Scanned-probe detection of electron spin resonance from a nitroxide spin probe

We report an approach that extends the applicability of ultrasensitive force-gradient detection of magnetic resonance to samples with spin-lattice relaxation times (T ₁) as short as a single cantilever period. To demonstrate the generality of the approach, which relies on detecting either cantilever frequency or phase, we used it to detect electron spin resonance from a T ₁ = 1 ms nitroxide spin probe in a thin film at 4.2 K and 0.6 T. By using a custom-fabricated cantilever with a 4 μm-diameter nickel tip, we achieve a magnetic resonance sensitivity of 400 Bohr magnetons in a 1 Hz bandwidth. A theory is presented that quantitatively predicts both the lineshape and the magnitude of the observed cantilever frequency shift as a function of field and cantilever-sample separation. Good agreement was found between nitroxide T ₁ ''s measured mechanically and inductively, indicating that the cantilever magnet is not an appreciable source of spin-lattice relaxation here. We suggest that the new approach has a number of advantages that make it well suited to push magnetic resonance detection and imaging of nitroxide spin labels in an individual macromolecule to single-spin sensitivity.     

Oxidative stress measurement by in vivo electron spin resonance spectroscopy in rats with streptozotocin-induced diabetes

Summary Enhanced oxidative stress in diabetic patients may contribute to the pathogenesis of diabetic angiopathy. We have recently developed a method to determine the electron spin resonance (ESR, electron paramagnetic resonance; EPR) of reactive oxygen species and free radicals in vivo, using the nitroxide derivative, carbamoyl-PROXYL as a probe. In this study, diabetes was induced in Wistar rats by streptozotocin (STZ) injection (65 mg/kg, body weight, intravenously). Two, 4, and 8 weeks later, the animals received carbamoyl-PROXYL (300 nmol/g, intravenously), and ESR was measured at the upper abdominal level at a frequency of 300 MHz. The intensity of the carbamoyl-PROXYL ESR signal decreased gradually after the injection, and the spin clearance rate was determined over the first 5 min. At all time points, the spin clearance rate was significantly greater in the diabetic rats than in control rats. Moreover, the spin clearance rate in the diabetic rats was significantly correlated with urinary malondialdehyde (MDA) levels, which serve as a marker for lipid peroxidation. Daily treatment with 4 units neutral protamin Hagedorn (NPH) insulin for 4 weeks reduced the spin clearance rate in the diabetic rats. Simultaneous injection of carbamoyl-PROXYL and superoxide dismutase reduced the spin clearance rate in the diabetic rats in a dose-dependent manner. Injection of the antioxidant α-tocopherol (40 mg/kg, intraperitoneally) for 2 weeks restored the spin clearance rate in the diabetic rats without concomitant glycaemic restoration. These results suggest that a diabetic state enhances the generation of free radicals in vivo, and that both glycaemic control and antioxidant treatment can reduce this oxidative stress. Non-invasive in vivo ESR measurement may be useful for evaluating oxidative stress in diabetes. [Diabetologia (1998) 41: 1355–1360] Received: 21 January 1998 and in final revised form: 12 June 1998     

DMPO and reperfusion injury: arrhythmia, heart function, electron spin resonance, and nuclear magnetic resonance studies in isolated working guinea pig hearts

With the use of isolated working guinea pig hearts with normothermic global ischemia, it was shown that 5,5-dimethyl-pirroline-N-oxide (DMPO), an organic spin trap agent designed specifically to form stable adducts with oxygen free radicals in electron spin resonance studies, can dramatically reduce the vulnerability of the heart to reperfusion-induced arrhythmias. Studied in concentrations ranging from 10 to 500 mumol/L, DMPO exerted a dose-dependent protective effect. Thus, after 30 minutes of global ischemia, the incidence of ventricular fibrillation (total) and tachycardia was reduced from control values of 100% and 100% to 100% and 100%, 91% and 100%, 25% (p less than 0.001) and 50% (p less than 0.05), and 25% (p less than 0.001) and 41% (p less than 0.05), respectively, with DMPO concentrations of 10, 30, 100, and 500 mumol/L. Maximum signals of DMPO-OH adduct, with the use of electron spin resonance studies, were observed after 3 minutes of reperfusion in fibrillated hearts but were not detected in nonfibrillated hearts. Results of nuclear magnetic resonance studies of myocardial adenosine triphosphate, creatine phosphate, pH, and inorganic phosphate showed that these parameters were not significantly changed by treatment with DMPO, and consequently myocardial heart function was not improved, although there was a dissociation between myocardial adenosine triphosphate content and left ventricular developed pressure during reperfusion. The data presented here indicate that oxygen free radicals play an important role in the development of reperfusion-induced arrhythmias but trapping these cytotoxic free radicals does not improve the recovery of postischemic heart function and high-energy phosphate contents in isolated working guinea pig hearts.     

Direct measurement of oxygen free radicals following cardiac failure of ischemic dog myocardium with the electron spin resonance technique.

OBJECTIVE: To determine whether the involvement of oxygen-derived free radicals in the pathogenesis of ischemic cardiac failure in dogs. DESIGN: Free radicals were measured in normal and ischemic myocardium from dogs with cardiac failure induced by acute coronary occlusion. The changes in free radical production in ischemic myocardium (compared with normal myocardium with or without polymorphonuclear leukocytes) were studies, with plasma superoxide dismutase and malondialdehyde analyzed concurrently. MAIN RESULTS: The results showed that the oxygen free radicals in the ischemic myocardium were about 42.5% higher than those in the normal myocardium, about 67.8% higher than those in the normal myocardium washed with normal saline and about 60.5% higher than those in the ischemic myocardium washed with normal saline (P < 0.05). Compared with controls, the concentration of malondialdehyde in ischemic dog myocardium was increased markedly. The activity of plasma superoxide dismutase was not significantly different between control dogs and dogs with ischemic cardiac failure. CONCLUSIONS: The current results indicate that there was increased production of free radicals and peroxidative damage in ischemic myocardium of dogs with cardiac failure. Polymorphonuclear leukocytes appear to be a main source of free radicals in dog with ischemic cardiac failure.     

Evaluation of the hepatic reduction of a nitroxide radical in rats receiving ascorbic acid, glutathione or ascorbic acid oxidase by in vivo electron spin resonance study

BACKGROUND: A nitroxide radical, 4-hydroxyl-2,2,6,6-tetramethylpiperidin-1-oxyl (TEMPOL), is directly reduced to hydroxylamine by ascorbic acid (AsA). Ascorbic acid is oxidized to dehydroascorbic acid (DHA) by ascorbic acid oxidase (AAOx), and DHA is reduced to AsA by glutathione (GSH). In the present study, in vivo and ex vivo reduction of TEMPOL in the rat liver under various conditions of AsA supply was investigated using an electron spin resonance (ESR) spectrometer equipped with a surface coil-type resonator. METHODS: To investigate in vivo hepatic reduction of TEMPOL, an ESR study of the liver of living rats which orally received AsA or intravenously received GSH or AAOx was made. To investigate direct interactions between TEMPOL and GSH or AAOx, an in vitro ESR study was conducted. To investigate TEMPOL reduction in the hepatic homogenate, an ex vivo ESR study was performed. RESULTS: Ascorbic acid and GSH administration increased the in vivo hepatic reducing ability of TEMPOL. In contrast, AAOx administration decreased the reducing ability. In vitro TEMPOL was not reduced by GSH and hydroxylamine was not oxidized by AAOx. Reducing ability in the hepatic homogenate of AAOx-treated rats decreased, but that for GSH-treated rats was unchanged. CONCLUSION: Ascorbic acid administration directly increases hepatic reducing ability. Ascorbic acid, which increased in the plasma due to GSH administration, entered the liver and enhanced the hepatic reducing ability. Administration of AAOx impaired the hepatic reducing ability by oxidizing AsA in the plasma and/or the liver.     

Stabilization of electron spin resonance probes for photosynthesis studies.

The major obstacle to the study of functional/structural interrelationships of spinach chloroplasts by using spin labels has been the rapid loss of the electron paramagnetic resonance (EPR) signals upon illumination with visible light. The present study demonstrates that the addition of ferredoxin and NADP+ in the presence of N-tris(hydroxymethyl)methylglycine (Tricine) buffer at pH 7.1 or higher mitigates the rapid loss of Biradical X [N,N'-bis(1-oxyl - 2,2,5,5 - tetramethylpyrroline-3-carboxy)-1,2-diaminoethane] and Monradical A (2,2,5,5-tetramethyl-3-carbamidpyrroline-1-oxyl). However, the 5-line EPR spectrum characteristic of Biradical X in aqueous solution was changed to a dominantly 3-line spectrum within a few minutes after illumination in the presence of ferredoxin and NADP+. Analysis of the double integration of the first derivative EPR spectrum revealed no decrease in Biradical X concentration for more than 30 min of illumination. Our data suggest that Biradical X attaches to some soluble macromolecule(s) and that illumination of chloroplasts promotes such an attachment.     

Direct detection of free radicals in the reperfused rat heart using electron spin resonance spectroscopy

The purpose of this study was to use a direct method, that of electron spin resonance (ESR) spectroscopy, to demonstrate that reperfusion after a period of ischemia results in a sudden increase in the production of free radicals in the myocardium. The isolated buffer-perfused rat heart was used with N-tert-butyl-alpha-phenylnitrone (PBN) as a spin-trapping agent. Samples of coronary effluent were taken and extracted into toluene for detection of radical adducts by ESR spectroscopy. After 15 minutes of total, global ischemia, aerobic reperfusion resulted in a sudden burst of radical formation that peaked at 4 minutes. When hearts were reperfused with anoxic buffer, no dramatic increase in radical production was observed. Subsequent reintroduction of oxygen, however, resulted in an immediate burst of radical production of a similar magnitude to that seen in the wholly aerobic reperfusion experiments. The ESR signals obtained (aN = 13.60 G, aH = 1.56 G) are consistent with the spin-trapping by PBN of either a carbon-centered species or an alkoxyl radical, both of which could be formed by secondary reactions of initially-formed oxygen radicals with membrane lipid components.     

Tumor trapping of 5-fluorouracil: in vivo 19F NMR spectroscopic pharmacokinetics in tumor-bearing humans and rabbits.

The pharmacokinetics of 5-fluorouracil (5FU) were studied in vivo in patients with discrete tumors and in rabbits bearing VX2 tumors by using 19F NMR spectroscopy. The human studies were conducted in a 1.5-T Magnetom magnetic resonance imager (Siemens), and the rabbit studies were conducted in a 4.7-T GE/Nicolet 33-cm bore magnet. Free 5FU was detected in the tumors of four of the six patients and in all VX2 tumors but not in normal rabbit tissues. No other metabolites were seen in these tumors, contrary to the extensive catabolism we had previously documented using 19F NMR spectroscopy in both human and animal livers. The tumor pool of free 5FU in those human tumors that trapped 5FU was determined to have a half-life of 0.4-2.1 hr, much longer than expected and significantly longer than the half-life of 5FU in blood (5-15 min), whereas the half-life of trapped 5FU in the VX2 tumors ranged from 1.05 to 1.22 hr. In this initial experience, patient response to chemotherapy may correlate with extent of trapping free 5FU in the human tumors. These studies document that NMR spectroscopy is clinically feasible in vivo, allows noninvasive pharmacokinetic analyses at a drug-target tissue in real time, and may produce therapeutically important information at the time of drug administration. Demonstration of the trapping of 5FU in tumors provides both a model for studying metabolic modulation in experimental tumors (in animals) and a method for testing modulation strategies clinically (in patients).     

Direct measurement of salt-bridge solvation energies using a peptide model system: implications for protein stability.

The solvation energies of salt bridges formed between the terminal carboxyl of the host pentapeptide AcWL- X-LL and the side chains of Arg or Lys in the guest (X) position have been measured. The energies were derived from octanol-to-buffer transfer free energies determined between pH 1 and pH 9. 13C NMR measurements show that the salt bridges form in the octanol phase, but not in the buffer phase, when the side chains and the terminal carboxyl group are charged. The free energy of salt-bridge formation in octanol is approximately -4 kcal/mol (1 cal = 4.184 J), which is equal to or slightly larger than the sum of the solvation energies of noninteracting pairs of charged side chains. This is about one-half the free energy that would result from replacing a charge pair in octanol with a pair of hydrophobic residues of moderate size. Therefore, salt bridging in octanol can change the favorable aqueous solvation energy of a pair of oppositely charged residues to neutral or slightly unfavorable but cannot provide the same free energy decrease as hydrophobic residues. This is consistent with recent computational and experimental studies of protein stability.     

Myocardial ischemia and reperfusion: direct evidence for free radical generation by electron spin resonance spectroscopy.

Electron spin resonance spectroscopy has recently been used by others to detect directly radical species in isolated perfused hearts. Sample processing prior to spectroscopy in this study involved pulverization of tissue, which can artifactually generate radical species. We assessed in isolated perfused hearts the influence of tissue pulverization on the identity of radical species detected by spectroscopy and then, using a processing technique less likely to induce artifacts, whether myocardial ischemia and reperfusion generate radical species. Rat and rabbit hearts (n = 8) were perfused aerobically for 10 min and freeze-clamped to -196 degrees C. Frozen tissue was processed at -196 degrees C for spectroscopic analysis by pulverization vs. chopping. Spectra of pulverized tissue consisted of three components: a semiquinone (g = 2.004), a lipid peroxy radical (g [ = 2.04 and g = 2.006), and a carbon-centered radical that is possibly a lipid radical (giso = 2.002 and AHzz approximately equal to 50 G). Chopped tissue consisted of a single component, a semiquinone (g = 2.004). Rat hearts (n = 8 per group) also underwent 10-min global no-flow normothermic ischemia followed by 5-60 sec of either aerobic or anaerobic reperfusion, with frozen tissue chopped prior to spectroscopy. Spectra of ischemic tissue consisted of an iron-sulfur center and a semiquinone. Aerobic reperfusion resulted in a spectrum similar to the control but with increased amplitude that peaked after 10-15 sec of reflow. Anaerobic reperfusion yielded a spectrum identical to that of ischemic tissue. We conclude that pulverization of frozen myocardial tissue arti-factually generates radical species. Using a nonpulverization technique for tissue processing, we found that myocardial ischemia and reperfusion produce radical species but that molecular oxygen is necessary for the burst of radical production during reflow.     

Evalution of oxidative stress in diabetic animals by in vivo electron spin resonance measurement--role of protein kinase C

Enhanced oxidative stress may be an important contributor to the pathogenesis of diabetic vascular complication. Although hyperglycemia-induced oxidative stress in diabetes has been well documented, exact source in vivo remains to be elucidated. Here we report a role of protein kinase C (PKC) in oxidative stress in diabetic animals using a technique of in vivo electron spin resonance (ESR) measurement that has been developed for direct and non-invasive analysis of free radical generation in living animals. First, using this measurement, we confirmed that streptozotocin-induced diabetic rats which showed a significant increase in free radical generation, which was restored by alpha-tocopherol treatment. Treatment of PKC inhibitor CGP41251 (50 mg/kg) or NAD(P)H oxidase inhibitor apocynin (5 mg/kg) restored the increased free radical generation in those diabetic animals. In conclusion, the present study provided the evidence that PKC-dependent activation of vascular NAD(P)H oxidase may be a major source in enhanced oxidative stress in diabetes in vivo. This may contribute to the pathogenesis of diabetic vascular complications.     

Direct cardiac effects in isolated perfused rat hearts of fentanyl and remifentanil

Opioids are widely used as analgesics to supplement general anaesthesia or as adjunct to anaesthetic agents and for long term analgesia and sedation in intensive care patients. Some clinical studies have suggested that opioids may have different and deleterious haemodynamic effects that remain incompletely examined. We compared the direct cardiac effects of fentanyl and remifentanil in isolated Wistar rat hearts. Twenty rats were randomly assigned to two groups. Hearts were perfused with modified Krebs Henseleit solution and were exposed to 1 x 10(-6) moles(M)/L fentanyl (n=10) in Group I and 1 x 10(-6) M/L remifentanil (n=10) in Group II. Heart rates, contractile force and coronary perfusion were recorded continuously during the study. There was a significant decrease in heart rate and increase in contractility and coronary perfusion in two groups (p<0.001). Fentanyl had less depressant effects on heart rate than remifentanil. We conclude that in isolated rat heart, fentanyl and remifentanil cause direct negative chronotropic and positive inotropic effect. Remifentanil had more depressant effects on heart rate than fentanyl in isolated rat heart.     

31P Nuclear magnetic resonance measurement of cardiac pH in perfused guinea-pig hearts.

Cardiac pH was measured by ³¹P nuclear magnetic resonance spectroscopy. Measurements were made on 23 control hearts perfused with Krebs-Henseleit bicarbonate buffer containing potassium phosphate (1.2 mm) at pH 7.4, but with no external bathing medium. Only one very weak peak could be observed in the orthophosphate region at pH 7.0±0.1. Previous reports have shown a relatively strong line in this region at pH 7.4. The pH 7.0 value was confirmed by perfusion with Krebs-Henseleit bicarbonate-phosphate at pH 7.5, but this time in the presence of an external bathing medium composed of the same buffer. Two peaks were observed in the orthophosphate region. One was at pH 7.0 while the other was at pH 7.5. Replacement of the external bathing medium and perfusate by one free of phosphate (Krebs-Henseleit bicarbonate-Tris-HCl, 1.2 mm Tris plus 1.2 mm KCl, pH 7.4) caused the pH 7.5 peak to disappear but did not affect the pH 7.0 line. Thus, cardiac pH in well-oxygenated, Krebs-Henseleit bicarbonate-phosphate perfused hearts is 7.0, not 7.4. In addition, the magnitude of the observed acidosis associated with coronary artery ligation was about two times smaller (∼0.4 pH units) than that seen in the other studies owing to this difference in control pH. The current value of cardiac pH determined by nuclear magnetic resonance is now in excellent agreement with the values determined by more conventional methods.     

Lateral diffusion of lipids in membranes by pulse saturation recovery electron spin resonance.

Short-pulse saturation recovery electron spin resonance methods have been used to measure lateral diffusion of nitroxide-labeled lipids in multilamellar liposomal dispersions. Nitroxides with 14N and 15N isotopes introduced both separately and together were used. Differential equations have been written and solved for complex saturation recovery signals involving several superimposed exponentials. The time constants contain various combinations of the spin-lattice relaxation time (T1e) for both isotopes, Heisenberg exchange rates, and nuclear spin-lattice relaxation times (T1n). Signals of high quality were fitted by Monte Carlo variation of the amplitudes and time constants. The reliability of the approach was tested extensively by verifying that (i) the predicted number of exponentials agreed with the experimental number, (ii) relaxation parameters that were determined were independent of the observed hyperfine transition, (iii) the time constants were independent of saturating pulse length, (iv) T1e and T1n do not change when Heisenberg exchange is changed by varying the concentration, and (v) Heisenberg exchange is indeed proportional to the concentration. It has been established that bimolecular collision rates over a wide range of conditions can be reliably measured using the methodology described here. The methods depend on the favorable match of bimolecular collision rates at micromolar concentrations to nitroxide spin-lattice relaxation probabilities.     

Assessment of oxidative stress in the spontaneously hypertensive rat brain using electron spin resonance (ESR) imaging and in vivo L-Band ESR.

This study examined the blood brain barrier (BBB)-permeable nitroxyl compound, 3-methoxycarbonyl-2,2,5,5-tetramethylpyrrolidine-1-oxyl (MC-PROXYL), as a spin probe for the assessment of oxidative stress in the brain by electron spin resonance (ESR) imaging and in vivo L-band ESR. Preliminary comparisons were made by ESR imaging of MC-PROXYL in the isolated brains of normal Wistar-Kyoto rats (WKY), spontaneously hypertensive rats (SHR), and stroke prone SHR (SHRSP). The decay of the ESR images of MC-PROXYL in the isolated brains was faster in SHR than in normal WKY, but was only moderate in SHRSP. In addition, the decay rate of MC-PROXYL in the heads of live rats, as measured noninvasively by L-band ESR, was faster in SHR than in WKY, and was slower in SHR than in SHRSP. Taken together, our data suggest that the oxidative stress of SHR is not as high as that in high oxidative stress animal models such as SHRSP. This is the first study to present reconstructed 3D images of the distribution of MC-PROXYL in the isolated SHR brain. The ESR technique employed herein appears to be a powerful tool for evaluating oxidative stress and for detecting the region of oxidative stress in the brain of SHR.     

Spin-label oximetry: kinetic study of cell respiration using a rapid-passage T1-sensitive electron spin resonance display.

An unusual ESR display has been developed that exhibits sensitivity to bimolecular collisions of dissolved oxygen in water with nitroxide radical spin probes at oxygen concentrations as low as 0.1 microM, requiring only 1 microliter of sample. The method involves observation of the ESR rapid-passage signal when tuned to the dispersion using a loop-gap resonator. The bimolecular collision rate determines the phase of the signal. The method has been used in a closed-chamber geometry to study respiration of asynchronous populations of Chinese hamster ovary (CHO) cells. An integral of the Michaelis-Menten equation permits direct comparison with experiment and is shown to be incompatible with the data. The theory of diffusion limitation also is developed and shown to be inconsistent with experiment. The average oxygen concentration is found to decrease as Vmaxt, where t is the time after sealing the chamber, to a critical oxygen concentration of 5.2 microM. Below 5.2 microM, the concentration can be fitted to an exponential form, exp(-t/tau), where tau = 15 sec for 4000 cells per microliter. It is believed that this experimental behavior is determined by complex enzyme kinetics.     

Protective effect of carteolol, a beta-blocker, on myocardial cellular damage in ischemic and reperfused pig hearts: assessment with gated in vivo 31-phosphorus magnetic resonance spectroscopy and electron microscopy.

To assess the effect of carteolol, a beta-blocker, on ischemia and reperfusion, changes in the ultrastructure of myocytes and energy metabolism were studied by 31P-NMR in 41 pig hearts without collateral circulation. The left anterior descending coronary artery was occluded for 20 min and reperfused for 120 min in three groups: seven pigs (group 1, no treatment with carteolol; group 2, pre-ischemia treatment with carteolol (10 micrograms/kg); group 3, post-ischemia treatment with carteolol before reperfusion). Other groups of five pigs were killed after 120 min of ischemia (group 4, no treatment; group 5, pre-ischemia treatment) or 20 min of ischemia (group 6, no treatment; group 7, pre-ischemia treatment). After 20 min of ischemia, ATP was higher in groups 2 (76 +/- 9% of the baseline value) than in group 1 (59 +/- 5%) and group 3 (60 +/- 10%). However, the difference disappeared after 30 min of ischemia. After 120 min of reperfusion, ATP showed much better recovery in group 2 (92 +/- 9%) than in groups 1 (66 +/- 7%) and 3 (68 +/- 10%). Ischemic injury, as viewed by light and electron microscopy, was milder in group 7 than in group 6 after 20 min occlusion, but the myocytes were almost normal after 120 min reperfusion in groups 1 to 3. The heart rate, blood pressure and rate pressure product showed no significant difference among the groups. These results indicate that pre-ischemia treatment with carteolol provided protection against ischemic cellular injury and accelerated the repletion of ATP during reperfusion, but the post-ischemia treatment did not lead to recovery of ATP. Therefore, the favorable effect during reperfusion of pre-ischemia treatment with carteolol depends on its protective effect during ischemia.     

Electron-electron double resonance and saturation-recovery studies of nitroxide electron and nuclear spin-lattice relaxation times and Heisenberg exchange rates: lateral diffusion in dimyristoyl phosphatidylcholine.

Lateral diffusion constants of the stearic acid nitroxide radical spin label 2-(14-carboxytetradecyl)-2-ethyl-4,4-dimethyl-3-oxazolindinyl oxide in dispersions of dimyristoyl phosphatidylcholine have been measured. Electron-electron double resonance methods were used to determine the product of the bimolecular collision frequency and T1e, the electron spin-lattice relaxation time. T1e in turn was measured by the technique of saturation recovery. The theoretical model of Träuble and Sackmann was then used to relate the bimolecular collision frequencies to the diffusion constants. Results are in agreement with other methods. Lower spin-label concentrations than were used in previous electron paramagnetic resonance studies are needed (label-to-lipid ratio less than 0.5 mol%). Analysis of the data also yields values of the nitrogen nuclear spin-lattice relaxation time of the nitroxide moiety. These values are indicative of membrane fluidity.     

Effects of ouabain on membrane fluidity of erythrocytes in essential hypertension. An electron spin resonance study.

In the present study, we have examined the effects of ouabain on membrane fluidity of erythrocytes by use of an electron spin resonance (ESR) and spin-labeling method, and elucidated a possible role of Na+, K(+)-ATPase in the regulation of membrane fluidity in hypertension. Erythrocytes obtained from patients with essential hypertension were examined compared with those from age-matched normotensive subjects, and the ESR spectra for 5-nitroxy stearate incorporated into erythrocyte membranes were studied. The values of outer hyperfine splitting and order parameter (S) of the ESR spectra were significantly higher in patients with essential hypertension than in normotensive subjects. This finding shows that the membrane fluidity of erythrocytes might be lower in essential hypertension. Ouabain loading to erythrocytes decreased the membrane fluidity (S value was increased). The alternative degree was significantly greater in essential hypertension than in normotensive subjects. These results demonstrate that the membrane fluidity of erythrocytes might be highly dependent on the Na+, K(+)-ATPase activity in essential hypertension, which would suggest an abnormality in Na(+)-related cellular functions in hypertension.