Charly N.W. Belterman

Increased Na+/H+-exchange activity is the cause of increased [Na+]i and underlies disturbed calcium handling in the rabbit pressure and volume overload heart failure model

OBJECTIVEnCytosolic sodium ([Na+]i) is increased in heart failure (HF). We hypothesize that up-regulation of Na+/H+-exchanger (NHE) in heart failure is causal to the increase of [Na+]i and underlies disturbance of cytosolic calcium ([Ca2+]i) handling.nnnMETHODSnHeart failure was induced in rabbits by combined volume and pressure overload. Age-matched animals served as control. [Na+]i, cytosolic calcium [Ca2+]i and cytosolic pH (pH(i)) were measured in isolated left ventricular midmural myocytes with SBFI, indo-1 and SNARF. SR calcium content was measured as the response of [Ca2+]i to rapid cooling (RC). Calcium after-transients were elicited by cessation of rapid stimulation (3 Hz) in the presence of 100 nmol/l noradrenalin. NHE and Na+/K+-ATPase activity were inhibited with 10 micromol/l cariporide and 100 micromol/l ouabain, respectively.nnnRESULTSnAt all stimulation rates (0-3 Hz) [Na+]i and diastolic [Ca2+]i were significantly higher in HF than in control. With increasing frequency [Na+]i and diastolic [Ca2+]i progressively increased in HF and control, and the calcium transient amplitude (measured as total calcium released from SR) decreased in HF and increased in control. In HF (at 2 Hz), SR calcium content was reduced by 40% and the calcium gradient across the SR membrane by 60%. Fractional systolic SR calcium release was 90% in HF and 60% in control. In HF the rate of pH(i) recovery following acid loading was much faster at all pH(i) and NHE dependent sodium influx was almost twice as high as in control. In HF cariporide (10 micromol/l, 5 min) reduced [Na+]i and end diastolic [Ca2+]i to almost control values, and reversed the relation between calcium transient amplitude and stimulation rate from negative to positive. It increased SR calcium content and SR membrane gradient and decreased fractional systolic SR depletion to 60%. Cariporide greatly reduced the susceptibility to develop calcium after-transients. In control animals, cariporide had only minor effects on all these parameters. Increase of [Na+]i with ouabain in control myocytes induced abnormal calcium handling as found in HF.nnnCONCLUSIONSnIn HF up-regulation of NHE activity is causal to increased [Na+]i and secondarily to disturbed diastolic, systolic and SR calcium handling. Specific inhibition of NHE partly normalized [Na+]i, end diastolic [Ca2+]i, and SR calcium handling and reduced the incidence of calcium after-transients. Chronic treatment with specific NHE inhibitors may provide a useful future therapeutic option in treatment of developing hypertrophy and heart failure.

SR calcium handling and calcium after-transients in a rabbit model of heart failure

OBJECTIVEnAfter-depolarization associated arrhythmias are frequently observed in heart failure and associated with spontaneous calcium release from sarcoplasmic reticulum (SR), calcium after-transients. We hypothesize that disturbed SR calcium handling underlies calcium after-transients in heart failure (HF).nnnMETHODSnWe measured the stimulation rate dependence (0.2-3 Hz) of diastolic calcium, calcium transient amplitude and SR calcium content in left ventricular myocytes isolated from hearts of rabbits with pressure and volume overload-induced HF and age-matched control animals. Cytosolic calcium was measured with indo-1. In some experiments, delayed after-depolarizations (DADs) were monitored with the voltage sensitive dye di-4-Annepps. SR calcium content was estimated from the response to rapid cooling (RC). After-transients were elicited in the presence of norepinephrine (100 nmol/l) after cessation of burst pacing.nnnRESULTSnWith increasing stimulation rate (0.2-3.0 Hz): (1) steady state diastolic [Ca](i) increased from 102 to 174 nmol/l in HF and from 44 to 103 nmol/l in control, (2) calcium transient amplitudes decreased from 310 to 254 nmol/l in HF and increased from 186 to 429 nmol/l in control, (3) SR calcium content decreased from 1.25 to 1.09 mmol/l in HF and increased from 1.51 to 2.48 mmol/l in control, (4) in HF and control, the end diastolic SR membrane calcium gradient decreased by about 30%; at any stimulation rate, the magnitude of gradient in HF was one-third of control, (5) systolic depletion of SR was 85% in HF and 60% in control. In HF, noradrenaline (100 nmol/l) increased SR calcium content and SR membrane gradient by 40% versus about 7% in control. Calcium after-transients were observed in 14 out of 18 HF rabbits, and none in eight control animals and were associated with DADs. Calcium after-transients were associated with a 35% decrease in SR calcium content. The frequency of occurrence of calcium after-transients was related to diastolic calcium.nnnCONCLUSIONSnin HF, diastolic calcium is increased and both SR calcium content and SR membrane calcium gradient are decreased in a stimulation rate-dependent manner. In HF, beta-adrenergic stimulation can partly restore the SR calcium content and SR membrane gradient at higher stimulation rates in a meta-stable condition; upon transition to low stimulation rates, the SR membrane can no longer maintain this high unbalanced SR calcium load at increased diastolic calcium, the magnitude of which is causally related to the occurrence of calcium after-transients.

[Na+](i) and the driving force of the Na+/Ca2+-exchanger in heart failure

OBJECTIVEnDiastolic calcium is increased in myocytes from failing hearts despite up-regulation of the principal calcium extruding mechanism the Na+/Ca2+-exchanger (NCX). We hypothesize that increased diastolic calcium ([Ca2+]i) is secondary to increased cytosolic sodium ([Na+]i) and decreased driving force of NCX (DeltaG(exch)).nnnMETHODSnThe stimulation rate dependence of simultaneously measured cytosolic sodium ([Na+]i), calcium transients ([Ca2+]i) and action potentials were determined with SBFI, indo-1 and the perforated patch technique in midmural left ventricular myocytes isolated from rabbits with pressure and volume overload induced heart failure (HF) and in age matched controls. Dynamic changes of DeltaG(exch) were calculated.nnnRESULTSnWith increasing stimulation frequency, 0.2-3 Hz (all data HF versus control): [Na+]i increased (6.4 to 10.8 versus 3.8 to 6.4 mmol/l), diastolic [Ca2+]i increased (142 to 219 versus 47 to 98 nmol/l), calcium transient amplitude decreased in HF (300 to 250 nmol/l) but increased in control (201 to 479 nmol/l), action potential duration (APD90) decreased (380 to 260 versus 325 to 205 ms) and time averaged DeltaG(exch) decreased (6.8 to 2.8 versus 8.7 to 6.4 kJ/mol. With increasing stimulation rate the forward mode time integral of DeltaG(exch) decreased in HF by about 30%, the reversed mode time integral increased about ninefold and the duration of reversed mode operation more than sixfold relative to control.nnnCONCLUSIONSn[Na+]i is increased in HF and the driving force of NCX is decreased. NCX exerts thermodynamic control over diastolic calcium. Disturbed diastolic calcium handling in HF is due to decreased forward mode DeltaG(exch) secondary to increased [Na+]i and prolongation of the action potential. Enhanced reversed mode DeltaG(exch) may account for increased contribution of NCX to e-c coupling in HF.

Chronic inhibition of the Na+/H+‐ exchanger causes regression of hypertrophy, heart failure, and ionic and electrophysiological remodelling

Increased activity of the Na+/H+‐exchanger (NHE‐1) in heart failure underlies raised [Na+]i causing disturbances of calcium handling. Inhibition of NHE‐1, initiated at the onset of pressure/volume overload, prevents development of hypertrophy, heart failure and remodelling. We hypothesized that chronic inhibition of NHE‐1, initiated at a later stage, would induce regression of hypertrophy, heart failure, and ionic and electrophysiological remodelling.

Sublingual microvascular perfusion is altered during normobaric and hyperbaric hyperoxia

Hyperoxia and hyperbaric oxygen therapy can restore oxygen tensions in tissues distressed by ischemic injury and poor vascularization and is believed to also yield angiogenesis and regulate tissue perfusion. The aim of this study was to develop a model in which hyperoxia-driven microvascular changes could be quantified and to test the hypothesis that microcirculatory responses to both normobaric (NB) and hyperbaric (HB) hyperoxic maneuvers are reversible. Sublingual mucosa microcirculation vessel density, proportion of perfused vessels, vessel diameters, microvascular flow index, macrohemodynamic, and blood gas parameters were examined in male rabbits breathing sequential O2/air mixtures of 21%, 55%, 100%, and return to 21% during NB (1.0 bar) and HB (2.5 bar) conditions. The results indicate that NB hyperoxia (55% and 100%) produced significant decreases in microvascular density and vascular diameters (p<0.01 and p<0.05, respectively) accompanied by significant increases in systolic and mean arterial blood pressure (p<0.05, respectively) with no changes in blood flow indices when compared to NB normoxia. HB normoxia/hyperoxia resulted in significant decreases in microvascular density (p<0.05), a transient rise in systolic blood pressure at 55% (p<0.01), and no changes in blood vessel diameter and blood flow indices when compared to NB hyperoxia. All microcirculation parameters reverted back to normal values upon return to NB normoxia. We conclude that NB/HB hyperoxia-driven changes elicit reversible physiological control of sublingual mucosa blood perfusion in the presence of steady cardiovascular function and that the absence of microvascular vasoconstriction during HB conditions suggests a beneficial mechanism associated with maintaining peak tissue perfusion states.

Detection and quantification methods of monocyte homing in coronary vasculature with an imaging cryomicrotome

Cellular imaging modalities are important for revealing the behavior and role of monocytes in response to neovascularization progression in coronary artery disease. In this study we aimed to develop methods for high-resolution three-dimensional (3D) imaging and quantification of monocytes relative to the entire coronary artery network using a novel episcopic imaging modality. In a series of ex vivo experiments, human umbilical vein endothelial cells and CD14+ monocytes were labeled with fluorescent live cell tracker probes and infused into the coronary artery network of excised rat hearts by a Langendorff perfusion method. Coronary arteries were subsequently infused with fluorescent vascular cast material and processed with an imaging cryomicrotome, whereby each heart was consecutively cut (5 μm slice thickness) and block face imaged at appropriate excitation and emission wavelengths. The resulting image stacks yielded 3D reconstructions of the vascular network and the location of cells administered. Successful detection and quantification of single cells and cell clusters were achieved relative to the coronary network using customized particle detection software. These methods were then applied to an in vivo rabbit model of chronic myocardial ischemia in which autologous monocytes were isolated from peripheral blood, labeled with a fluorescent live cell tracker probe and re-infused into the host animal. The processed 3D image stacks revealed homing of monocytes to the ischemic myocardial tissue. Monocytes detected in the ischemic tissue were predominantly concentrated in the mid-myocardium. Vessel segmentation identified coronary collateral connections relative to monocyte localization. This study established a novel imaging platform to efficiently determine the localization of monocytes in relation to the coronary microvascular network. These techniques are invaluable for investigating the role of monocyte populations in the progression of coronary neovascularization in animal models of chronic and sub-acute myocardial ischemia.

Local transmural action potential gradients are absent in the isolated, intact dog heart but present in the corresponding coronary-perfused wedge

The left ventricular (LV) coronary‐perfused canine wedge preparation is a model commonly used for studying cardiac repolarization. In wedge studies, transmembrane potentials typically are recorded; whereas, extracellular electrical recordings are commonly used in intact hearts. We compared electrically measured activation recovery interval (ARI) patterns in the intact heart with those recorded at the same location in the LV wedge preparation. We also compared electrically recorded and optically obtained ARIs in the LV wedge preparation. Five Langendorff‐perfused canine hearts were paced from the right atrium. Local activation and repolarization times were measured with eight transmural needle electrodes. Subsequently, left ventricular coronary‐perfused wedge preparations were prepared from these hearts while the electrodes remained in place. Three electrodes remained at identical positions as in the intact heart. Both electrograms and optical action potentials were recorded (pacing cycle length 400–4000 msec) and activation and repolarization patterns were analyzed. ARIs found in the subepicardium were shorter than in the subendocardium in the LV wedge preparation but not in the intact heart. The transmural ARI gradient recorded at the cut surface of the wedge was not different from that recorded internally. ARIs recorded internally and at the cut surface in the LV wedge preparation, both correlated with optically recorded action potentials. ARI and RT gradients in the LV wedge preparation differed from those in the intact canine heart, implying that those observations in human LV wedge preparations also should be extrapolated to the intact human heart with caution.

Selective subepicardial localization of monocyte subsets in response to progressive coronary artery constriction

Following myocardial infarction and atherosclerotic lesion development, monocytes contribute to myocardial protection and repair, while also partaking in myocardial ischemic injury. The balance of proinflammatory and reparative monocyte subsets is crucial in governing these therapeutic and pathological outcomes. Myocardial ischemic damage displays heterogeneity across the myocardium, whereby the subendocardium shows greatest vulnerability to ischemic damage. In this study we examined the transmural distribution of monocyte subsets in response to gradual coronary artery occlusion. CD14(+) monocytes were isolated from peripheral blood of New Zealand White rabbits and divided into two subgroups based on the expression of CD62L. We employed a rabbit model of progressive coronary artery obstruction to induce chronic myocardial ischemia and reinfused fluorescently labeled autologous monocytes. The distribution of fluorescently labeled autologous monocytes was examined with a high-resolution three-dimensional imaging cryomicrotome. The subepicardial layer contained the largest infiltration of both monocyte subgroups, with a significantly greater proportion of CD14(+)CD62L(+) monocytes at the time when the ischemic area was at a maximum. By targeting CD13(+) angiogenic vessels, we confirmed the presence of angiogenesis in epicardial and midmyocardial regions. These myocardial regions demonstrated the highest level of infiltration of both monocyte subsets. Furthermore, CD14(+)CD62L(+) monocytes showed significantly greater migration towards monocyte chemoattractant protein-1, greater adhesive capacity, and higher expression of C-C chemokine receptor type-2 relative to CD14(+)CD62L(-) monocytes. In conclusion, we note selective subepicardial distribution of monocyte subpopulations, with changes in proportion depending on the time after onset of coronary narrowing. Selective homing is supported by divergent migratory properties of each respective monocyte subgroup.

Simultaneous in Vitro Recording of Electrode Position and Electrograms

A method was developed to localize measurement electrodes within a beating heart in a Langendorff setup. A prototype printed circuit board was build. First results show that it is possible to follow the electrodes during the contraction although the coordinates are distorted.

Response to Letter Regarding Article “Acute Administration of Fish Oil Inhibits Triggered Activity in Isolated Myocytes From Rabbits and Patients With Heart Failure”

We thank Drs Pignier and LeGrand for their interest in our work.1 In their letter, Drs Pignier and LeGrand express their belief that inhibition of the persistent component of the sodium current (INa,P) constitutes a key mechanism of the antiarrhythmic properties of ω3-polyunsaturated fatty acids in heart failure in our study,1 a …