Helge Refsum

Rate-dependent class III antiarrhythmic action, negative chronotropy, and positive inotropy of a novel IK blocking drug, UK-68,798 : potent in guinea pig but no effect in rat myocardium

The electromechanical effects of UK-68,798 (UK), a novel class III antiarrhythmic drug, were studied in guinea pig and rat papillary muscles (PMs) and atria in vitro using conventional microelectrode technique. UK (10−8-10−6 M) prolonged the action potential duration (APD) by 21–58% and effective refractory period in parallel, without affecting the resting potential or maximum rate of depolarization in guinea pig PM stimulated at 1 Hz. UK increased the contractile force without prolonging the time to peak force or relaxation. In comparison, 5 ± 10−5 M d-sotalol was needed to induce the same electrophysiological effects as 10−8 M UK. UK prolonged the APD significantly less at 2 Hz than at 1 and 0.5 Hz. Early afterdepolarizations (EADs) developed in 2 of 11 preparations after 10–6 M at 0.5 Hz. No reversal of drug effect was seen after up to 2 h washout. UK (10−9-10−3 M) reduced the spontaneous heart rate and prolonged the sinus node recovery time of guinea pig right atria. No effects on rat PM or atria, even after 10−5 M, indicate a selective action of UK on the delayed rectifying outward potassium current, Ik. These results indicate a potent and selective, rate-dependent class III antiarrhythmic action of UK-68,798 linked with positive inotropy. Increased APD, bradycardia, and induction of EADs, however, represent a potential arrhythmogenic combination.

Cardiac electrophysiologic and hemodynamic effects related to plasma levels of bupivacaine in the dog.

To investigate electrophysiologic and hemodynamic responses to various plasma levels of bupivacaine, especially those in the range normally seen during regional anesthesia, bupivacaine was given intravenously as a bolus dose followed by continuous infusion in pentobarbital-anesthetized dogs. Cardiac electrophysiology was studied by His bundle electrography, programmed electrical stimulation, and monophasic action potential recordings. At plasma bupivacaine concentrations below 1000 ng/ml, no significant electrophysiologic or hemodynamic effects were observed. This indicates that systemic responses to absorbed bupivacaine do not contribute to the cardiac electrophysiologic effects recently demonstrated during thoracic epidural analgesia. At a plasma level of about 2000 ng/ml, a level occasionally achieved during regional anesthesia, bupivacaine prolonged impulse conduction time in all parts of the heart, prolonged atrial and AV nodal refractoriness, decreased left ventricular inotropy, but had no effect on ventricular refractoriness or monophasic action potential duration. These electrophysiologic effects may enhance susceptibility to reentrant arrhythmias.

Experimental hypothermia: effects of core cooling and rewarming on hemodynamics, coronary blood flow, and myocardial metabolism in dogs.

Conflicting results have been reported as to the extent that cardiovascular function can be reestablished after rewarming from hypothermia. We measured hemodynamic function, myocardial metabolism and tissue water content in dogs core-cooled to 25 degrees C and later rewarmed. At 25 degrees C left ventricular (LV) systolic pressure (LVSP) was 54% +/- 4%, maximum rate of LV pressure rise (LV dP/dtmax) 44% +/- 5%, aortic pressure (AOP) 50% +/- 6%, heart rate (HR) 40% +/- 0%, cardiac output (CO) 37% +/- 5%, myocardial blood flow (MBF) 34% +/- 5%, and myocardial oxygen consumption (MVO2) 8% +/- 1%, compared to precooling. Stroke volume (SV) and LV end-diastolic pressure (LVEDP) were unchanged. As normothermia (37 degrees C) was reestablished, the depression of cardiac function and myocardial metabolism remained the same as that at 25 degrees C: LVSP 71% +/- 6%, LV dP/dtmax 73% +/- 7%, SV 60% +/- 9%, AOP 70% +/- 6%, CO 57% +/- 9%, MBF 53% +/- 8%, and MVO2 44% +/- 8% HR, in contrast, recovered to precooling values. The arterial concentrations of glucose and free fatty acids (FFA) did not change significantly during the experimental period, whereas an increase in lactate of nonmyocardial origin appeared after rewarming. Increased myocardial contents of creatine phosphate and water were found during both hypothermia and rewarming. The present study demonstrates a persistent depression of cardiac function after hypothermia and rewarming in spite of adequate energy stores. Thus, a direct influence on myocardial contractile function by the cooling and rewarming process is suggested.

Class III antiarrhythmic action linked with positive inotropy: antiarrhythmic, electrophysiological, and hemodynamic effects of the sea-anemone polypeptide ATX II in the dog heart in situ.

Summary: Most antiarrhythmic drugs are more or less negatively inotropic. Positively inotropic properties, however, have been demonstrated for some class III antiarrhythmic drugs. To test the hypothesis that class III antiarrhythmic effect and positive inotropy may be linked, we used the sea-anemone polypeptide ATX II, which in isolated heart muscle preparations has been shown to specifically inhibit the inactivation of the sodium channel and thereby increase action potential duration and inotropy. We used 12 pentobarbital-anesthetized dogs. Atrial arrhythmias were induced by high-rate stimulation of the right atrium in 5 dogs. Cardiac electro-physiological effects were studied by His-bundle electrography, programmed electrical stimulation, and monophasic action potential (MAP) recordings in 7 autonomically blocked dogs. ATX II (1.0–5.0 μg/kg i.v.) converted the arrhythmias, and in the autonomically blocked dogs markedly increased atrial and ventricular refractoriness and ventricular MAP duration without influencing atrial or ventricular conduction velocities, heart rate, or AV-nodal refractoriness. ATX II induced a marked increase in left ventricular dP/dt max. The study indicates that ATX II has class III antiarrhythmic effect, and that the electrophysiological and positive inotropic effects of ATX II have a common mechanism.

Cardiac electrophysiological and hemodynamic effects of beta-adrenoceptor blockade and thoracic epidural analgesia in the dog.

To investigate whether thoracic epidural analgesia (TEA) has additional cardiac electrophysiological and hemodynamic effects when induced after β-adrenergic blockade, bupivacaine (0.7–1.2 mg/kg) was injected into the epidural space at T2–3 after intravenous injection of atenolol (1.0 mg/kg) in anesthetized dogs. Cardiac electrophysiology was studied by His bundle electrography, programmed electrical stimulation, and monophasic action potential recordings. Atenolol reduced heart rate, prolonged atrio-ventricular (AV) nodal impulse conduction time and refractoriness, prolonged ventricular refractoriness and action potential duration, and decreased left ventricular (LV) dP/dt max. Addition of TEA further reduced heart rate, prolonged AV nodal conduction time and refractoriness, decreased LV dP/dt max and arterial blood pressure, but had no effect on atrial and ventricular electrophysiology. Induction of TEA during β-blockade may thus have additive depressive effects on sinoatrial and AV nodal functions, as well as on left ventricular inotropy. The study indicates that the cardiac electrophysiological effects induced by TEA are mainly caused by decreased β-receptor stimulation, but increased vagal activity may also contribute.

Effects of N-acetylprocainamide as compared with procainamide in isolated rat atria

The actions of procainamide and its major metabolite N-acetylprocainamide were tested and compared on isolated rat atria. While procainamide exerted a negative chronotropic and iontropic effect, N-acetylprocainamide had the opposite effect. It is suggested that a N-acetylprocainamide-induced increase in myocardial work can counteract the negative inotropic action of procainamide and thus to some extent explain the variable results with the latter compound on myocardial performance reported from in vivo experiments. Procainamide increased the refractory period and reduced the excitability of isolated rat atria. N-acetylprocainamide, on the other hand, caused negligible effects on these parameters.

Class III antiarrhythmic action and inotropy : effects of dofetilide in acute ischemic heart failure in dogs

Summary We studied the hemodynamic and metabolic effects of the novel class III antiarrhythmic agent dofetilide (UK-68,798) in acute ischemic heart failure. In pentobarbital-anesthetized dogs, heart failure was induced by microembolization of the area supplied by the main left coronary artery until a stable left ventricular (LV) end-diastolic pressure of 27 ± 2 mm Hg was achieved. Embolization depressed LV systolic pressure, LV dP/dtmax, LV dP/dtmin, and cardiac output. None of these parameters were changed following i.v. infusion of dofetilide 5, 10, or 25 μg/kg, during spontaneous and paced cycle length of 300 ms (n = 9). Heart rate decreased by 12 ± 8, 19 ± 7, and 21 ± 7 beats/min (p < 0.05), while QT time increased by 23 ± 7, 33 ± 9, and 40 ± 10 ms (p < 0.05) after 5, 10, and 25 μg/kg, respectively. Ventricular effective refractory period increased from 128 ± 10 to 153 ± 11 ms after 25 μg/kg (n = 4). Arterial concentration and net myocardial uptake of glucose, lactate, and free fatty acids were not significantly influenced by dofetilide. In conclusion, dofetilide, at doses that prolonged repolarization, was devoid of cardiodepressive effects in acute ischemic heart failure.

CHANGES IN VENTRICULAR FIBRILLATION THRESHOLD DURING ACUTE HYPOTHERMIA. A MODEL FOR FUTURE STUDIES

Hypothermia and rewarming are associated with an increased incidence of lethal arrhythmias in man. The relationship between reduction in body temperature and ventricular fibrillation threshold was studied in 7 pentobarbital anaesthetized dogs using programmable electrical stimulation while cooling and rewarming between 37 degrees C and 25 degrees C in steps of 3 degrees C. Fibrillation threshold was defined as the number of extrastimuli required to evoke ventricular fibrillation. QRS-durations and corrected QT-intervals (QTc) were measured from surface electrocardiograms. Monophasic action potential durations were recorded from the base and apex of the heart. Fibrillation threshold decreased with decreasing temperatures; e.g., at 37 degrees C ventricular fibrillation was not inducible after 5 extrastimuli, while at 25 degrees C only 2 extrastimuli were required. From 37 degrees C to 25 degrees C QRS-width, monophasic action potential durations and QTc increased while conduction velocity decreased. The differential effects on conduction and monophasic action potential duration provide a basis for induction of ventricular fibrillation during acute hypothermia. This model of hypothermia-induced ventricular fibrillation should prove useful for future studies aimed at understanding the mechanisms responsible for hypothermia-related deaths.

Effects of levomepromazine, chlorpromazine and their sulfoxides on isolated rat atria.

The effects of levomepromazine, chlorpromazine and their sulfoxides were studied on spontaneously beating and on electrically driven rat atria in vitro. Levomepromazine, chlorpromazine and levomepromazine sulfoxide produced a dose-dependent decrease in the work index of spontaneously beating atria and in the contractile force of electrically driven atria, while chlorpromazine sulfoxide was relatively inactive in these respects. At higher concentrations, levomepromazine sulfoxide caused a pronounced increase in the threshold for electrical stimulation and the effective refractory period. Compared to chlorpromazine, levomepromazine looses less of its cardio-depressive effect through sulfoxidation.

Sodium addition to nonionic contrast media. Effects on cardiac monophasic action potentials and hemodynamics in a dog model.

In order to study the electrophysiologic and hemodynamic effects of sodium addition to low-osmolality contrast media during coronary arteriography, eight dogs with surgically opened thoraces were studied. Epicardial monophasic action potentials (MAP) were recorded from the contrast perfused area, using suction electrodes. Six milliliters of iohexol, iohexol with addition of 20 to 80 mmol/L Na+ and ioxaglate, were selectively administered into the left coronary artery. Only minor hemodynamic alterations occurred with the iohexol solutions, whereas ioxaglate decreased left ventricular (LV) inotropy and pressures initially. Iohexol and iohexol containing less than 40 mmol/L Na+ did not change MAP duration significantly. The addition of 80 mmol/L Na+ to iohexol lengthened MAP duration at 25%, 50%, and 90% repolarization by 14 +/- 2, 18 +/- 3, and 18 +/- 5 mseconds, respectively. Ioxaglate lengthened MAP duration by 14 +/- 3, 17 +/- 3, and 26 +/- 8 mseconds, respectively. Thus, during coronary arteriography in dogs, iohexol with sodium added, like ioxaglate, induced regional electrophysiologic changes in the contrast-perfused area of the myocardium, while sodium-free iohexol did not.