Pathophysiology of tachycardia- and bradycardia-dependent block in the canine proximal His-Purkinje system after acute myocardial ischemia

Attenuating loss of cardiac conduction during no-flow ischemia through changes in perfusate sodium and calcium

Myocardial ischemia leads to conduction slowing, cell-to-cell uncoupling, and arrhythmias. We previously demonstrated that varying perfusate sodium (Na⁺) and calcium (Ca²⁺) attenuates conduction slowing and arrhythmias during simulated ischemia with continuous perfusion. Cardioprotection was selectively associated with widening of the perinexus, a gap junction adjacent nanodomain important to ephaptic coupling. It is unknown whether perfusate composition affects the perinexus or ischemic conduction during nonsimulated ischemia, when coronary flow is reduced or halted. We hypothesized that altering preischemic perfusate composition could facilitate perinexal expansion and attenuate conduction slowing during global ischemia. To test this hypothesis, ex vivo guinea pig hearts (n = 49) were Langendorff perfused with 145 or 153 mM Na⁺ and 1.25 or 2.0 mM Ca²⁺ and optically mapped during 30 min of no-flow ischemia. Altering Na⁺ and Ca²⁺ did not substantially affect baseline conduction. Increasing Na⁺ and decreasing Ca²⁺ both lowered pacing thresholds, whereas increasing Ca²⁺ narrowed perinexal width (W_p). A least squares mean estimate revealed that reduced perfusate Na⁺ and Ca²⁺ resulted in the most severe conduction slowing during ischemia. Increasing Na⁺ alone modestly attenuated conduction slowing, yet significantly delayed the median time to conduction block (10 to 16 min). Increasing both Na⁺ and Ca²⁺ selectively widened W_p during ischemia (22.7 vs. 15.7 nm) and attenuated conduction slowing to the greatest extent. Neither repolarization nor levels of total or phosphorylated connexin43 correlated with conduction slowing or block. Thus, perfusate-dependent widening of the perinexus preserved ischemic conduction and may be an adaptive response to ischemic stress.NEW & NOTEWORTHY Conduction slowing during acute ischemia creates an arrhythmogenic substrate. We have shown that extracellular ionic concentrations can alter conduction by modulating ephaptic coupling. Here, we demonstrate increased extracellular sodium and calcium significantly attenuate conduction slowing during no-flow ischemia. This effect was associated with selective widening of the perinexus, an intercalated disc nanodomain and putative cardiac ephapse. These findings suggest that acute changes in ephaptic coupling may serve as an adaptive response to ischemic stress.

Post-repolarization refractoriness increases vulnerability to block and initiation of reentrant impulses in heterogeneous infarcted myocardium

Myocardial infarction causes remodeling of the tissue structure and the density and kinetics of several ion channels in the cell membrane. Heterogeneities in refractory period (ERP) have been shown to occur in the infarct border zone and have been proposed to lead to initiation of arrhythmias. The purpose of this study is to quantify the window of vulnerability (WV) to block and initiation of reentrant impulses in myocardium with ERP heterogeneities using computer simulations. We found that ERP transitions at the border between normal ventricular cells (NZ) with different ERPs are smooth, whereas ERP transitions between NZ and infarct border zone cells (IZ) are abrupt. The profile of the ERP transitions is a combination of electrotonic interaction between NZ and IZ cells and the characteristic post-repolarization refractoriness (PRR) of IZ cells. ERP heterogeneities between NZ and IZ cells are more vulnerable to block and initiation of reentrant impulses than ERP heterogeneities between NZ cells. The relationship between coupling intervals of premature impulses (V1V2) and coupling intervals between premature and first reentrant impulses (V2T1) at NZ/NZ and NZ/IZ borders is inverse (i.e. the longer the coupling intervals of premature impulses the shorter the coupling interval between the premature and first reentrant impulses); this is in contrast with the reported V1V2/V2T1 relationship measured during initiation of reentrant impulses in canine infarcted hearts which is direct.

IN CONCLUSION

(1) ERP transitions at the NZ-IZ border are abrupt as a consequence of PRR; (2) PRR increases the vulnerability to block and initiation of reentrant impulses in heterogeneous myocardium; (3) V1V2/V2T1 relationships measured at ERP heterogeneities in the computer model and in experimental canine infarcts are not consistent. Therefore, it is likely that other mechanisms like micro and/or macro structural heterogeneities also contribute to initiation of reentrant impulses in infarcted hearts.

Modulation of ventricular fibrillation in isolated perfused heart by dofetilide

The authors studied the involvement of IKr potassium current in ventricular fibrillation during perfusion. Electrophysiologic parameters were measured before and after dofetilide administration (2.5, 7.5, and 12.5 x 10-7 M, n = 8) in isolated perfused feline hearts. During pacing, these parameters included epicardial conduction time, refractoriness, and the fastest rate for 1:1 pacing/response capture. During 8 minutes of electrically induced tachyarrhythmias, they included heart rate and normalized entropy reflecting the degree of organization. In all groups, arrhythmia rate was slower in the right ventricle than in the left ventricle. Dofetilide decreased the arrhythmia rate more than it increased organization, reduced its maintenance, or increased difficulty in initiation. Refractoriness was prolonged in a reverse use-dependent way which was less than 1:1 pacing/response capture. Unexpectedly, a moderate prolongation of conduction time was observed. Inverse correlation was found between the arrhythmia rate and changes in refractoriness and conduction time and between the degree of organization and refractoriness (both ventricles) and conduction time (right ventricle). Dofetilide, which intensively blocks IKr current and unexpectedly suppressed conduction, has different quantitative effects on fibrillation features. These changes in fibrillation suggest that these effects are mainly associated with refractoriness prolongation and do not seem to be attenuated by conduction suppression.

Role of sodium channels in ventricular fibrillation: a study in nonischemic isolated hearts

Because the role of sodium channels in the initiation and maintenance of VF is not fully elucidated, we studied the significance of sodium channel activity in VF using sodium channel blockers. In nonischemic isolated feline hearts, the following electrophysiologic parameters were measured before and after application of tetrodotoxin (5 x 10(-7) M, n = 6) or lidocaine (1 x 10(-5) M, n = 8): (a) during pacing, epicardial conduction time; refractoriness; the fastest rate for 1:1 pacing/response capture, and all tissue resistivity, indirectly reflecting intercellular electrical resistance; (b) during 8 min of electrically induced tachyarrhythmias, all tissue resistivity; peak frequency (to measure average frequency based on fast-Fourier transformation analysis); and normalized entropy (to measure the degree of arrhythmia organization). In nonischemic isolated rabbit hearts (n = 4), three-dimensional mapping was performed before and after application of lidocaine (1 x 10(-5) M). In feline hearts, lidocaine and tetrodotoxin application resulted in: (a) more spontaneous arrhythmia termination (63-67%) than in nontreated hearts (7%); (b) transformation from mainly VF into ventricular tachycardia with increased organization; and (c) prolongation of conduction time (155-248%) (p < 0.01 for all parameters). The ventricular refractory period was slightly prolonged by tetrodotoxin in the right ventricle and exhibited rate-dependent shortening in control and with lidocaine. Tetrodotoxin and lidocaine reduced the pacing rate for 1:1 pacing/response capture, and all tissue resistivity was not significantly affected. Peak frequency was decreased by tetrodotoxin and lidocaine mainly in the left ventricle (p < 0.01). In nontreated left ventricles, peak frequency was increased over time but was attenuated by lidocaine. In isolated rabbit hearts, several simultaneous wave fronts were detected during VF in nontreated hearts and were reduced to only one or two major wavefronts after application of lidocaine. Suppression of sodium channel activity that primarily slowed conduction time and had little or no effect on ventricular refractory period and all tissue resistivity resulted in less stable and more organized arrhythmias and reduced tachyarrhythmia rate compared with nontreated hearts. These results suggest an active role for sodium channels in the maintenance of ventricular fibrillation.

Repolarisation and refractoriness during early ischaemia in humans

OBJECTIVES

To determine whether effective refractory period (ERP) shortens or lengthens in the first minutes of ischaemia in humans, and the relation between ERP changes and action potential duration (APD).

METHODS

ERP and monophasic action potential duration (MAPD) were measured from a single left ventricular epicardial site in 26 patients undergoing coronary artery surgery. Cardiopulmonary bypass was instituted and normothermia maintained. Refractory period was determined by the extrastimulus technique at a basic cycle length of 500 ms, at four times (group 1, 15 patients) or two times (group 2, 11 patients) the preischaemic diastolic threshold. A three minute period of ischaemia was instituted by aortic cross clamping between the input from the pump oxygenator and the heart.

RESULTS

After three minutes of ischaemia, mean (SEM) ERP lengthened from 232 (5) ms (control) to 246 (7) ms (p < 0.005) in group 1, and from 256 (10) ms (control) to 348 (25) ms (p < 0.005) in group 2. In the same time MAPD shortened from 256 (5) ms (control) to 189 (9) ms (p < 0.001) with no difference between groups. Thus postrepolarisation refractoriness developed during ischaemia. Before ischaemia, ERP showed a good correlation with APD (R(2) = 0.64) but by one minute of ischaemia the correlation was poor (R(2) = 0.29).

CONCLUSIONS

These results show that during the first three minutes of global ischaemia in patients with coronary artery disease: (1) ERP lengthened in response to both a low and a high stimulus strength; and (2) there was a good correlation between ERP and APD before ischaemia, which was lost by one minute as APD decreased and ERP increased. These findings may have important implications in arrhythmogenesis.

Integrative models and responses in cardiac ischemia

This chapter considers the study of electrophysiological changes during ischemia and incorporates mechanoelectric feedback, i.e., mechanical changes affecting electrophysiology. It considers these interactions in the cell, through multicell systems, the intact heart and the intact organism.

Anterior septal coronary artery infarction in the canine: a model of ventricular tachycardia with a subendocardial origin. Ablation and activation sequence mapping

BACKGROUND

In humans, chronic ventricular tachycardia (VT) is usually associated with myocardial infarcts that involve the interventricular septum. In an effort to more closely mimic the anatomic substrate that gives rise to chronic VT in humans, we developed a canine model of VT in which the anterior septal coronary artery was ligated. The site of earliest activation, the subsequent activation sequence, and the mechanism of VT associated with the resultant ventricular septal infarct was then evaluated to determine if this model accurately reflected the characteristics of human VT.

METHODS AND RESULTS

Seventeen dogs underwent occlusion-reperfusion ventricular septal infarcts. Four to 7 days later, electrophysiological studies were performed. VT was initiated by programmed electrical stimulation and terminated by pacing at a cycle length of 50% to 75% of the VT cycle length. Electrophysiological studies were performed using a 256-channel mapping system. A total of 15 VT morphologies were mapped in 9 animals. Fourteen of 15 morphologies had septal subendocardial sites of earliest activation and 1 had a septal midwall site of earliest activation. VT ablation was performed using a nitrous oxide cryoprobe and confirmed the site of earliest activation by subsequently rendering VT noninducible. Electrophysiological studies demonstrated four distinct VT activation sequences: (1) circular reentrant (n = 7), (2) concentric spread (n = 5), (3) figure-of-eight (n = 2), and (4) septal midwall (n = 1).

CONCLUSIONS

This canine model of ventricular septal infarction produces VTs with sites of earliest activation and activation sequences similar to those in humans. A reentrant mechanism as the basis of these arrhythmias is supported by the following observations: (1) all VT was initiated and terminated with programmed electrical stimulation; (2) VT activation sequences were consistent with reentry; and (3) precise interruption of the sequence terminated the VT and rendered it noninducible.

Reentrant ventricular arrhythmias in the late myocardial infarction period: mechanism by which a short-long-short cardiac sequence facilitates the induction of reentry

The electrophysiological mechanism by which a short-long-short stimulated cardiac sequence facilitates the induction of ventricular tachyarrhythmia was investigated in dogs 4 days after ligation of the left anterior descending coronary artery. In these dogs, reentry develops in the surviving electrophysiologically abnormal epicardial layer that overlies the infarct zone when premature stimulation results in a critically long arc of functional conduction block. The activation wavefront circulates around both ends of the arc, coalesces, and conducts slowly distal to the arc before reactivating sites proximal to the arc to initiate a figure-eight reentrant circuit. Epicardial isochronal activation maps and effective refractory periods (ERPs) were determined during three different stimulation protocols: A, a basic train of eight beats at a cycle length of 300 msec followed by a single premature stimulus (S2); B, a basic train of eight beats at a cycle length of 300 msec with abrupt lengthening of the last cycle of the train before S2 to 600 msec; C, a basic train of eight beats at a cycle length of 600 msec followed by S2. Protocol B was found to result in a differential lengthening of ERP at adjacent sites within the border of the epicardial ischemic zone, whereas protocols A and C induced, respectively, comparable shortening and lengthening of ERPs at the same sites. The differential lengthening of ERPs at adjacent sites resulted in an increased dispersion of refractoriness so that a premature stimulus induced functional conduction block between those sites. The development of a longer arc of conduction block and, hence, a longer reentrant pathway as well as slower conduction of the circulating wavefront during protocol B allowed more time for refractoriness to expire proximal to the arc and for the circulating wavefront to reexcite those sites to initiate reentry. The lengthening of ERP, associated with a single long cycle (protocol B), ranged from 44% to 79% of the total increase in ERP after a series of eight long cycles (protocol C). Epicardial sites with longer ERPs located close to the center of the ischemic zone showed more lengthening of refractoriness during protocol B compared with more normal sites near the border of the ischemic zone. This strongly suggests that the increased dispersion of refractoriness during protocol B is caused by the shorter memory of ischemic myocardium to the cumulative effects of preceding cycle lengths.

Ventricular arrhythmias in the subacute myocardial infarction period. High-resolution activation and refractory patterns of reentrant rhythms

Patterns of activation, functional conduction block, and effective refractory periods during reentrant activation were investigated in a 4-day postinfarction canine model using a 64-channel high-resolution (1 mm) bipolar electrode array. Lower resolution (3-10 mm) isochronal activation maps of the entire epicardial surface were constructed from 126 sites during the initiation and sustenance of reentry and showed reentrant wave fronts that circulated around arcs of functional conduction block. During initiation of reentry by premature stimulation, high-density recordings from these same regions showed that conduction block occurred abruptly, within 1 mm, and without prior decrement of the impulse. Electrograms recorded in proximity to the arc of block were comprised of two deflections: a local activation potential and an electrotonic potential reflecting activation 1 mm away; the reverse order of activation and electrotonus was observed on the opposite side of the arc of block. The occurrence of functional conduction block during premature stimulation in this model was correlated with abrupt increases in effective refractory periods of 10-120 msec (27 +/- 24 msec; mean +/- SD) within 1 mm or less. Neither the abrupt change of refractoriness nor functional conduction block appeared to depend on differences in excitability, the geometrical characteristics of the surviving epicardial layer, or the orientation of the myocardial fibers. During sustained reentrant activation, high-density recordings along the arcs of block showed split electrograms comprised of local activation and electrotonus, which were identical in morphology to those recorded during the initiation of reentry. The interval between the deflections was shorter at the ends of the arc and increased to a maximum value at the center of the arc. The activation potentials corresponded in time with activation of large isochronal regions on either side of the arc of block. There was evidence that at least part of the arc of block during sustained reentry represented thin discrete zones of constant block due to electrotonic influences of impulse penetration from both sides of the arc. Our results strongly suggest that continuous arcs of functional conduction block are a necessary prerequisite for both the initiation and the sustenance of reentrant activation in subacute canine myocardial infarction. Functional conduction block during the initiation of reentry was due to abrupt changes in refractoriness, within a distance of 1 mm or less.

Electrophysiologic effects of propranolol in intraventricular conduction disturbance

Sixteen patients underwent electrophysiologic studies before and after intravenous infusion of propranolol, 0.1 mg/kg. All of them had intraventricular conduction disturbances. A significant (p less than 0.01) increase occurred after propranolol in the mean spontaneous cycle length (mean change 122 ms) and the AH interval (mean 28 ms). The HV interval did not change significantly. The effective refractory period of the His-Purkinje system increased in 4 of 5 patients (mean net change 44 ms, p greater than 0.10). In 7 patients with phase 3 infranodal block, the longest cycle length for producing block increased after propranolol in 5 and remained unchanged in 2 (mean increase 40 ms, p less than 0.02). Two patients showed phase 4 atrioventricular block. Propranolol increased the critical cycle length by an average of 120 ms. Propranolol-induced bradycardia restored stable atrioventricular conduction in 2 patients with intermittent 2:1 block but facilitated the occurrence of high grade infranodal block in 1 patient. Thus, propranolol can impair His-Purkinje conduction in patients with preexisting infranodal abnormalities.

Nonhomogeneous electrophysiological changes and the bimodal distribution of early ventricular arrhythmias during acute coronary artery occlusion

There is experimental evidence that the bimodally distributed ventricular arrhythmias (phases Ia and Ib) during the first 30 min after coronary occlusion (CO) in dogs are not due to the same mechanism. In 39 dogs we related the incidence of phases Ia and Ib to the time courses of excitation thresholds (ET), refractoriness (REFR), conduction times (CT) and effective refractory periods (ERP) at 6-12 epicardial electrode sites within the ischemic zone. The regional collateral myocardial blood flow (RMBF-tracer microsphere technique) was determined in 14 out of the dogs. This measurement only served for rough grouping into dogs with low and higher RMBF at the electrode sites during ischemia. REFR was determined as temporal recovery of excitability at a constant current strength of 4-6 times preocclusion ET. ERP was intermittently measured at 2.0-8.0 mA. At low RMBF ET, REFR and CT increased very inhomogeneously (dispersion of ET increased from 0.06 to 2.42 mA) 2-8 min after CO, leading to Ia-arrhythmias (also depending on infarct size) which terminated as ET, REFR and CT partially recovered 10-30 min after CO, their dispersions being still markedly elevated. With further recovery of these electrophysiological parameters the phases Ib subsided. On the other hand, the ERP diminished for the most part within the first 10 min after CO with only minor further decrease. Remarkably the dispersion of ERP did not significantly increase within the ischemic zone (from mean = 15 +/- 5 ms to 22 +/- 8 ms at low RMBF and from 14 +/- 6 ms to 18 +/- 9 ms at higher RMBF, p = ns). As a consequence of the homogeneous and constant shortening of the ERP, the time course of REFR mainly was determined by the nonhomogeneous alterations of ET. At a higher RMBF there were only minor electrophysiological alterations, and Ia- or Ib-arrhythmias did not emerge. These results indicate a strong relation of the Ia- and Ib-arrhythmias to the ischemia-induced time courses and dispersions of ET, REFR and CT but not of ERP within the ischemic area. Although the phases Ia relate to a strong increase of ET, REFR and CT and the Ib-arrhythmias to a partial recovery of these parameters, both the Ia- and Ib-arrhythmias seem to depend on a "critical" extent of electrophysiological inhomogeneity within a "critical" mass of ischemic but excitable myocardium.

Transient bifascicular block during Prinzmetal's variant angina

A 49-year-old man had bradycardia-hypotension syndrome and transient right bundle branch block with left anterior fascicular block during an attack of Prinzmetal's angina. Coronary arteriography showed 50 percent obstruction of the proximal left anterior descending artery; subsequently, he had subtotal occlusion at the stenotic portion with ergonovine administration. The occurrence of this conduction abnormality with Prinz metal's angina suggests that diminished blood supply of the proximal His-Purkinje system is the probable mechanism.

Effects of sympathetic stimulation on refractory periods of ischemic canine ventricular myocardium

We studied the difference in effect of sympathetic stimulation on refractory periods of ischemic and non ischemic myocardium in eight dogs, and the effect of sympathetic stimulation on dispersion of refractory periods in ischemic myocardium in seven additional dogs. In the first group of dogs, refractory periods of ischemic sites averaged 164 +/- 2.2 msec (M +/- SEM) and those at non ischemic sites averaged 193 +/- 1.8 msec. Sympathetic stimulation shortened refractory periods at non ischemic sites to an average of 183 +/- 2.0 msec and prolonged refractory periods at ischemic sites to an average of 171 +/- 2.2 msec. As a result of the different effects of sympathetic stimulation on refractory periods of ischemic and non ischemic myocardium, refractory periods between ischemic and non ischemic areas were more uniform during sympathetic stimulation than during coronary occlusion alone. In the second group of dogs in which the effects of sympathetic stimulation on dispersion of refractory periods were studied, pooled variances in refractory periods were calculated. There was no statistically significant difference in the pooled variance of refractory periods during control periods and during sympathetic stimulation alone. Coronary occlusion alone significantly increased the variance in refractory periods, but there was no statistically significant difference in the variance of refractory periods during coronary occlusion alone and during coronary occlusion and sympathetic stimulation. Our findings suggest that at some times during the course of myocardial infarction the effects of high sympathetic tone may be partially protective with respect to arrhythmias by reducing inequalities of recovery between ischemic and non ischemic tissue.

Tachycardia-dependent left posterior hemiblock

A patient with intermittent tachycardia-dependent left posterior hemiblock is reported. Electrocardiographic patterns of complete and incomplete block were documented. Identification of the electrocardiographic characteristics of intraventricular conduction defects is aided when they are intermittent. The difficulty in diagnosing incomplete left posterior hemiblock, and the possible masking of the signs of previous inferior infarction by left posterior hemiblock are emphasised.

Tachycardia-dependent and bradycardia-dependent intraventricular conduction defects in acute myocardial infarction: electrocardiographic, electrophysiologic, and clinical correlates

Presence of rate-dependent (RD) intraventricular conduction defects (IVCD) was documented by inducing variations in heart rate in 30 acute myocardial infarction (AMI) patients (10 right bundle branch block, six left bundle branch block, 13 left anterior hemiblocks, and two left posterior hemiblocks). Five IVCDs were tachycardia-dependent (TD), 20 were bradycardia-dependent (BD), and six were both TD and BD. In TD blocks shortest cycles showing normal intraventricular conduction ranged from 410 to 1330 msec (697 +/- 84 SE); in BD blocks longest cycles with normal intraventricular conduction ranged from 450 to 1450 msec (962 +/- 52). In 60% of cases intermittent incomplete RD blocks were also present. In one patients RD-IVCD intermittency remained until discharge; in the others it lasted from 4 minutes to 10 days. Afterwards 19 RD-IVCDs disappeared and four became stable; six patients died during RD-IVCD intermittency period. Disappearance of RD block was preceded by gradual reduction in cycle length showing TD block and lengthening of cycles stopped beats with BD block. Serial observation of RD-IVCDs provides information about sequence of electrophysiologic effects on the intraventricular conduction system in clinical AMI.

Case reports of phase 4 paroxysmal atrioventricular block

Four cases of PAVB were reported, 3 of which manifested third-degree AV block, while one exhibited first-degree AV block, while one exhibited first-degree AV block. The location and mechanism of establishment and disappearance of PAVB was discussed. It was speculated that, in some cases, concealed conduction of P waves could promote depolarization of the injured area which displayed Phase 4 block and thus temporarily restore 1.1 AV conduction.

Transient tachycardia- and bradycardia-dependent left anterior and left posterior hemiblocks. Effects of isoproterenol

Tachycardia- and bradycardia-dependent, left anterior and left posterior hemiblocks as transient phenomena were registered in two patients spontaneously, and especially as a consequence of isoproterenol infusion. A chronic trifascicular type of A-V block was present in the first case, whereas in the second case a bradycardia-dependent left posterior hemiblock was registered during an acute myocardial infarction. In the first patient the isoproterenol effects were: (1) a shortening of the refractoriness and an increase of the conduction velocity in the injured fascicle, (2) an increase in the slope of phase-4 depolarization on the left posterior fascicle, and (3) a presumably shifting toward zero of threshold potential on the left anterior fascicle. Isoproterenol effects disappeared from 30 to 40 min after it was discontinued. In the second case the bradycardia-dependent left posterior hemiblock was registered during very fast heart rates (150 beats min). This finding supports the view that enhanced phase-4 depolarization is the main factor in the development of bradycardia-dependent intraventricular blocks in the course of acute myocardial ischemia.

A case of coexisting tachycardia- and bradycardia-dependent bilateral bundle branch block

Electrocardiograms and His bundle electrograms were presented from a patient with a rare combination of intermittent bilateral bundle branch block. Critical analyses of R-R intervals and evolution of bundle branch block patterns revealed both tachycardia dependent right bundle branch block and bradycardia dependent left bundle branch block. Evaluation of HV intervals on His bundle electrograms suggested an additional possibility of bradycardia dependent conduction delay in the right bundle branch system.

Effects of isoproterenol on abnormal intraventricular conduction

An isoproterenol infusion (1.0-4.0 microgram/min) was administered to 15 patients with intermittent bundle branch block (BBB) and two patients with apparently fixed BBB. Three main effects were documented: (1) In all patients with phase 3, or tachycardia-dependent, BBB, isoproterenol caused a pronounced shortening of refractoriness in the affected fascicle. (2) In patients showing phase 4, or bradycardia-dependent, BBB, isoproterenol prolonged the phase 4 block range, probably because of enhanced diastolic depolarization. In one patient (four studies) in whom phase 4 block was not present, isoproterenol caused the appearance of a phase 4 block range. (3) In the two patients with fixed BBB, isoproterenol restored conduction, probably as a result of a hyperpolarizing effect. This study shows that isoproterenol tends to restore or improve conduction related to tachycardia-dependent block, but may impair conduction related to bradycardia-dependent block.

Reentrant ventricular arrhythmias in the late myocardial infarction period. 7. Effect of verapamil and D-600 and the role of the "slow channel"

Reentrant ventricular arrhythmias (RVA) were analyzed in dogs 3--7 days after ligation of the anterior descending coronary artery using averaged "composite" recordings of electrical activity of reentrant pathways (RP) from the epicardial surface of the infarction zone (IZ). Verapamil (V) and D-600 (D) (0.2--0.5 mg/kg i.v.) resulted in slight-to-moderate improvement of conduction in RP with abolition of spontaneous RVA and RVA initiated by premature depolarizations. The effect of V was not blocked by pretreatment with propranolol (0.5 mg/kg i.v.). Using a standard microelectrode technique and strips of epicardial muscle from the IZ, D (0.5--1 X 10(-6) g/ml) slightly improved the upstroke velocity and membrane responses of depressed ischemic cells. In contrast, tetrodotoxin (5 X 10(-7) g/ml) further depressed or abolished action potentials of ischemic cells. We conclude: 1) the moderate antiarrhythmic effect of V and D on RVA is the result of improved conduction in RP; 2) this action is partly explained by improvement of a depressed sodium channel and is not related to catecholamine release; 3) slow-response action potentials play no significant role in the genesis of ischemia-related RVA, which probably results from depression of the fast response.

Prospective evaluation of intrahisian conduction delay

We prospectively evaluated 46 patients who had intrahisian conduction delay. Twenty-three had a split His potential and 23 had a prolonged HV interval with a normal QRS complex. In those with a split His, the interval between the two His potentials averaged 32.7 msec (range 9--90 msec); in nine patients this split His was demonstrated only by atrial pacing. The 20 patients from this group with 1:1 atrioventricular conduction have been followed for an average of 18.1 months (range 2--48 months). All are alive. Three have had syncope, but Holter monitoring revealed no bradyarrhythmias. In the 23 patients with a narrow QRS and prolonged HV interval, the HV interval averaged 73.7 msec (range 57--180 msec). Twelve of these patients received pacemakers at the time of the His bundle study, six had symptomatic atrioventricular block and five had symptomatic sinus pauses. The 11 patients who did not receive pacemakers have been followed for an average of 15.1 months (range 2--44 months). In three with recurrent syncope and five with dizziness, monitoring has revealed no bradyarrhythmias. One patient died from a myocardial infarction without arrhythmias. Further prospective evaluation of patients with intrahisian conduction delay without documented bradyarrhythmias is needed, but with follow-up averaging 17 months and up to 4 years, patients with intrahisian conduction delay and without documented bradyarrhythmias appear not to require prophylactic permanent pacemakers to decrease morbidity or mortality.

The significance of dissociation of conduction in the canine His bundle. Electrophysiological studies in vivo and in vitro

Fractionated His bundle potentials were induced by ischemia or trauma in 30 anesthetized dogs, in vivo. Functional dissociation, i.e., alteration of the activation sequence of portions of these His bundle potentials was demonstrated in vivo as well as in 10 in vitro preparations of the His-Purkinje system. In vivo, plunge wire and electrode catheters were utilized to record from portions of the His bundle. During vagal-induced slowing of the heart rate, atrial pacing or His bundle pacing, His-Purkinje conduction as measured by the H-V interval was constant over a wide range of heart rates, 50-300/min. One or two hours after anterior septal artery ligation, His bundle damage manifested as split His bundle potentials (H, H'). Atrial pacing or proximal His bundle pacing induced H-H' delays with concomitant right or left bundle branch block patterns in ECG leads. However, distal His bundle pacing at comparable or even higher rates produced normal QRS complexes. In other cases, during atrial pacing or with progressive ischemia at a constant rate, H' progressively delayed during the H-V interval or even disappeared into the QRS complex with a concomitant occurrence of right or left bundle branch block. In vitro, a dissected septal preparation was studied containing the His bundle, proximal and distal right bundle and left bundle branches. Normal conduction throughout the His-Purkinje system was observed at pacing rates of 30-220/min. Punctate lesions, anatomically placed above the branching His bundle caused tachycardia-dependent, complete bundle branch blocked with concurrent temporal reversal of proximal and distal His bundle action potentials. These data suggest that ischemic or traumatic lesions in the His bundle may manifest on the electrocardiogram as bundle branch block patterns. From a clinical point of view, a critical site of lesion would markedly increase the liability for A-V blocked although the electrocardiogram alone would not indicate the actual site of lesion. Predestination of fiber tracts and alternative proposals to the pedestination theory are considered to explain QRS aberration due to exclusive His bundle lesions.

Electrophysiologic observations in a patient with bradycardia-dependent atrioventricular block

In a patient with atrioventricular (A-V) block distal to the His bundle (H), 1:1 A-V conduction with right bundle branch block and H-V interval of 70 msec was established with atrial pacing at rates of 120 to 150/min, suggesting that the A-V block was bradycardia-dependent. Advanced second degree A-V block distal to the H deflection occurred with atrial pacing at 160/min after completion of A-V nodal Wenckebach periodicity proximal to the H deflection because of the long H-H encompassing the blocked P wave. Atrial extrastimulus testing coupled with sinus rhythm (with A-V block) demonstrated that critical H1-H2 intervals of less than 545 msec allowed conduction to the ventricles. The H2-V2 interval shortened progressively from 290 to 70 msec with shortening of these critical H1-H2 intervals. Atrial extrastimulus testing coupled with an atrial driven cycle lenght of 500 mesc (with intact A-V conduction) revealed block of the H2 deflection with an H1-H2 interval longer than 540 msec. In conclusion, at critical diastolic intervals, impulses were blocked, creating a state of decreased responsiveness. If a cycle length of subsequent impulses was shorter than the critical diastolic blocking interval, membrane responsiveness gradually improved and conduction resumed. If a cycle length of subsequent impulses was longer than the critical blocking diastolic interval, A-V block was sustained. Blocked impulses continually penetrated to the site of block and reset the state of membrane responsiveness.

The induction of ventricular arrhythmias in acute myocardial ischemia by atrial pacing with long-short cycle sequences

Recent studies emphasize the importance of heart rate in the genesis of ventricular arrhythmias during myocardial ischemia. The role of alterations in rhythm has not previously been systematically investigated. In 20 dogs subjected to acute myocardial ischemia and crushing of the sinus node, standard electrocardiographic leads were recorded, as well as His bundle and epicardial electrograms from the normal and ischemic areas. Abrupt pauses in regular atrial pacing did not cause arrhythmias prior to the onset of ischemia; however, during ischemia, atrial pacing with intermittent abrupt pauses resulted in the induction of ventricular arrhythmias beginning after the second conducted beat following each pause (ventricular premature beats, 20/20; ventricular tachycardia, 19/20; and ventricular fibrillation, 8/20). Onset of the arrhythmia was associated with increased delay in activation of ischemic epicardium and fractionation of the electrogram potential of the second conducted impulse. Typical Gouaux-Ashman phenomenon was an incidental observation. Unlike the Gouaux-Ashman phenomenon, which is restricted to the His-Purkinje system, the phenomenon we observed orginated within ischemic myocardium. In vitro studies indicate that the underlying mechanism may be related to postrepolarization refractoriness induced by ischemia.

Atrioventricular block after reciprocating atrioventricular junctional tachycardia

Short runs of symptomatic atrioventricular (A-V) block occurred after spontaneous cessation of reciprocating A-V junctional tachycardia in a patient with right bundle branch block, normal H-V interval and sinus nodal dysfunction. These episodes were characterized by long (more than 1 sec) P-P intervals during which the A deflections were not followed by His bundle electrograms. Three possible explanations are: (1) a posttachycardia-induced period of abnormally prolonged A-V nodal refractoriness; (2) pseudo-A-V block produced by concealed A-V junctional tachycardia, or (3) bradycardia-dependent (phase 4) A-V block at the "upper" His bundle, above the site from which the H deflection was recorded.

Electroide cather recording during malignant ventricular arrythmia following experimental acute myocardial ischemia. Evidence for re-entry due to conduction delay and block in ischemic myocardium

In 20 anesthetized opened-chest dogs, plunge wire and electrode catheter recordings of the this bundle electrogram which also showed septal activation, were monitored before and after ligation of the anterior septal artery. The average time to onset of ventricular tachycardia after ligation was 5-1/2 min. The evolution of the arrhythmia was temporally related to progressive fragmentation and delay of the septal potential, resulting in a marked increase in total ventricular activation time (up to 335 msec). In six experiments the fragmented, delayed septal depolarization was inscribed well beyond the T wave of the surface QRS prior to the onset of arrhythmias. Various conduction disorders involving the ischemic septal myocardium were observed which closely correlated to the patterns of conduction disorder in the ischemic proximal His-Purkinje system. First degree block, 2 degree block of the Mobitz II and Wenckebach types, higher degree block and paroxysmal complete block occurred. The onset of the arrhythmia was characteristically associated with a Wenckebach pattern of conduction delay of a part of the septal deflection. Conduction disorders of the ischemic myocardium were tachycardia-dependent. Bradycardia resulted in recovery of form, duration, and timing of the septal potential with the coincident disappearance of ventricular arrhythmias. The study shows that the basic prerequisites for re-entry do exist during the early period following occlusion of a major coronary artery and can explain the malignant phase of ventricular arrhythmias. Similar disorders in man may be detected by intracardiac electrode catheter recordings.

His bundle recordings in bradycardia-dependent AV block induced by premature beats

Symptomatic bradycardia-independent atrioventricular block occurred in a patient with right bundle-branch block, left anterior hemiblock, and prolonged HV interval. The arrhythmia, triggered by a spontaneous or induced premature beats, appeared when the post-extrasystolic PP and HH intervals increased to a critical value. Reinitiation of atrioventricular conduction required the presence of ventricular escapes. Bradycardia-dependent atrioventricular block was related to either an enhanced or slightly rising slope of diastolic depolarization, or to a decrease in membrane responsiveness. The patient also, most probably, had tachycardia-dependent atrioventricular block. Both types of conduction disturbance occurred in the same part of the intraventricular conducting system, either in the low His bundle or left bundle-branch or its posteroinferior division. It is suggested that the electrophysiological study of cases with prolonged HV intervals should include procedures which can expose bradycardia-dependent atrioventricular block.

Three variants of concealed bigeminy

Long electrocardiographic strips were analyzed from five patients who exhibited periods of typical "concealed bigeminy," i. e., recurrent unifocal extrasystoles which were separated from one another by odd numbers of normally conducted sinus beats. However, in each of these patients, there were periods in which one of three different variants of concealed bigeminy was observed. Three patients displayed an "even number" variant; i. e., there were large numbers of consecutive extrasystoles which were separated exclusively or preponderantly by even rather than by odd numbers of sinus beats. One other patient exhibited an "interpolated extrasystole" variant: those interectopic intervals which were initiated by an interpolated extrasystole contained an even number of sinus beats, whereas all other interectopic intervals contained an odd number. In the fifth patient, the distribution of the numbers of sinus beats separating extrasystoles was such as to suggest a periodic fluctuation between the classical forms of concealed bigeminy and concealed trigeminy; i. e., a "combined bigeminy and trigeminy" variant.

Multiform ventricular ectopic rhythm. Evidence for multiple parasystolic activity

Six patients whose standare electrocardiograms showed multiform ventricular ectopic rhythm were studied. All patients had advanced organic heart disease and a significant intraventricular conduction defect (left bundle branch block in five and right bundle branch block plus left anterior hemiblock in one). The ventricular arrhythmia was generally resistant to antiarrhythmic therapy. Five of the six patients died after 2 to 6 months form the period of observation from terminal heart failure. None died suddenly. The ventricular arrhythmia did not seem to be directly related to mortality in any patient. Critical analysis of several long rhythm strips in each case revealed that discharge from multiple ventricular parasytolic foci shared in the multiform ventricular activity. The concurrent discharge of a minimum of three parasytolic foci and a maximum of six foci was found in the same case with a total of 24 parasystolic foci in the six patients. There was a remarkable constancy of the QRS configuration of all parasytolic foci over periods of observation of up to 16 months. However, 22 out of 24 parasystolic rhythms showed significant variation in the apparent rhythm or the administration of drugs. Fourteen parasytolic foci showed evidence of exit block, some of which were exaples of a rapid parasystole with a high degree of exit block. The study suggests that multiform ventricular ectopic rhythm may, in part, be due to the concurrent discharge of multiple parasystolic foci.

Pathophysiology of second degree atrioventricular block: a unified hypothesis

An in vivo and in vitro correlative study of second degree atrioventricular (A-V) block in the canine proximal His-Purkinje system after ligation of the anterior septal artery is reported. Evidence is presented to suggest that Mobitz type II and the Wenckebach ypte of conduction represent different degrees of the same disorder rather than two distinct electrophysiologic processes. The in vivo study showed that an increment of conduction delay almost always preceded the blocked impulse in second degree A-V block. The increment, as 1 or 2 msec at the early stage of block, often increased gradually up to 180 msec. The in vitro study consistently showed an increment of conduction delay preceding the blocked impulse. The same experiments revealed a greater increment in conduction delay early after excision that, on recovery during superfusion, gradually decreased to a few milliseconds (the reverse order of the in vivo observation). Characteristic changes in duration and configuration of action potentials in the ischemic proximal His-Purkinje system were observed depending on the state of transmission and the temporal relation of the impaled cell to areas of slow propagation and block. The study revealed a remarkable similarity between characteristics of conduction in the ischemic His-Purkinje system and conduction in both the normal A-V doe and Purkinje fibers subjected to various pathophysiologic interventions. It is suggested that in the pathologic situation--exemplified in this study by acute myocardial ischemia--the normal His-Purkinje system may gradually lose the characteristics of the fast response and start showing properties of the slow response. At an early stage of departure from normal, the proximal His-Purkinje system may show second degree A-V block with no perceptible to a few milliseconds' increment of conduction delay (the equivalent of Mobitz type II block). On further departure from normal, the His-Purkinje system resembles the A-V node in showing a significant increment of conduction delay prior to the blocked impulse (the equivalent of Wenckebach periodicity). Both the in vivo and in vitro observations demonstrated a clear propensity of the ischemic proximal His-Purkinje system to develop paroxysmal A-V block during the stage of second degree A-V block when there is no perceptible to a few milliseconds' increment of conduction delay. A new classification of second degree A-V block is presented based on the suggested electrophysiologic mechanism.

Disorders of cellular electrophysiology produced by ischemia of the canine His bundle

In the first 4 hours after occlusion of the anterior septal coronary artery, 18 dogs developed bundle branch block, heart block, or both. The hearts were then excised, and preparations were dissected to expose the His bundle and the bundle branches, which were superfused with modified Tyrode's solution at 37 degrees C. In the His bundle and the most proximal bundle branches, resting potentials were reduced and diminutive action potentials had slow upstrokes, often with notches or steps. Action potentials were generated by fibers that had resting potentials between--40 and --50 mv. Conduction was impaired; conduction velocities less than 0.01 m/sec were sometimes observed. In more severely affected cells, refractoriness outlasted repolarization. Encroachment on the prolonged refractory period resulted in further diminution of action potentials and continuous rather than intermittent block. More commonly, the response to rapid rate took the form of intermittent block with progressive conduction delay in the series of conducted beats, culminating in a blocked beat (Wenckebach sequence). There was a fatigue factor that accumulated at short cycle lengths and depressed the action potential. Automaticity was not enhanced, but pacemaker function was abnormal. The threshold potential shifted erratically, and pacemaker potentials sometimes were intermittently diminished, resulting in intermittent failure to propagate. During prolonged superfusion, there was a tendency to recover with a drift of the maximum diastolic potentials toward more negative levels. None of these changes were found in ten hearts excised from dogs in which the coronary artery had not been ligated.

The pathophysiology of malignant ventricular arrhythmias during acute myocardial ischemia

In 20 anesthetized open-chest dogs, epicardial electrograms were recorded from ischemic and nonischemic zones of the left ventricle during acute occlusion of the left anterior descending artery. The average time to onset of ventricular tachycardia during atrial pacing (150-200 beats/min) was 4 min, 18 sec. In 18 dogs, ventricular ectopic beats were induced in normal and ischemic zones after every tenth atrial stimulus. Those induced in the ischemic zone consistently caused ventricular tachycardia earlier (mean: 3 min, 22 sec) than those in the normal zone (mean: 4 min, 11 sec) ( P < 0.01). This arrhythmia, whether spontaneous or induced, always followed the complex which demonstrated the greatest delay of the ischemic zone potential and increased ventricular activation time. Ventricular tachycardia was repeatedly produced by ectopic beats with late diastolic coupling. Analysis of the episodes of tachycardia leading to fibrillation revealed a progressive increase in the ventricular activation time of the successive beats, whereas in those self-terminating episodes ventricular activation time progressively decreased. These data suggest that the major determinant of malignant ventricular arrhythmias in acute ischemia may be the related abnormalities of ventricular activation rather than the coupling of the premature ectopic beats.