Mechanical control of the time-course of contraction of the frog heart.
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Changes in load during most phases of an isotonic contraction of the frog and turtle heart increased or decreased the duration of the twitch. It was abbreviated by a maintained increase or by a brief decrease in load. The relaxing effect of these procedures developed with a delay lasting more than a second under some conditions and will be called lengthening deactivation. The reverse procedures, a maintained diminution or a brief increase in load, increased the duration of the twitch. This effect will be called shortening activation. Although the termination of relaxation may be delayed or advanced by the mechanical interventions mentioned, the normal time-course of isotonic relaxation was always resumed later, regardless of the starting level of the load, making it possible to measure accurately changes in the duration of the twitch. The responses to changes in load produce positive feedback during the isotonic contraction and explain, at least in part, the difference in the time-course of isotonic and isometric contraction. The effects of changes in load were much smaller and briefer in the atrium than the ventricle. (+info)
Electrical characteristics of frog atrial trabeculae in the double sucrose gap.
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The electrical behavior of small single frog atrial trabeculae in the double sucrose gap has been investigated. The currents injected during voltage clamp experiments did not behave as predicted from the assumption of spatial uniformity of the voltage across a Hodgkin-Huxley membrane. Much of the difference is due to the geometrical complexities of this tissue. Nonetheless, two transient inward currents have been identified, the faster of which is blocked by tetrodotoxin (TTX). The magnitude of the slower transient varies markedly between preparations but always increases in a given preparation with increase of external calcium. The fast transient current traces, at small to intermediate depolarizations, are often marred by the presence of notches and secondary peaks due most probably to the loss of space clamp conditions. In many preparations these could be removed by reducing the current magnitude through application of a partially-blocking dose of TTX. Conversely, in the preparations whose fast transient was fully blocked by TTX, notches and secondary peaks in the slow transient could by induced through increasing calcium concentration and thereby the slow current magnitude. Previously used techniques for the measurement of the reversal potential of the fast inward transient have been shown to be invalid. In so far as they can be measured, the reversal potentials of the fast and slow inward transient are in the same neighborhood, i.e. around 120 mV from rest. The true values may be quite a bit apart. The total charge flow in the capacitive transient was measured for different sized nodes and preparations. From these data and estimates of plasma membrane area per unit trabecular volume, specific membrane capacitances of around 3 muF/cm2 were calculated for small bundles. The apparent ion current densities on this basis are approximately 1/10 of those measured in axons. The capacitive current occurring in small bundles decayed as the sum of at least three exponential functions of time. On the basis of these data and the anomalously large stable node widths, we suggest a coaxial core model of the preparation with the inner elements in series with an additional large extracellular resistance. (+info)
Angiotensin II antagonist prevents electrical remodeling in atrial fibrillation.
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BACKGROUND: The blockade of angiotensin II (Ang II) formation has protective effects on cardiovascular tissue; however, the role of Ang II in atrial electrical remodeling is unknown. The purpose of this study was to investigate the effects of candesartan and captopril on atrial electrical remodeling. METHODS AND RESULTS: In 24 dogs, the atrial effective refractory period (AERP) was measured before, during, and after rapid atrial pacing. Rapid atrial pacing at 800 bpm was maintained for 180 minutes. The infusion of saline (n=8), candesartan (n=5), captopril (n=6), or Ang II (n=5) was initiated 30 minutes before rapid pacing and continued throughout the study. In the saline group, AERP was significantly shortened during rapid atrial pacing (from 149+/-11 to 132+/-16 ms, P<0.01). There was no significant difference in AERP shortening between the saline group and the Ang II group. However, in the candesartan and captopril groups, shortening of the AERP after rapid pacing was completely inhibited (from 142+/-9 to 147+/-12 ms with candesartan, from 153+/-15 to 153+/-14 ms with captopril, P=NS). Although rate adaptation of the AERP was lost in the saline group, this phenomenon was preserved in the candesartan and captopril groups. CONCLUSIONS: The inhibition of endogenous Ang II prevented AERP shortening during rapid atrial pacing. These results indicate for the first time that Ang II may be involved in the mechanism of atrial electrical remodeling and that the blockade of Ang II may lead to the better therapeutic management of human atrial fibrillation. (+info)
Effects of experimental heart failure on atrial cellular and ionic electrophysiology.
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BACKGROUND: Congestive heart failure (CHF) is frequently associated with atrial fibrillation (AF), but little is known about the effects of CHF on atrial cellular electrophysiology. METHODS AND RESULTS: We studied action potential (AP) properties and ionic currents in atrial myocytes from dogs with CHF induced by ventricular pacing at 220 to 240 bpm for 5 weeks. Atrial myocytes from CHF dogs were hypertrophied (mean+/-SEM capacitance, 89+/-2 pF versus 71+/-2 pF in control, n=160 cells per group, P<0.001). CHF significantly reduced the density of L-type Ca(2+) current (I(Ca)) by approximately 30%, of transient outward K(+) current (I(to)) by approximately 50%, and of slow delayed rectifier current (I(Ks)) by approximately 30% without altering their voltage dependencies or kinetics. The inward rectifier, ultrarapid and rapid delayed rectifier, and T-type Ca(2+) currents were not altered by CHF. CHF increased transient inward Na(+)/Ca(2+) exchanger (NCX) current by approximately 45%. The AP duration of atrial myocytes was not altered by CHF at slow rates but was increased at faster rates, paralleling in vivo refractory changes. CHF created a substrate for AF, prolonging mean AF duration from 8+/-4 to 535+/-82 seconds (P<0.01). CONCLUSIONS: Experimental CHF selectively decreases atrial I(to), I(Ca), and I(Ks), increases NCX current, and leaves other currents unchanged. The cellular electrophysiological remodeling caused by CHF is quite distinct from that caused by atrial tachycardia, highlighting important differences in the cellular milieu characterizing different clinically relevant AF substrates. (+info)
The effect of quinidine on membrane electrical activity in frog auricular fibres studied by current and voltage clamp.
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1 The action of quinidine sulphate 50 muM has been investigated on frog auricular trabeculae transmembrane currents recorded with a double sucrose gap apparatus. Results were obtained either in current or in voltage clamp conditions. 2 Quinidine modified the time course of repetitive activity elicited by long lasting depolarizing currents and reduced the range of current over which repetitive activity could be triggered, eventually abolishing repetitive responses altogether. 3 Several authors have emphasized the limitations of the voltage clamp method. Taking into account these limitations, the numerical values of the parameters obtained in the present work must not be considered as exact values but may be interpreted as indicators of the variations of the parameters. 4 The results are in agreement with previous findings that the main features of the action of quinidine are to produce (a) a reduced maximum rate of depolarization (MRD), (b) a reduced total amplitude of action potential, (c) a flattening of the plateau of the action potential, (d) a slight prolongation of the tail of the action potential, (e) an increased effective refractory period without greatly prolonging action potential duration, (f) no change of resting potential and of 50% repolarization time. 5 The analysis of ionic conductances has provided explanations for the above effects. 6 Quinidine reduced the reactivation kinetics of the sodium inward current, and decreased sodium conductance and the steady state of activation. These effects account for (a) and (b). 7 Quinidine increased the activation and inactivation time constants of sodium conductances, which account in part for (e). 8 Quinidine delayed reactivation of slow inward current, reduced calcium conductance, and decreased the steady state of activation of calcium conductance. These effects could account for (c). 9 The amplitudes of the two components of the delayed conductances responsible for repolarization were decreased by quinidine, and the time constant of activation for the faster of the two was slowed. These effects could account for (d) and in part for (e). (+info)
Identification of the pace-maker current in frog atrium.
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1. The nature and interactions of the membrane currents underlying induced pace-maker activity in frog atrial muscle have been investigated using a double sucrose gap technique. 2. The membrane current which controls the speed of the atrial pacemaker depolarization (the pace-maker current, ip), is shown to be an outward current activated within the plateau potential range of a normal action potential. The subsequent deactivation of ip at more negative potentials unmasks the depolarizing action of time-independent inward membrane currents so that a pace-maker potential can result. 3. The deactivation of ip over a limited potential range (between about -30 and -60 mV) can be reliably recorded by switching on the voltage clamp during an induced pace-maker depolarization. 4. Investigation of the time and voltage-dependent behaviour of ip over a much wider potential range is less straightforward. How ip can be separated from other components of outward current present in the decay tails following square voltage clamp depolarizations is described. 5. The majority of such current decay tails contain three components of outward current. It appears that two of these components, one of which is ip, are true Hodgkin-Huxley conductance systems chiefly carrying potassium ions. 6. The nature of the third current, which decays very slowly at moderate membrane potentials (about -40 mV), is discussed and reasons are briefly given for considering it to result from the accumulation of potassium ions in extracellular spaces. Preliminary evidence that potassium depletion occurs at potentials negative to the resting potential of the trabeculum is also presented. 7. Because of the obvious complexities involved, a quantitative analysis of the atrial outward currents is not attempted here but forms the subject of a following paper (Brown, Clark & Noble, 1976a). (+info)
Analysis of pace-maker and repolarization currents in frog atrial muscle.
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1. A quantitative analysis of the time-dependent component of outward membrane current in atrial wall trabeculae from Rana catesbeiana and Rana ridibunda has been carried out using a double sucrose gap technique. 2. Separation of the different components of delayed outward current was hampered by the sigmoid onset of one of the outward current systems ixfast and by the development of potassium ion accumulation which prevented current activation from reaching a steady state at positive membrane potentials. Semilogarithmic analysis of positive current decay tails recorded immediately following square voltage clamp depolarizations was therefore used to separate the two membrane conductance components ixfast and ixslow and the third component, attributable to potassium ion accumulation, which was almost invariably present in the tails. 3. It is shown that inaccuracies in this method of semilogarithmic separation of components caused by visual assessment of the i3 (accumulation) line are minor compared with the large changes in the time constants of ixfast and more especially of ixslow which would result from ignoring the potassium accumulation component. 4. Such semilogarithmic separation of the three components of outward current gave separate activation curves for each of the two membrane conductance components, ixfast and ixslow. 5. Measurement of 'total' activation curves in which all components of outward current were represented could be made more easily and fairly reliably. The position and shape of these activation curves on the voltage axis were found to closely resemble those obtained by three component separation. It is therefore suggested that such a simplified analysis reflects the properties of the individual currents sufficiently well for it to be of use in preliminary studies of, for example, drug action. 6. The kinetic properties of the atrial outward currents have been investigated over a wide potential range. Because of the presence of potassium ion accumulation, an indirect method of obtaining the average value of 1/gamma for outward current decay at negative potentials had to be employed. 7. It is shown that some degree of inward-going rectification is associated with the outward current systems of frog atrium. 8. The possible reasons for the differences between the analysis presented here and those presented earlier by us (Brown & Noble, 1969a, b) and by Ojeda & Rougier (1974) are discussed. (+info)
Involvement of tyrosine phosphorylation in the positive inotropic effect produced by H(1)-receptors with histamine in guinea-pig left atrium.
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We investigated the effect of stimulation of H(1)-receptors with histamine on protein tyrosine phosphorylation levels in guinea-pig left atrium and evaluated the influences of tyrosine kinase inhibitors on the positive inotropic effect mediated by H(1)-receptors in this tissue. Histamine induced an increase in tyrosine phosphorylation in four main clusters of proteins with apparent molecular weights of 25, 35, 65 and 150 kDa. Tyrosine phosphorylation of these proteins attained a peak around 2 - 3 min following histamine stimulation and then declined to or below basal levels. Histamine-induced protein tyrosine phosphorylation was antagonized by the H(1)-receptor antagonists mepyramine (1 microM) and chlorpheniramine (1 microM), but not by the H(2)-receptor antagonist cimetidine (10 microM). The positive inotropic effect of histamine was depressed in a concentration-dependent manner by the tyrosine kinase inhibitors tyrphostin A25 (50 to 100 microM) and genistein (10 to 50 microM) but not by the inactive genistein analogue daidzein (50 microM). The positive inotropic effect of isoprenaline was unchanged by tyrphostin A25 and genistein. At a concentration of 1 microM histamine produced a dual-component positive inotropic response composed of an initial increasing phase and a second and late developing, greater positive inotropic phase. Treatment with tyrphostin A25 (100 microM) and genistein (50 microM), but not daidzein (50 microM), significantly attenuated the two components of the inotropic response, although genistein suppressed the initial component more markedly than the late component. We conclude that increased protein tyrosine phosphorylation may play an important role in initiating at least some part of the positive inotropic effect of H(1)-receptor stimulation in guinea-pig left atrium. (+info)