160 pg/ml, indicating PHT in these patients. Eculizumab-treated patients showed a 50% reduction in the incidence of PHT over the course of the 26-week treatment period from 52.5% to 26.3%, while PHT did not change with placebo (39.4% to 43.8%; P<0.001). Additionally, eculizumab significantly improved dyspnea (EORTC-QLQ-C30) compared to placebo (Effect size 0.69; P=0.0002). Similarly, eculizumab treatment was associated with a concomitant decrease in systemic arterial blood pressure as compared to patients receiving placebo. To summarize, in patients with hemolytic anemia, the depletion of NO is associated with the development of cardiovascular morbidities, including PHT. The current data demonstrate that intravascular hemolysis in untreated patients with PNH is associated with high levels of plasma ferrous oxyhemoglobin, which stoichiometrically catabolizes NO, and high levels of plasma arginase 1, which catabolizes arginine – all leading to significant depletion of NO. We show a high prevalence of PHT in untreated patients with PNH as indicated by levels of NT-proBNP. Further, the data demonstrate that in a placebo-controlled study, the anti-hemolytic effect of chronic eculizumab treatment significantly increases nitric oxide bioavailability and reduces pulmonary hypertension. [Display omitted]

Erythrocyte Membrane Deformation and Antihemolytic Effect of Antituberculosis Drugs in Rats

Erythrocyte Membrane Deformation and Antihemolytic Effect of Antituberculosis Drugs in Rats

Interaction of flavonoids with red blood cell membrane lipids and proteins: Antioxidant and antihemolytic effects

Plant flavonoids are emerging as potent therapeutic drugs effective against a wide range of free radical mediated diseases. Hence their interactions with cell membranes, which generally serve as targets for lipid peroxidation, are of enormous interest. Here we report in vitro studies, via absorption and fluorescence spectroscopy, on the effects of several flavonoids (namely fisetin, quercetin, chrysin, morin, and 3-hydroxyflavone, 3-HF) in goat RBC membranes. Owing to the presence of functionally relevant membrane protein components embedded in the lipid bilayer RBC ghosts provide a more realistic system for exploring drug actions in biomembranes than simpler membrane models like phosphatidylcholine liposomes used in our previous studies [e.g. B. Sengupta, A. Banerjee, P.K. Sengupta, FEBS Lett. 570 (2004) 77–81]. Here, we demonstrate that binding of the flavonoids to the RBC membranes significantly inhibits lipid peroxidation, and at the same time enhances their integrity against hypotonic lysis. Interestingly, the antioxidant and antihemolytic activities are found to be crucially dependent on the locations of the flavonoids in the membrane matrix as revealed by fluorescence studies. Furthermore, we observe that FRET (from membrane protein tryptophans to flavonoids) occurs with significant efficiency indicating that the flavonoid binding sites lie in close proximity to the tryptophan residues in the ghost membrane proteins.

Inhibitory Effects of Triterpenes Isolated from Chuling (Polyporus umbellatus FRIES) on Free Radical-Induced Lysis of Red Blood Cells

Chuling, sclerotia of Polyporus umbellatus FRIES, has long been used for urological disorders in traditional medicine. In this study, we demonstrated that Chuling in vitro protects red blood cells from 2,2-azo-bis(2-amidinopropane)dihydrochloride (AAPH)-induced hemolysis. The inhibitory effect was dose-dependent at concentrations of 50 to 1000 microg/ml. Moreover, tests were carried out to identify the main ingredient of Chuling with scavenging effect on free radicals. Triterpene carboxylic acids isolated from the methanol extract of Chuling, namely, polyporusterone A and polyporusterone B, were found to have inhibitory activities against AAPH-induced lysis of red blood cells. The anti-hemolytic effect was significantly stronger in polyporusterone B compared with polyporusterone A. Furthermore, the ingestion of 150 mg of Chuling was associated with a significant increase in free-radical scavenging effect of plasma in rats.

Effect of O 2/O 3 atmosphere on the rate of osmotic hemolysis of bovine erythrocytes in the presence of some antioxidants

Purified red blood cells, exposed to an ozone atmosphere, show an increased rate of hemolysis on sudden osmotic stress. To determine this effect of ozone in the presence of natural antioxidants, bovine red blood cells, used as models, were suspended in blood plasma, or in physiological saline with one of the following antioxidants: albumin, glutathione, uric acid, glucose and a vitamin E analog (trolox). After exposure of the suspensions to oxygen and oxygen/ozone atmospheres the rates of osmotic hemolysis were measured, using a stop-flow technique, and compared with rates measured in air-exposed controls. Blood plasma, containing all natural antioxidants, caused a decreased rate of osmotic hemolysis of cells exposed to oxygen and also decreased the effect of ozone. Trolox cancelled the oxygen effects only. Albumin, glutathione and uric acid tended to protect the cells from the hemolytic effects of ozone. The antihemolytic effect of glucose, seen only in some samples, may depend on uncontrolled factors. The alteration of the rates correlates with an increased fluidity of red cell membranes exposed to ozone.

Flunitrazepam partitioning into natural membranes increases surface curvature and alters cellular morphology

In recent studies, we showed that flunitrazepam (FNTZ) and other benzodiazepines interact with artificial phospholipid membranes locating at the polar head group region, inducing a membrane expansion, reducing the molecular packing and reorganising molecular dipoles. In the present paper we investigated the possibility that those phenomena could be transduced into changes in the curvature of membranes from natural origin. Hence we studied the effect of FNTZ on cellular morphology using human erythrocyte as a natural assay system. Shape changes of erythrocytes were evaluated by light microscopy and expressed as a morphological index (MI). FNTZ induced echinocytosis in a time-dependent manner with MI values significantly higher than those of control (without drug) or DMSO (vehicle) samples. Lidocaine, a local anesthetic known to induce stomatocytosis by incorporating in the inner monolayer, counterbalanced the concentration-dependent FNTZ crenating effects. FNTZ induced protective effects, compared with control and DMSO, against time-dependent hemolysis. Hypotonic-induced hemolysis, was also lowered by FNTZ in a concentration-dependent manner. Both antihemolytic effects suggested a drug-induced membrane expansion allowing a greater increase in cell volume before lysis. In such a complex system like a cell, curvature changes triggered by drug partitioning towards the plasma membrane, might be an indirect effect exerted through modifications of ionic-gradients or by affecting cytoskeleton–membrane linkage. In spite of that, the curvature changes can be interpreted as a mechanism suitable to relieve the tension generated initially by drug incorporation into the bilayer and may be the resultant of the dynamic interactions of many molecular fluxes leading to satisfy the spontaneous membrane curvature.

Protective effects of neutral amino acids against amphipathic drug-induced hemolysis.

Some neutral amino acids were compared for their anti-hemolytic effects with sugars which are well-known colloid-osmotic protectants. The kinetic studies in isotonic suspensions of erythrocytes indicated that the hemolysis induced by the amphipathic drug chlorpromazine (CPZ) or flufenamic acid (FA) was retarded by addition of sugars, and the degree of the anti-hemolytic effect increased with increases in molecular size. Phenylalanine (Phe), the largest among the amino acids tested, showed the greatest inhibitory effect on CPZ-induced hemolysis, but not on FA-induced hemolysis. This demonstrated that the anti-hemolytic effects of amino acids were not the result of colloid-osmotic protection. Hemolytic actions of amino acids were also examined to determine their interaction with the erythrocyte membrane, and the mechanism of their inhibitory effects against amphipathic drug-induced hemolysis was discussed.

Effect and safety of liposome-encapsulated hemoglobin neo red cells (NRCs) as a perfusate for total cardiopulmonary bypass.

We developed a liposome encapsulated hemoglobin named Neo Red Cells (NRC), NRC (1) readily circulates, (2) shows a high oxygen transport efficiency, and (3) has a strong capsule membrane. In this study, we evaluated the effect of NRC as a priming solution for total cardiopulmonary bypass (TCPB) using a dog. The TCPB was started after removal of 57.1-73.3% of autologous blood and continued for 7 hours. During TCPB using NRC, the vascular resistance (VR) decreased to 1/4 of VR when red blood cells (RBC) were used. This change suggests that NRC, the viscosity of which is lower than that of RBC, reduced the load on the circulation system. The oxygen volume delivered by NRC was higher than that delivered by RBC, resulting in a greater oxygen consumption with NRC. During TCPB using NRC, the serum LDH level was lower than that using RBC. So we concluded that NRC compensated for the reduction in the oxygen transport ability, which is a disadvantage of dilution TCPB, and further increased the circulation improving effect and anti-hemolytic effect, which are advantages of the procedure. It, thus, enhanced both the safety and effectiveness of dilution TCPB.

Effect of Membrane Incorporation of 1-Palmitoylcarnitine on Surface Charge of Human Erythrocytes

1-Palmitoylcarnitine (1-PC) reduced the electrophoretic mobility of human erythrocytes bathed in low ionic strength solution. Unlike divalent cations which appear to reduce electrophoretic mobility by screening surface negative charge, cationic 1-PC does so by being incorporated into the plasma membrane. Incorporation of 1-PG was assessed directly by measurement of the partition coefficients which are 1.18 × 10 5 and 1.38 × 10 5 in sarcoplasmic reticulum vesicles and erythrocyte ghosts, respectively. The hydrophobic nature of the amphiphile interaction with erythrocyte membrane was also evident as an antihemolytic effect at 1-PC concentrations that also reduced electrophoretic mobility. Moreover, the potency and efficacy of acylcarnitines to reduce electrophoretic mobility increased as the acyl chain length increased. 1-PC also reduced the electrophoretic mobility of guinea-pig ventricular myocytes in low ionic strength solution. Estimation of the zeta potential yielded positive shifts of 4mV in myocytes and 5mV on crythrocytes at 1 μM 1-PC. These voltage shifts are essentially the same as those reported for activation and inactivation of sodium and calcium currents in myocytes. Therefore, the surface charge effect of 1-PC depends upon membrane incorporation and underlies the electrophysiological actions of the amphiphile including arrhythmias.

Detecting membrane impairment caused by xenobiotics

AbstractThe toxicity of 14 substituted anilines and 15 aliphatic alcohols was assessed by the electrorotation of yeast cells. Depending on the applied frequency, control cells exhibit both anti‐ and cofield rotation. From this spectrum, a frequency was selected at which untreated cells do not rotate, but impaired cells rotate with the field. The experimental spectra are fully in accord with theoretical models of the rotational response, calculated on the basis of changes in membrane permeability. High correlations exist between rotational data and physiological and biochemical end points (growth rate, plasma membrane ATPase, purine transport of yeast cells, and antihemolytic assays with human erythrocytes). A Quantitative Structure‐Activity Relationship analysis was made, whereby rotation data from 23 phenols were included. The effects of all chemicals on cell rotation could be predicted by their lipophilicity. Some residuals and deviations could be accounted for by the inclusion of molecular weight or connectivity in the analysis. 4‐Nitrophenol was an outlier, having an effect at least one order of magnitude higher than predicted, suggesting a specific toxic mechanism. Based on lipophilicity and rotation data, the antihemolytic effect on erythrocytes could be accurately estimated. © 1993 John Wiley &amp; Sons, Inc.

Some effects of fructose‐1,6‐diphosphate on rat myocardial tissue related to a membrane‐stabilizing action

This study aims at elucidating the mechanism of action of extracellular fructose-1,6-diphosphate (FDP). FDP is able to inhibit Ca++ entry into the myocardial tissue with an IC50 value of 11.5 mM and in addition, it is bound by rat heart slices, the binding being activated by Zn and conditions of chemical hypoxia induced by KCN and iodoacetate. The overall effect of extracellular FDP includes an increase of frequency and amplitude of contraction of perfused heart at concentration below 1 mM, and, in general, a stimulation of the oxygen consumption of the tissue. The antihaemolytic effect of FDP suggests its action as a membrane stabilizer. The effects of extracellular FDP on the myocardial cell can be interpreted both on the basis of a limited permeability of the cell membrane to it and as a purely extracellular effect transduced through the cell membrane with a final response consisting of an increase in the intracellular FDP.

Follow-up of the antihemolytic effect of toluene inhalation in rats

The antihemolytic effects of toluene were studied with inhalation exposures in vivo. At a concentration of 2000 ppm the effect seemed to begin 0.5 h after the onset of exposure, and it ended completely 0.5 h after the end of the exposure. There was no significant change in the mean corpuscular volume (MCV), although it increased at first during and also following the exposure. The antihemolytic effect of different toluene concentrations was also tested with inhalation exposures. The inhalation of 300–2000 ppm of toluene caused a significant antihemolytic effect in a 1-h exposure, but it did not change the MCV. The greatest antihemolytic effect was obtained with a concentration of 1500 ppm of toluene. Our results confirm the assumption that the effect of toluene as a membrane-stabilizing agent is a reversible phenomenon that requires the presence of the agent molecules during the hemolytic process. The antihemolytic effect does not seem to be caused by an increase in the MCV.