Coupling Interval Of Premature Beats Research Articles

Bachmann’s Bundle

Bachmann’s bundle (BB), also known as the interatrial bundle, is well recognized as a muscular bundle comprising of parallel aligned myocardial strands connecting the right and left atrial walls and is considered to be the main pathway of interatrial conduction.1 Disruption of the bundle’s structure causes interatrial conduction block (IAB),2 which is associated with development of various atrial tachyarrhythmias3,4 and with electromechanical dysfunction of the left atrium.5 Technological progress providing sophisticated mapping and imaging techniques in the past decade has increased our knowledge of specific anatomic structures and their role in development of both atrial brady- and tachyarrhythmias. This review outlines the current knowledge of the relation between anatomic and electrophysiological properties of BB and its possible role in initiation and perpetuation of atrial fibrillation (AF). In 1963, Thomas N. James described 3 pathways connecting the sinus node to the atrioventricular node (AVN), namely the anterior, medial, and posterior internodal pathways.6 Whether these conduction pathways were because of the presence of specialized conduction tissue or because of the anisotropic orientation of the muscle fibers remains controversial. Nevertheless, James described the anterior pathway as leaving the sinus node in anterior direction and giving off a secondary branch at the level of the superior vena cava to form BB.1 BB stretches subepicardially across the interatrial groove (septal raphe). It is at the interatrial groove that the BB can be identified as a discrete bundle (Figures 1 and 2) separated by fatty tissues from the infolded right atrial wall that is the limbus of the oval fossa. Notably, the bundle is not surrounded by a fibrous tissue sheath. Instead, the bundle is comprised of strands of atrial myocardium that are similarly aligned in parallel fashion. Its rightward and leftward extensions bifurcate to pass to either …

Observations on the onset of torsade de pointes arrhythmias in the acquired long QT syndrome.

Premature ectopic beats may create a specific sequence of events (e.g. short-long-short) preceding Torsade de Pointes arrhythmias (TdP) in the long QT syndrome. The relevance of this sequence for the initiation of TdP is not clear. In our dog model of TdP, interventricular dispersion (DeltaAPD=left-right ventricular monophasic action potential duration: APD) is associated with TdP, therefore we tested the hypothesis that the ectopic beats contributes to DeltaAPD. In 17 anaesthetized dogs with chronic AV-block, which showed spontaneous TdP after class III medication, APD was analyzed to 1. quantitate the alterations due to (multiple) ectopic beats on the left and right APD (measured with endocardial catheters) and 2. compare the DeltaAPD prior to the occurrence of premature beats (steady state) in dogs with non-sudden onset of TdP (n=10) and sudden onset TdP (n=7). Three phases were distinguished: phase 1: steady state beats prior to ectopic beats, phase II: the beat(s) belonging to the dynamic phase, and phase III: the beat causing TdP. Because the coupling interval of premature beats in this condition often falls within the APD, the DeltaAPD(50) was validated as an alternative for the previously applied DeltaAPD(100) (r=0.51, P<0.01). In steady state (phase I) DeltaAPD(50) is longer in the sudden onset TdP (130+/-35 ms) as in the non-sudden onset TdP (65+/-40 ms). In the non-sudden TdP group the dynamic phase II contribute to the heterogeneity in APD, i.e. LV-APD increases more than RV-APD leading to a DeltaAPD(50) increase to 130+/-100 ms (P<0.01) just preceding TdP (phase III). The synergism between ectopic beats (short-long-short sequence) and DeltaAPD create the circumstances for TdP initiation.

Effect of nifedipine and AQ-A 39 on the sinoatrial and atrioventricular nodes of the rabbit and their antiarrhythmic action on atrioventricular nodal reentrant tachycardia.

The effects of two drugs that apparently block slow inward current--nifedipine and the new compound AQ-A 39--were studied on the isolated sinoatrial (SA) and atrioventricular (AV) nodes of the rabbit heart using intracellular microelectrodes. Nifedipine and AQ-A 39 both slowed the sinus rate associated with a decrease in the rate of diastolic depolarisation. Conduction through the AV node was consistently impaired; this effect was enhanced with increasing atrial rates or with decreasing coupling intervals of premature beats. The action potential amplitude was significantly reduced in SA nodal and upper (AN) AV nodal fibres but was not significantly affected in lower (NH) AV nodal and in atrial fibres. The maximum diastolic potential showed little or no alteration. In all fibre types studied, the action potential duration was shortened with nifedipine but was significantly prolonged with AQ-A 39. Prevention of AV nodal reentrant tachycardia by nifedipine was related to an increase in the effective refractory period of the AV node. AQ-A 39 prevented the tachycardia by both slowing of AV nodal conduction and by prolongation of action potential duration in the AV nodal and atrial compartments of the reentrant circuit associated with the appearance of different gap phenomena of the AV conduction. The maximum possible A-H interval was, however, not shortened by either drug and single atrial echo beats could still be initiated. The results suggest that nifedipine and AQ-A 39 both have a direct depressant action on the slow inward current-dependent electrical activity of the SA and AV node but have opposite effects on the repolarisation phase resulting in different antiarrhythmic mechanisms.

Frequency potentiation and postextrasystolic potentiation in patients with and without coronary arterial disease.

Frequency potentiation and postextrasystolic potentiation of myocardial contractility were induced in 17 patients found not to have cardiac disease (group 1) and in 10 patients with coronary arterial disease (group 2). Atrial stimulation was performed starting at a rate of 110/min and going up to 200/min (frequency potentiation). Single, premature ventricular beats with decreasing coupling intervals were induced every fifteenth beat during basal atrial stimulation at 125/min, after which compensatory pauses were provided (posts used an an index of contractility. With increasing heart rate dp/dt max was augmented equally, in both groups of patients, by frequency increases and premature beats (the coupling interval of the extrasystole being expressed as heart rate). dp/dt min and left ventricular systolic pressure remained unchanged while left ventricular end-diastolic pressure decreased in both groups of patients with the two forms of potentiation It was concluded that both these forms of potentiation have the same augmenting effect on myocardial contractility. Shortening the coupling intervals of premature beats caused a decreased in left ventricular end-diastolic pressure, suggesting that the Frank-Starling mechanism was not involved in postextrasystolic potentiation. Patients with coronary arterial disease had lower values of dp/dt max, dp/dt min, and higher values of left ventricular end-diastolic pressure during rest and stimulation procedures, while the systolic pressures equalled those in the control group. Though individual case values from the healthy and diseased hearts might be similar, it was only under the stress of potentiation that the true state of contractility was made apparent. Impairment of dp/dt min was not found without an impairment of dp/dt max in the presence of myocardial ischaemia.

Ventricular vulnerability during acute coronary occlusion

Ventricular fibrillation thresholds were determined by delivering gated trains of pulses to the ventricle, spanning the vulnerable period. The coupling interval of premature beats decreased and the number of subsequent repetitive responses increased with an increase in the intensity of gated stimuli. Although fibrillation thresholds were determined before and during coronary occlusion at an identical site unaffected by ischemia, they were consistently lower in the ventricle with an ischemic area. The decrease in fibrillation threshold resulted because the ventricle with an ischemic area could be fibrillated by premature beats with longer coupling intervals and fewer subsequent repetitive responses. It was concluded that reentrant activity and resulting fibrillation are more likely to be induced in the ventricle with an ischemic area because of the increased irregularity in the propagation of premature impulses. This irregularity is a result of a marked depression of excitability and conduction velocity in the ischemic area. The results emphasize the greater chance that premature ventricular beats will induce fibrillation in patients with myocardial infarction.