Ventricular quadrigeminy as a manifestation of concealed bigeminy.

Long rhythm strips were analyzed from five patients with frequent ventricular extrasystoles. The predominant pattern was quadrigeminal; i.e., three sinus beats between extrasystoles. However, about 20% of the interectopic intervals contained numbers of sinus beats (S) greater than three. Analysis of the distribution of such values of S greater than 3 revealed that there were many more odd than even values (P less than 0.001). Also, carotid sinus pressure yielded only odd values of S greater than 3. This predominance of odd values strongly suggested the existence of concealed extrasystoles. Therefore, all odd values of S greater than 3 were analyzed to determine whether they satisfied the criterion for concealed bigeminy (S = 2n - 1) or for concealed quadrigeminy (S = 4n - 1). The distribution was found to satisfy the criterion for concealed bigeminy, suggesting that the quadrigeminal pattern was a manifestation of a 2:1 rather than a 4:1 block in a re-entry loop. Stable quadrigeminy occurs often in concealed bigeminy, because the re-entrant impulse finds the myocardium excitable after a normal R-R interval but refractory after a compensatory pause.     

A subvariant of concealed bigeminy.

A subvariant of the "even variant" of concealed bigeminy was studied in two patients. The typical pattern consisted of two types of sequences of conducted sinus beats between extrasystoles. One pattern was bigeminal, i.e., alternating sinus beats and extrasystoles. Between bigeminal sequences were intervals in which there were more than one conducted sinus beat between extrasystoles. In such longer sequences, the numbers of sinus beats were almost invariably even. In the bigeminal sequences, the coupling intervals progressively diminished for each successive extrasystole in the sequence. The proposed explanation for the subvariant was based on a reentry loop in which there were three sites of block: proximal, intermediate, and distal. Block was postulated to take place at the proximal site after those extrasystoles with the shortest coupling intervals, at the intermediate site after odd-numbered conducted sinus beats in the non-bigeminal sequences, and at the distal site ("concealment") after the even-numbered sinus beats in these longer sequences.     

Concealed atrial bigeminy and trigeminy.

Patterns indicative of concealed atrial extrasystoles were observed in two patients with frequent premature atrial depolarizations. In the first patient, the predominant pattern was such that most of the numbers (S) of sinus P waves between atrial extrasystoles satisfied the equation S = 3n-1, where n is any positive integer. This pattern is characteristic of concealed trigeminy. Over a sequence of 49 interectopic intervals, this patient vacillated between concealed atrial trigeminy and bigeminy. A second patient displayed a pattern characteristic of the "even number" variant of concealed bigeminy. The numbers of sinus P waves in consecutive interectopic intervals were predominantly even. These various patterns of concealed atrial extrasystoles closely resemble previously reported patterns of concealed ventricular extrasystoles.     

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.     

Ventricular ectopic beats with exit block: a retrospective Holter monitor study

A retrospective study was conducted to define the incidence of ventricular ectopic beats with exit block (concealed extrasystoles). Of 904 Holter recordings, 92 were admitted for study on the basis of sufficient ventricular ectopic beats on rhythm strips. Concealed bigeminy conforming to the equation of S = 2n - 1 (where S = the interectopic sinus beat and N = any interger) was the most common and occurred in 42 of 92 (46%) Holters included in this study. Concealed trigeminy was observed in 12 of 92 (13%) studies. These Holters also showed ventricular ectopic beats strongly suggestive of parasystole with entrainment. Of 53 Holters reviewed for parasystole 12 were suggestive of, and five indicated this dysrhythmia. We conclude that: 1. Concealed extrasystoles are more common than previously appreciated. 2. Concealed bigeminy and trigeminy appear together and conversion may not always be associated with a change in heart rate. 3. Recognition of this dysrhythmia is uncommon mostly because of inadequate lengths of rhythm strips. 4. Parasystole with entrainment is suggested as a common dysrhythmia when frequent extrasystoles are present.     

Concealed quadrigeminy and quintageminy

Electrocardiographic rhythm strips were analyzed from three patients who had frequent unifocal extrasystoles. Parasystole was excluded in all three cases. Analysis of the distributions of the numbers (S) of conducted sinus beats between extrasystoles revealed that the distributions conformed to two variants of concealed quadrigeminy (namely, the "S = 4n" and "S = 4n - 2" variants) and to one variant of concealed quintageminy (namely, the "S = 5n - 2" variant). The binomial theorem was used to test the likelihoods that these patterns of distribution of extrasystoles could occur on the basis of chance alone; the probabilities were all extremely small.     

Repetitive supernormal conduction in the right bundle branch in high degree bilateral bundle branch block

Electrocardiograms were taken from a 67-year-old woman with high-degree atrioventricular block in which ventricular escape beats of right bundle branch block pattern occurred, accompanying occasional ventricular capture beats. Only when a sinus P wave occurred 0.60 s after the preceding escape beat, it was followed by a capture beat of left bundle branch block pattern with the RP interval of 0.60 s and the PR interval of 0.19 s. Similar left bundle branch block with left axis deviation pattern had been shown in the electrocardiogram taken 2 years before. Such RP and PR intervals in capture beats were invariable. These suggest that capture beats occurred as a result of supernormal conduction in the right bundle branch, which denies the possibility of ventricular extrasystoles. Such capture beats with the above RP and PR intervals were observed repeatedly.     

Second degree entrance block with supernormal conduction in intermittent ventricular parasystole

A patient with intermittent ventricular parasystole is reported in whom the presence of second degree entrance block with supernormal conduction was suggested for the first time. In this patient, ventricular extrasystoles with variable coupling frequently occurred. The QRS configuration of the extrasystoles was different from that of the parasystolic beats. When extrasystoles did not occur, the parasystolic beat was never seen because the conducted sinus impulse always reset the parasystolic rhythm. When an extrasystole occurred 0.52 sec or more after the preceding sinus beat, this extrasystolic impulse also reset the parasystolic rhythm. On the other hand, when an extrasystole occurred between 0.47 and 0.51 sec after the sinus beat, the parasystolic focus was protected from this extrasystolic impulse. When, however, an extrasystole occurred in a short terminal portion of the T wave of the preceding sinus beat, this extrasystolic impulse reset the parasystolic rhythm again, suggesting entrance block failure during the supernormal phase.     

Concealed ventricular hexageminy

The authors report a case of concealed ventricular hexageminy in which, with a few exceptions, extrasystoles were separated by sinus beats conforming to the formula 6n - 1. Whenever an exception to this formula occurs, the intervening beats are not all of sinus origin, but include also a ventricular extrasystole that is different from those occurring in hexageminal distribution. The pattern is explained by a parasystolic rhythm modulated by sinus impulses, assuming a 3:1 ratio between the parasystolic cycle and the sinus cycle. Such a ratio would have to be associated with a trigeminal or concealed trigeminal distribution. There is, however, a 2:1 ectopic-ventricular block, leading to a change of the ectopic distributional pattern from the expected concealed trigeminy to that of the concealed hesageminy.     

Concealed ventricular extrasystoles due to interference and due to exit block.

Two cases of sinus rhythm with ventricular extrasystoles are reported in which extrasystoles arising from the same focus obey the rule of "comcealed bigeminy" and the "rule of bigeminy". In a comparatively rapid sinus rhythm, shortening of the sinus cycle favors the appearance of extrasystoles, and the extrasystoles obey the fule of "concealed bigeminy"; namely, sinus impulses intervene between extrasystoles in even numbers. The sinus impulses here include those both conducted and not conducted to the ventricles. Conversely, in a comparatively slow sinus rhythm, interectopic sinus impulses appear in odd numbers only, and the extrasystoles obey the "rule of bigeminy"; namely, lengthening of the sinus cycle favors the appearance of extrasystoles. From these observations, a new mechanism governing both of the rules is suggested as follows. Ectopic impulses arise following all the interctopic sinus beats, but they become concealed extrasystoles of two types. One of them is the "concealed extrasystole due to interference at the external end of the ventricular-ectopic (V-E) junction."The other is the "concealed extrasystole due to exit block within the V-E junction" because of refractoriness following stimulation. They alternate with each other. In the of "concealed begeminy", the last concealed extrasystole intervening between manifest extrasystoles is due to exit block, whereas in the "rule of bigeminy", it is due to interference.     

Progressively decreasing ectopic to second sinus beat intervals in concealed trigeminy

A case of classical concealed trigeminy is reported in which the concealed ventricular extrasystoles occur due to a progressive shortening of the intervals in between manifest extrasystoles and their subsequent conducted second sinus beats. The specific mechanisms underlying such a remarkable phenomenon remain to be explained.     

Simultaneous but separate intermittent and continuous ventricular parasystole

A 19 year old female with end-stage biventricular congestive cardiomyopathy and digitalis toxicity demonstrated double ventricular parasystole with separate but simultaneous intermittent and continuous parasystolic rhythms. The intermittent parasystolic focus, left ventricular in origin, showed failure of entrance block when conducted beats followed its ectopic beats at a critical compensatory interval. Each new parasystolic series was coupled to this interrupting conducted beat at an interval equaling the parasystolic cycle length. Even numbers of conducted beats intervened between ectopic beats during intermittency and odd numbers during uninterrupted parasystole. The mechanism of intermittency was explained by a concealed ventricular tachycardia with 3 3n1 exit block with the demonstration of occasional 3 3n2 Wenckebach exit block within a parasystolic interectopic interval.A second continuous parasystolic rhythm, right ventricular in origin, occurred at a later time without altering the first intermittent parasystolic rhythm.A 4% parallel and proportionate lengthening of both the sinus node and intermittent parasystolic cycle lengths was shown at an even later time.     

Rate dependent variation in concealed bigeminy

A 63 year old man with angina pectoris was found to have frequent extrasystoles separated by odd as well as even numbers of conducted sinus beats. Analysis of 935 conducted sinus beats showed that premature ventricular beats without interpolation were separated by odd numbers of conducted sinus beats in 117 sequences and even numbers (exceptions) in 48 sequences (p less than 2 X 10(-4)). Tabulation of cycle lengths revealed that cycles with even numbers of conducted sinus beats were characterized by a significant reduction in the preceding postextrasystolic pause (1441+/-76 msec vs. 1487 +/-59 msec; p less than .001) and second sinus cycle (720 +/- 44 msec vs. 750 +/- 38 msec; p less than .001). Premature ventricular beats were interpolated in 41 additional sequences. Interpolated extrasystoles were separated by the expected even numbers of conducted sinus beats in 39 cases and odd numbers (exceptions) in only two cases. The frequency of exceptions to the usual rules for concealed bigeminy was therefore 2/39 during interpolation and 48/117 without interpolation (p less than .01). This case demonstrates that: 1) a reduction in cycle length may be associated with exceptions to the usual rules for concealed bigeminy, and 2) the frequency of exceptions to concealed bigeminy may be altered by the presence of interpolation. Only one previous case has contained statistical documentation of these circumstances. The diagnosis of a concealed ventricular rhythm may be facilitated by careful analysis at multiple cycle lengths.     

Modulated ventricular parasystole as a mechanism for concealed bigeminy

Concealed extrasystolic ventricular bigeminy reflects a distributional pattern of ventricular extrasystoles where intervening sinus beats are always in odd numbers. This has been explained on bigeminal rhythm associated with exit block. This presentation reflects a modification of this concept in that the distributional pattern may be explained on the basis of complex concealed modulation of ventricular parasystole, the concealment being due to impulses falling within the refractory period rather than suffering true exit block.     

Intermittent parasystole with concealed extrasystolic bigeminy during myocardial infarction.

A 72-year-old man demonstrated persistent intermittent ventricular parasystole for 6 days during an acute inferior wall myocardial infarction. Entrance block failure occurred at a critical interval of 1.24 sec. after parasystolic beats with resetting of the parasystolic cycle length. The first ectopic beat in each parasystolic series showed coupling to its second preceding conducted beat, and successive cycle lengths in each series usually showed gradual shortening. Concealed extrasystolic bigeminy was also demonstrated between parasystolic series with the number of intervening conducted beats conforming to the formula 2n + 2. After interpolated parasystolic beats, this formula became 2n + 3.     

Pseudo bundle branch block produced by premature impulses arising in the bundle branches.

Pseudo bundle branch block, a previously unreported arrhythmia produced by concealed premature impulses arising in the bundle branches, was seen in two patients with sick sinus node syndrome. Although concealed conduction was not apparent in either the surface or intracardiac leads, the latter were essential in localizing the site of manifest impulse formation. Patient 1, with left bundle branch extrasystoles, had pseudo bundle branch block and pseudo atrioventricular block that depended on the timing and extent of concealment of premature depolarization. Because of the coexisting sinus bradycardia in this patient, electrical stimulation and the recording of the right ventricular apical electrograms gave additional information that helped corroborate the postulated mechanisms. Patient 2 had right bundle branch extrasystoles with sinus beats that showed a right bundle branch block pattern possibly caused by pseudo bundle branch block. In this case the possibility that both the automaticity and the conduction disturbance had a mechanical origin could not be excluded.     

QT dispersion in sinus beats and ventricular extrasystoles in normal hearts.

OBJECTIVE--Recent studies have suggested that QT interlead variability (dispersion) on the surface electrocardiogram may have potential as a measure of recovery time dispersion. To test this hypothesis further QT dispersion occurring in sinus beats was compared with that in ventricular extrasystoles. DESIGN--Simultaneous electrocardiograms were recorded at 50 mm/s during sinus rhythm in a drug free state while ventricular extrastimuli were introduced by programmed right ventricular stimulation at different coupling intervals. QT dispersion, defined as the difference between the maximum and minimum QT, was calculated separately for the extrasystoles and preceding and following sinus complexes. To correct for the influence of the number of measurable leads on QT dispersion, an "adjusted" QT dispersion calculated as QT dispersion/square root of the number of measurable leads, was used to compare sinus complexes and extrasystoles. PATIENTS--Nine patients were studied who were undergoing electrophysiological study for investigation of palpitation and were found to have electrically normal ventricles. RESULTS--At all coupling intervals tested "adjusted" QT dispersion was significantly greater in the ventricular extrasystoles than in either the preceding or following sinus complexes. For the coupling interval 350 ms, the 95% confidence intervals for the difference between means was 52 to 78 ms (preceding sinus complex) and 56 to 82 ms (following sinus complex) (p less than 0.00001). There was no correlation between the coupling interval and the magnitude of the "adjusted" QT dispersion. CONCLUSION--These results accord fully with expected differences in ventricular recovery time dispersion and offer further support for the hypothesis that QT dispersion reflects regional variation in ventricular recovery. If substantiated by invasive studies, these findings have wide implications for both the usefulness and the method of QT measurement.     

Concealed junctional bigeminy inducing pseudo 2:1 AV block

This case report describes the electrocardiographic features of concealed junctional premature beats. When the junctional premature beats occurred in a bigeminal fashion, pseudo 2:1 AV block occurred. The presence of 2:1 AV block was related to the prematurity (H1-H2) of the junctional extrasystoles, in which coupling intervals less than 425 msec were concealed and those greater than 425 msec were manifest. This report is unusual in that persistent long runs of pseudo 2:1 AV conduction were established. In addition, the extrasystolic beats demonstrated exit block and the interectopic sinus beats (n) followed the formula 2n-1.     

Role of the compensatory pause in the production of concealed bigeminy

In experiments conducted on anesthetized dogs, a single prolonged cardiac cycle caused an increase in the duration of the refractory period of the ventricular myocardium. The refractory period remained prolonged for one or two additional cardiac cycles after the basic cycle length was resumed. In concealed bigeminy, a 2:1 block in a reentry path is postulated. The compensatory pause that follows a manifest extrasystole results in a prolongation of the refractory period. If the refractory period exceeds the propagation time of the next ectopic impulse conducted through the reentry path, that ectopic impulse will be concealed. However, if the refractory period does not exceed the propagation time, another extrasystole will occur, and a bigeminal sequence will ensue. Consecutive compensatory pauses appear to exert a cumulative effect on refractory period duration, so that for critical propagation times, the bigeminal pattern will be terminated briefly when an ectopic impulse becomes concealed. A quadrigeminal pattern occurs when the propagation time in the reentry loop lies between the refractory period durations of the beat terminating a compensatory pause and the beat that occurs two sinus cycles later. In concealed bigeminy where an odd number of conducted beats greater than five lies between extrasystoles, the propagation time in the reentry path is just less than the refractory period of the ventricular cells during normal sinus rhythm at the prevailing heart rate. Random increases in propagation time or decreases in refractory period result in manifest extrasystoles.     

Mechanism of escape, extrasystolic, and parasystolic arrhythmias. Study on an electrical analogue.

A simple analogue of the heart consisting of a system of neon relaxation oscillators is presented. The analogue may display rhythm patterns similar to sinus rhythm, escape rhythm, isorrhythmic dissociation with synchronization, atrial extrasystoles, ventricular extrasystoles, and parasystole. The strict rules followed by these arrhythmias, as well as the deviations from the rules commonly followed by the equivalent heart arrhythmias, may be easily reproduced on the analogue. Such features are the Treppe phenomenon and captured beats in escape rhythm, fixed coupling intervals in extrasystoles, partial or complete atrioventricular block in very premature atrial extrasystoles, prolongation of the period following an atrial extrasystole, interpolated premature beats, complete compensatory pause and the rule of bigeminy in ventricular extrasystoles, slight instability of the parasystolic period, multiple length parasystolic periods slightly different from the exact multiples of the parasystolic idioperiod, preference of the parasystoles for certain phase in the sinus cycle, synchronization at a phase difference and fluctuation repeatedly and without interruption from a parasystolic to an extrasystolic rhythm and synchronization in escape rhythm with isorrhythmic dissociation. The mechanisms involved in these phenomena are discussed in detail. The striking similarity between the properties of the cardiac pacemakers and those of the relaxation oscillators on the one hand and betwen the rhythm patterns of the heart and those of the analogue on the other may permit the hypothesis that the mechanisms operating in the analogue may be used in analyzing and understanding heart arrhythmias.