Electrical remodeling and atrial dilation during atrial tachycardia are influenced by ventricular rate: role of developing tachycardiomyopathy.

INTRODUCTION: Atrial fibrillation (AF) and congestive heart failure (CHF) are two clinical entities that often coincide. Our aim was to establish the influence of concomitant high ventricular rate and consequent development of CHF on electrical remodeling and dilation during atrial tachycardia. METHODS AND RESULTS: A total of 14 goats was studied. Five goats were subjected to 3:1 AV pacing (A-paced group, atrial rate 240 beats/min, ventricular rate 80 beats/min). Nine goats were subjected to rapid 1:1 AV pacing (AV-paced group, atrial and ventricular rates 240 beats/min). During 4 weeks, right atrial (RA) and left ventricular (LV) diameters were measured during sinus rhythm. Atrial effective refractory periods (AERP) and inducibility of AF were assessed at three basic cycle lengths (BCL). After 4 weeks of rapid AV pacing, RA and LV diameters had increased to 151% and 113% of baseline, whereas after rapid atrial pacing alone, these parameters were unchanged. Right AERP (157+/-10 msec vs 144+/-16 msec at baseline with BCL of 400 msec in the A-paced and AV-paced group, respectively) initially decreased in both groups, reaching minimum values within 1 week. Subsequently, AERP partially recovered in AV-paced goats, whereas AERP remained short in A-paced goats (79+/-7 msec vs 102+/-12 msec after 4 weeks; P < 0.05). Left AERP demonstrated a similar time course. Inducibility of AF increased in both groups and reached a maximum during the first week in both groups, being 20% and 48% in the A-paced and AV-paced group, respectively. CONCLUSION: Nature and time course of atrial electrical remodeling and dilation during atrial tachycardia are influenced by concurrent high ventricular rate and consequent development of CHF.

Digoxin delays recovery from tachycardia-induced electrical remodeling of the atria.

BACKGROUND: Atrial fibrillation (AF) induces electrical remodeling, which is thought to be responsible for the low success rate of antiarrhythmic treatment in AF of longer duration. Electrical remodeling seems to be related to tachycardia-induced intracellular calcium overload. Due to its vagomimetic action, digoxin is widely used to control the ventricular rate during AF, but it also increases intracellular calcium. On the basis of these characteristics, we hypothesized that digoxin would aggravate tachycardia-induced electrical remodeling. METHODS AND RESULTS: We analyzed the atrial effective refractory period (AERP) at cycle lengths of 430, 300, and 200 ms during 24 hours of rapid atrio/ventricular (300/150 bpm) pacing in 7 chronically instrumented conscious goats treated with digoxin or saline. Digoxin decreased the spontaneous heart rate but had no other effects on baseline electrophysiological characteristics. In addition to a moderate increase in the rate of electrical remodeling during rapid pacing, digoxin significantly delayed the recovery from electrical remodeling after cessation of pacing (at 430, 300, and 200 ms: P=0. 001, P=0.0015, and P=0.007, respectively). This was paralleled by an increased inducibility and duration of AF during digoxin. Multivariate analysis revealed that both a short AERP and treatment with digoxin were independent predictors of inducibility (P=0.001 and P=0.03, respectively) and duration (P=0.001 for both) of AF. CONCLUSIONS: Dioxin aggravates tachycardia-induced atrial electrical remodeling and delays recovery from electrical remodeling in the goat, which increases the inducibility and duration of AF.

Prediction of lesion size through monitoring the 0 degree C isothermic period following transcatheter cryoablation.

A prototype steerable 8.5 F bipolar catheter fitted with a feedback thermocouple was tested in 7 anaesthetized pigs (30 kg) guided by the electrocardiogram in order to modify the AV nodal and His-Purkinje system conductive properties. Thermal energy was delivered by a pressurized N2O tank (> 650 psi) via a cardiac cryo unit (Spembly, Hampshire, UK) into the catheter wherein gas expands resulting in a tip temperature as low as -70 +/- 2 degrees C within 10 seconds. Cryoablation under fluoroscopic and electrocardiographic guidance was applied at distinct sites in both ventricles for 60 or 120 seconds. After a follow-up period of 6 weeks, the ablation lesions found were well demarcated with small margins of hypertrophy of myocardial cells. With respect to lesion volume variability (8-207 mm3) and geometry, a relationship between the 0 degree C isothermic period and cryolesion volume was found. Results of an in vitro model corroborated this relationship. Therefore, an isothermic period probably can predict the lesion size and its geometry in terms of lesion depth. This potential therapeutic mode of transcatheter cryoablation deserves further investigation.

Verapamil reduces tachycardia-induced electrical remodeling of the atria.

BACKGROUND: Prolonged periods of atrial fibrillation or rapid atrial pacing induce shortening of the atrial effective refractory period (AERP), which is thought to be related to the lower success rates of various antifibrillatory treatments when the arrhythmia has lasted for a longer period of time. METHODS AND RESULTS: To investigate whether an increase in intracellular calcium could be the stimulus for electrical remodeling, the effects of verapamil on shortening of the AERP in response to 24 hours of rapid atrial pacing (300 bpm) were studied in five chronically instrumented conscious goats during infusion of saline or verapamil. During rapid atrial pacing, the ventricular rate was kept constant by ventricular pacing (150 bpm). The AERP was measured by programmed electrical stimulation at basic cycle lengths of 430, 300, and 200 ms. Verapamil had no effects on the AERP before rapid atrial pacing. However, in the course of 24 hours of rapid atrial pacing, the AERP shortened significantly less (27% to 58%) in the presence of verapamil compared with control (at 430, 300, and 200 ms, P < .001, P < .01, and P < .01, respectively). Also, after cessation of pacing, complete recovery of the AERP during verapamil infusion occurred much sooner than in the control experiments. Despite a significant reduction in electrical remodeling, there was only a minimal reduction in inducibility of atrial fibrillation by verapamil (34% versus 39% in the control experiments, P = .03). CONCLUSIONS: Electrical remodeling of the atrium during rapid atrial pacing was significantly attenuated by verapamil. This suggests that electrical remodeling of the atrium is triggered by the high calcium influx during rapid atrial pacing rates.

Effects of beta-blockade on atrial and atrioventricular nodal refractoriness, and atrial fibrillatory rate during atrial fibrillation in pigs.

Despite their widespread use in atrial fibrillation, the effects of beta-adrenoceptor blockers on atrial and atrioventricular (AV) nodal refractoriness, and atrial fibrillatory rate during atrial fibrillation have been incompletely characterised. In particular, it is unknown whether additional sodium channel (class I) blocking effects play a role. Effects of bisoprolol (no class I effect) and metoprolol (mild class I effect) were therefore compared in 12 open-chest pigs. Atrial and AV-nodal effective refractory periods were determined at pacing cycle length 500 ms and 300 ms. Atrial fibrillation was then induced by premature stimulation and topical application of metacholine, and atrial fibrillatory intervals and ventricular intervals were recorded. After resumption of sinus rhythm, bisoprolol 0.1 mg/kg or metoprolol 0.3 mg/kg was administered, and measurements were repeated. Also, effects on plasma catecholamines and signal-averaged QRS duration were determined. Both bisoprolol and metoprolol prolonged atrial and AV-nodal effective refractory periods at both pacing cycle lengths, however, no differences were noted between the two drugs. No significant effects were observed on atrial and ventricular intervals during atrial fibrillation. Plasma catecholamines were low and unaffected by either drug, as was the QRS duration. It is concluded that the mild class I effect of metoprolol does not play a role in atrial fibrillation. Also, the results confirm the clinical notion that beta-blockers exert insignificant effects during atrial fibrillation in the setting of low sympathetic tone.

Electrophysiological, rate dependent, and autonomic effects of the class III antiarrhythmic almokalant after myocardial infarction in the pig.

Ventricular arrhythmias remain a major problem, in particular in patients with left ventricular dysfunction or heart failure. In this group of patients, Class I drugs were shown to be ineffective, and they even increased mortality during chronic treatment. New antiarrhythmic agents should preferably not only have pure antiarrhythmic effects, but should also be free from adverse autonomic properties. In the present study, the electrophysiological, rate dependent and autonomic effects of intravenously administered almokalant, a new Class III antiarrhythmic drug, were investigated in nine pigs surviving a myocardial infarction. The ventricular effective refractory period (VERP) increased after almokalant (loading dose: 0.05 mumol.kg-1.min-1, continuous infusion: 0.0025 mumol.kg-1.min-1) from 292 +/- 25 to 308 +/- 13 ms (pacing cycle length [PCL] 500 ms + 1 extrasystole [ES]), from 249 +/- 19 to 261 +/- 16 ms (PCL 400 ms +1ES), and from 209 +/- 18 to 219 +/- 18 ms (PCL 300 ms +1ES). The VERPs increased most after three ES at PCL 400 ms: from 167 +/- 27 to 186 +/- 29 ms (P < 0.05) and at PCL 300 ms: from 150 +/- 29 to 174 +/- 27 ms (P < 0.05). The ventricular monophasic action potential durations (MAPD) were similarly prolonged and the ratio VERP/MAPD did not change. Prolongation of MAPD after almokalant remained present at short pacing cycle lengths. Before almokalant infusion, sustained monomorphic ventricular tachycardia (VT) was inducible in two pigs, and nonsustained VT in a third animal. After almokalant, only one pig remained inducible. Two weeks after myocardial infarction, heart rate variability and baroreflex sensitivity were reduced. Furthermore, subsequent electrophysiological testing transiently reduced these parameters of autonomic activity. During almokalant however, no changes in autonomic functions were observed after programmed stimulation. Heart rate variability decreased after myocardial infarction from 6.3 +/- 2.5 ms to 5.4 +/- 4.2 ms (P = NS). After programmed stimulation, it further decreased to 2.8 +/- 2.0 ms (P = 0.028). Almokalant infusion prevented autonomic deterioration: 3.3 +/- 2.2 ms before stimulation and 3.3 +/- 1.3 after stimulation (P = NS). In postinfarct pigs, almokalant prolongs VERP and MAPD at shorter pacing cycle lengths. The results indicate absence of reverse rate dependence and of adverse autonomic changes.

Rate-dependent effects of the class III antiarrhythmic drug almokalant on refractoriness in the pig.

The electrophysiologic effects of intravenously administered almokalant, a new class III antiarrhythmic drug, in 7 isoflurane-anesthetized pigs after low and high dose were investigated. Low-dose almokalant included bolus infusion of 0.05 mumol/kg/min for 5 min followed by a continuous infusion of 0.0025 mumol/kg/min for 40 min. Thereafter, a high dose of 0.2 mumol/kg/min for 5 min and 0.01 mumol/kg/min for 40 min was given. PR, QRS, AH, and HV intervals did not change during almokalant administration. The QT interval increased dose dependently from 337 +/- 17 to 442 +/- 20 ms at high dose (p < 0.05). Atrial refractory periods (AERP) were prolonged dose dependently at a 500-ms pacing cycle length from 178 +/- 15 at baseline to 227 +/- 27 and 253 +/- 23 ms during low- and high-dose almokalant infusion, respectively. For pacing cycle lengths of 400 and 300 ms, these values were 180 +/- 11, 207 +/- 25, and 259 +/- 34 and 157 +/- 12, 193 +/- 21, and 234 +/- 28 ms, respectively. At a pacing cycle length of 500 ms, mean ventricular effective refractory period (VERP) was 270 +/- 25 ms as compared with 306 +/- 24 and 337 +/- 17 during low and high dose, respectively. A similar pattern of VERP changes during both low- and high-dose infusion was noted at the shorter pacing cycle lengths, with an increase from 240 +/- 23 to 274 +/- 22 and 279 +/- 24 ms during a 400-ms cycle length and from 210 +/- 17 to 235 +/- 19 and 234 +/- 21 ms during a 300-ms cycle length. The ratio of the VERP and ventricular monophasic action potential duration (VAPD) did not change significantly. The Wenckebach cycle length increased by 36 +/- 36 and 83 +/- 37 ms with low- and high-dose almokalant infusion, respectively. The percent increase of AERP at pacing cycle lengths of 500, 400, and 300 ms during high-dose almokalant was 42, 44, and 49%, respectively; these increases for VERP were 25, 16, and 11%, respectively. In conclusion, prolongation of refractoriness by almokalant was more pronounced at the atrial than the ventricular level. Prolongation of refractoriness was maintained at short pacing cycle lengths especially in the atrium, indicating absence of reverse-use dependence of almokalant in the porcine heart. The marked atrial effects, paralleled by atrioventricular conduction slowing, and the absence of reverse use-dependence all contribute to the feasibility of use of almokalant, in particular in the treatment of supraventricular tachyarrhythmias.

Analysis of randomness of atrial and ventricular rhythm in atrial fibrillation.

The aim of the present study was to examine the relationship between randomness of atrial and ventricular rhythm during atrial fibrillation. Atrial fibrillation was induced in 10 open-chest pigs by application of metacholine on the surface of the right atrium followed by incremental pacing. Local atrial rhythm (AA intervals) was recorded with a bipolar epicardial electrode, and episodes of atrial fibrillation corresponding to 500 ventricular (RR) intervals were selected for analysis. Randomness of the distribution of AA and RR intervals was assessed by autocorrelation. Pearson's test was used for statistical analysis. Random AA and RR interval distribution was observed in nine pigs (P > or = 0.05). In the remaining pig, atrial fibrillation had changed to atrial tachycardia. This was associated with immediate transition of a random to a non-random ventricular rhythm. These findings provide strong circumstantial evidence in support of the contention that randomness of ventricular rhythm during atrial fibrillation is due to randomness of atrial rhythm.

Effect of metoprolol on atrial fibrillatory rate, atrioventricular nodal concealed conduction, and ventricular response during atrial fibrillation in pigs.

We wished to elucidate the effect of beta-blockade on fibrillatory rate and atrioventricular (AV) nodal concealed conduction during atrial fibrillation (AF). Subsequent to determination of the effect on atrial functional refractoriness with the extrastimulus technique (basic cycle length 400 ms), the effect of metoprolol (0.3 mg/kg) on atrial fibrillatory rate was determined in 8 open-chest pigs with metacholine-facilitated AF. Once stable AF was established, fibrillatory rate was recorded with a bipolar epicardial electrode, together with the ventricular response during 500 ventricular intervals. For each episode of AF, three indexes were calculated to determine the degree of concealed conduction: the ratio of the longest to the shortest ventricular interval, the ratio of the median ventricular interval to the median atrial interval, and the coefficient of variation of the ventricular intervals. Metoprolol decreased fibrillatory rate (571-432 beats/min, p < 0.01), suggesting a proportionate increase (+32%) in atrial functional refractoriness during AF that far exceeded the increase (+7%) during sinus rhythm (217-233 ms, p < 0.05). None of the indexes of concealed conduction was affected by metoprolol. Metoprolol decreases fibrillatory rate in AF, possibly due in part to its class I effect, causing rate-dependent prolongation of atrial refractoriness. Despite reducing fibrillatory rate, metoprolol does not affect AV nodal concealed conduction measurably. Our results support the assumption that the reducing effect of beta-blockers on ventricular rate during AF is due to direct prolongation of AV nodal refractoriness.

Sustained atrial flutter around the tricuspid valve in pigs: differentiation of procainamide (class IA) from flecainide (class IC) and their rate-dependent effects.

The wavelength theory considers two determinants of reentry, i.e., refractoriness and conduction velocity. It does not take excitability into account primarily. We evaluated frequency-dependence of excitability and refractoriness before and after flecainide or procainamide administration in relation to termination of reentrant atrial flutter. After making a Y-shaped lesion in the right atrium, we induced 62 flutters (cycle length 171 +/- 15 ms) by electrical stimulation in 15 pigs. Strength-interval curves were determined to assess excitability and refractoriness. Multiple cycle lengths were used to establish rate-dependent changes. Flutter cycle length increased after flecainide (to 290 +/- 67 ms) or procainamide (to 295 +/- 54 ms). The flutters always terminated abruptly (flecainide dose 103 +/- 104 mg, plasma concentration 370 +/- 21 ng/ml; procainamide dose 1,150 +/- 686 mg, concentration 51 +/- 24 mg/l). Flecainide caused an increase in diastolic thresholds from 0.3 +/- 0.2 to 0.8 +/- 0.5 mA (p < 0.006) and procainamide from 0.5 +/- 0.3 to 0.9 +/- 0.5 mA (p < 0.02). The increase in threshold was frequently dependent. Procainamide increased refractoriness at longer cycle lengths (> or = 250 ms), but this effect was abolished at shorter cycle lengths, indicating that only after significant slowing of the rate, prolongation of refractoriness may appear. Thus, both drugs interrupt reentrant flutter mainly by reducing excitability. Subclassification into IA and IC may be less relevant at high rates. Construction of strength-interval curves and assessment of rate-dependent "postrepolarization refractoriness" should be considered when one studies drugs that influence excitability.

Late potentials in a porcine model of anterior wall myocardial infarction and their relation to inducible ventricular tachycardia.

In this study, normal values for signal averaged electrocardiographic parameters were assessed in healthy pigs (n = 100) and the development of late potentials after myocardial infarction (n = 41) in relation to inducible ventricular tachycardia was investigated. Normal values are: filtered QRS duration (QRS) < or = 78 msec; root mean square voltage of the averaged QRS complex (V(tot)) > or = 51 microV, and duration of terminal activity below 30 microV (D30) < or = 37 msec. The distribution of the root mean square voltage in the last 30 msec (V30) was biphasic. Two weeks after myocardial infarction, QRS was prolonged from 55 +/- 10 to 66 +/- 19 msec (P < 0.002). D30 was prolonged from 19 +/- 6 msec to 28 +/- 13 (P < 0.002). V30 was decreased from 107 +/- 135 microV to 45 +/- 77 (P < 0.02). The total voltage (V(tot)) was decreased from 195 +/- 78 to 123 +/- 61 microV (P < 0.002). In four pigs (19%) late potentials developed. Sustained ventricular tachycardia was inducible in 11 pigs (52%), ventricular fibrillation in two pigs (10%) and eight pigs (38%) were noninducible. Three of 11 inducible pigs and one of the noninducible pigs had a late potential. The incidence of late potentials and their relation to inducible sustained ventricular tachycardia is comparable to the situation in man. Therefore, this pig model is an attractive alternative to the commonly used dog models.

The angiotensin converting enzyme inhibitor perindopril improves survival after experimental myocardial infarction in pigs.

In this randomized, blinded study the effect of the angiotensin converting enzyme inhibitor perindopril on electrical stability after myocardial infarction in pigs was compared to placebo. The left anterior descending artery was occluded for 45 min. Perindoprilat (0.06 mg/kg, n = 12) or saline (n = 12) was injected 15 min before reperfusion. Treatment was continued till day 13 with perindopril (12 mg, once daily) or placebo. At day 14 an electrophysiologic study was performed. The release of creatine phosphokinase did not differ significantly. During the subsequent days, seven of 12 placebo-treated pigs died (six within 24 h), whereas two of the 12 perindopril-treated pigs died (one within 24 h; p less than 0.04). Sustained ventricular tachycardia was inducible in one of five placebo-treated pigs versus three of 10 perindopril-treated survivors (NS). Late potentials had developed in one placebo-treated pig but not in pigs that received perindopril. Characteristics of infarct border zone heterogeneity (percentages of a reference electrode in viable myocardium) such as a dispersion of current thresholds (127 +/- 96 vs. 238 +/- 463% in perindopril-treated pigs, NS) and refractoriness (9.8 +/- 8.4 vs. 11.9 +/- 6.0% in perindopril-treated pigs, NS) were comparable. This treatment with perindopril significantly improved survival while electrical stability was comparable between survivors. The latter indicates that a comparable electrical stability 2 weeks after myocardial infarction is obtained in perindopril-treated pigs at a significantly higher survival rate.

Neurohumoral changes and the inducibility of ventricular tachycardias: effect of early reperfusion on the ischemic porcine myocardium.

The effects of early reperfusion were studied in closed-chest pigs subjected to either 45 min or 3 hr of regional ischemia. Myocardial enzyme release during early reperfusion and electrophysiological stability after two weeks were assessed. Coronary artery occlusion durations of 3 hr and early reperfusion after 45 min were compared. The creatine phosphokinase levels in the coronary effluent were lower after early reperfusion (p less than 0.001). Moreover, in the early reperfusion group, the coronary sinus catecholamine and purine levels rose to higher values than in the 3 hr group. The plasma levels of catecholamines and the plasma renin activity increased rapidly but transiently at reperfusion in the 45 min group. Both the rate-pressure product and the heart rate were elevated at the end of the reperfusion period (p less than 0.001) in the 45 min group. Survival for two weeks was 3 out of 6 animals in the 3 hr group and 5 out of 8 in the 45 min group. In all but one surviving animal, sustained ventricular tachycardias were inducible by programmed stimulation. Abnormally low QRS amplitudes and delayed potentials were found in the signal-averaged electrocardiogram in the early reperfusion group only. In conclusion, early reperfusion causes a reduction of myocardial tissue damage, but simultaneously, neurohumoral parameters showed a greater activation of the sympathetic nervous system and the renin-angiotensin system apparently causing a deleterious increase in oxygen consumption. Therefore, this injurious component of early reperfusion might prevent the potentially beneficial effects of a reduced tissue damage on survival or late arrhythmias.

Effects of early angiotensin-converting enzyme inhibition in a pig model of myocardial ischemia and reperfusion.

In a blind, randomized study, the effects of perindopril, a nonsulfhydryl-containing angiotensin-converting enzyme (ACE) inhibitor, were compared with those of placebo in a closed-chest pig model of myocardial infarction. In anesthetized pigs, myocardial ischemia and reperfusion were induced by inflation and deflation of a catheter balloon in the left anterior descending coronary artery (LAD), respectively. Thirty minutes after induction of ischemia and 15 min before reperfusion, a bolus injection of 0.06 mg/kg perindoprilat (n = 12), the active compound of perindopril, or placebo (n = 12) was administered in the pulmonary artery of these animals. After the acute phase of myocardial infarction, treatment with 12 mg/day perindopril or placebo was continued orally for 2 weeks. During the entire treatment period, 7 of 12 animals died in the placebo group versus 2 of 12 animals in the perindopril group (Fisher's exact test p less than 0.04). This beneficial effect of perindopril on mortality could not be attributed to salvage of myocardial tissue because the increases in creatine phosphokinase and coronary venous purine levels were similar in perindopril- and placebo-treated animals. Neither were there any significant between-treatment differences in the hemodynamic and (neuro)humoral parameters during the acute phase of myocardial infarction. The difference in mortality was observed within 24 h after myocardial infarction. Prevention of acute pump failure and, especially, life-threatening ventricular arrhythmias may explain this improvement in survival by perindopril. Retrospectively, logistic regression analysis showed that, irrespective of treatment, survival was inversely correlated to plasma renin activity (PRA) before induction of ischemia (r = -0.33; p less than 0.02).(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of bradykinin on inducible sustained ventricular tachycardia two weeks after myocardial infarction in pigs.

We studied the in vivo effect of bradykinin infusion on inducible sustained ventricular tachycardia (VT) 2 weeks after myocardial infarction in pigs, based on the assumption that the antiarrhythmic effect of angiotensin-converting enzyme (ACE) inhibitors may, apart from their angiotensin-II lowering effect, also be due to elevation of endogenous bradykinin levels. Of the six pigs with inducible VT in the control state, four were noninducible during subsequent bradykinin infusion (p less than 0.05). The ventricular effective refractory period (VERP) did not change during bradykinin infusion (from 237 +/- 37 to 239 +/- 42 ms), nor did intraventricular conduction change (filtered QRS duration was 45 +/- 17 ms before and 43 +/- 19 ms during infusion). Bradykinin caused both a significant systolic blood pressure (SBP) decrease (from 79 +/- 14 to 49 +/- 4 mm Hg, p less than 0.001) and diastolic BP (DBP) decrease (from 41 +/- 10 to 27 +/- 4 mm Hg, p less than 0.01). In conclusion, exogenous bradykinin reduced the inducibility of sustained VT 2 weeks after myocardial infarction. Because refractory periods or conduction velocity were not affected, the mechanism of action might be associated with the BP decrease, which can decrease wall stress. The previously reported antiarrhythmic effect of ACE inhibitors may be due in part to elevation of endogenous bradykinin levels.

In vivo effect of bradykinin during ischemia and reperfusion: improved electrical stability two weeks after myocardial infarction in the pig.

In this study, the effect of bradykinin or saline infusion during ischemia and reperfusion on electrical stability, 2 weeks after myocardial infarction, was assessed. Acute myocardial infarction was induced in 21 pigs by a transluminal occlusion of the left coronary artery with a catheter balloon, inflated for 45 min. Bradykinin was administered by a 30-min infusion that started after 30 min of coronary occlusion and was continued until 15 min after reperfusion. Although creatine kinase levels in bradykinin-treated animals were significantly lower (p less than 0.001), 2 week survival was not different between groups. In survivors, the filtered QRS (ventricular deflection) duration (detected using signal-averaged electrocardiography) was significantly prolonged in saline-treated pigs, whereas in bradykinin-treated pigs this prolongation was prevented. The terminal voltage of the QRS complex was significantly lower in saline-treated pigs than in bradykinin-treated pigs. These two parameters signify an improved electrical stability after bradykinin treatment. Refractory periods in saline-treated hearts were longer than in bradykinin-treated hearts (106 +/- 10% vs. 95 +/- 13%, p less than 0.05). Also, current thresholds in the infarct border zones showed a greater variance in saline-treated hearts (p less than 0.001), pointing toward more tissue heterogeneity of the infarct border zone. Programmed electrical stimulation showed a trend toward reduced inducibility of sustained ventricular tachycardia in bradykinin-treated hearts. Therefore, bradykinin improves electrical stability weeks after experimental myocardial infarction.

Beneficial effects of bradykinin on porcine ischemic myocardium.

Exogenous bradykinin was administered to pigs in which an experimental infarction was evoked by ischemia and reperfusion. Ischemia (45 min) was induced in a closed-chest model with a balloon catheter in the left anterior descending artery, reperfusion by deflating and removing the balloon. The pigs were treated with saline (n = 11) or bradykinin (0.1 mg/kg in 30 min) infusion (n = 10) during the last 15 min of the ischemic period and the first 15 min of reperfusion. During ischemia, heart rate increased in the saline group to 120 +/- 9% of the initial value (p less than 0.05) and in the bradykinin group to 155 +/- 13% (p less than 0.05). After reperfusion, the rate-pressure product was increased in both groups. The increase of arterial creatine kinase levels was significantly less in the bradykinin-treated group. However, the catecholamine and purine levels were increased, as was the plasma renin activity when compared with the saline group. Two weeks after the infarction, six pigs had died in each group. In three out of five surviving saline-treated pigs and one out of four surviving bradykinin-treated pigs, a sustained ventricular tachyarrhythmia was inducible after programmed electrical stimulation. In conclusion, although systemically administered bradykinin caused a temporary increase in myocardial ischemia, it did reduce the (enzymatic indices of) infarct size. Therefore, the beneficial effects, previously found for ACE-inhibitors might at least partially be related to the potentiation of endogenous bradykinin.

The effects of oral pretreatment with zofenopril, an angiotensin-converting enzyme inhibitor, on early reperfusion and subsequent electrophysiologic stability in the pig.

The effects of oral zofenopril pretreatment were investigated in a chronic closed-chest pig model of ischemia and reperfusion. Pigs (25-35 kg) were pretreated orally with zofenopril (15 mg/day) on the 2 days prior to ischemia, which was evoked by the inflation of a catheter balloon in the left anterior descending coronary artery over 45 minutes. The catheter was then removed and the myocardium was reperfused. After 2 weeks, infarct properties were assessed by signal averaging of the body surface electrocardiogram and the inducibility of malignant ventricular tachyarrhythmias was tested with a programmed electrical stimulation protocol. A significant increase in the pressure-rate product (43 +/- 11%, mean +/- SEM), indicating the oxygen demand of the heart, was prevented by zofenopril (19 +/- 8%, p less than 0.05). Zofenopril reduced the peak efflux of adrenaline (1302 +/- 213 vs. 3201 +/- 760 pg/ml; p less than 0.05), noradrenaline (402 +/- 54 vs. 902 +/- 282 pg/ml; p less than 0.05), and of the adenosine catabolites inosine and hypoxanthine (56 +/- 4 vs. 78 +/- 9, pg/ml; p less than 0.05) in the coronary venous effluent. The efflux of the cytoplasmatic enzyme creatine phosphokinase was not significantly reduced after zofenopril (p = 0.08). No difference in plasma renin levels between the groups were found. After 2 weeks, late potentials were found only in the surviving animals from the untreated group, i.e., the voltage vector magnitude was more reduced, and a prolongation of the QRS duration and of the terminal low-amplitude part of the high-frequency QRS were found.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of angiotensin II and captopril on inducible sustained ventricular tachycardia two weeks after myocardial infarction in the pig.

The effects of angiotensin II (AII) and captopril (C) on the inducibility of ventricular tachyarrhythmias were investigated 14 days after infarction in pigs. In 27 pigs, ischemia was induced by 60-min occlusion of the left coronary artery. Four pigs died of ventricular fibrillation during ischemia, and six others died within 24 h due to pump failure. Of the 17 survivors, eight pigs developed a sustained (greater than 30 s) monomorphic ventricular tachycardia (sVT) after programmed electrical stimulation. In nine noninducible pigs, an AII infusion (0.6 microgram/kg/min) caused inducible sVT in three animals and nonsustained VT in two animals (greater than 10 reentrant beats). In two of the remaining four animals, spontaneous premature ventricular beats appeared during the infusion. In a group of five healthy pigs, the electrophysiological effects of AII were evaluated. Infusion of AII caused a rapid and sustained increase in arterial blood pressure to 161 +/- 6.4% (p less than 0.001). The sinus cycle length decreased to 74 +/- 5.2% (p less than 0.02). The effective refractory period of the right ventricle decreased significantly to 82 +/- 5.5% (p less than 0.05). These results show that modulation of the renin-angiotensin system after myocardial infarction influences the inducibility of malignant ventricular tachyarrhythmias, as shown by the increased inducibility of sustained ventricular tachycardia. This may be related to a decreased ventricular refractoriness. Therefore, it is suggested that C can reduce malignant ventricular tachycardia late after myocardial infarction by preventing the deleterious arrhythmogenic effects of AII.