Proximal Atrioventricular Bundle, Atrioventricular Node, and Distal Atrioventricular Bundle Are Distinct Anatomic Structures With Unique Histological Characteristics and Innervation

Racker, Darlene K.; Kadish, Alan H.

doi:10.1161/01.cir.101.9.1049

Cited by 36 publications

(23 citation statements)

References 23 publications

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“…TranumJensen and Bojsen-Moller (72) showed by electron microscopy of thin sections made from the stained tissue that the SA node extensions are different from the adjacent myocardium in displaying small branching myocytes containing glycogen deposits and grouped in clusters. These attributes are also similar to those for the proximal AV bundle, AV node, and distal AV bundle (56,58). The fact that the atrionodal bundles are associated with epicardium and terminate in the atrial-interventricular septal groove likely accounts for failure to detect connections of the extensions with the proximal AV bundle, the specialized AV ring tissues of Tranum-Jensen and BojsenMoller (72).…”

Section: Atrial Approaches To the Av Node: Atrionodal And Proximal Avmentioning

confidence: 64%

“…Elastic fibers are restricted to the walls of large blood vessels. The myocytes are ϳ6 m in diameter, possess uniform cross striations, and are joined by intercalated disks that appear to be more prominent and more numerous compared with those in the proximal AV bundle, AV node, and distal AV bundle (58). No cell-to-cell connections were found with the ordinary atrial myocardium.…”

Section: Specialized Conduction Tissues Of the Av Junction Regionmentioning

confidence: 98%

“…3 B-D and 6, B and D, inset in Ref. 58). The collagen encasement of fascicles comprising the tissues most probably function as insulation, and that of the central fibrous location of the AV node and distal AV bundle as protection from compression, as adult-like ECG patterns are recorded in the bent single primordial heart tube before the appearance of collagen or the central fibrous body by Patten (47).…”

Section: Physiological Significance For Transmissionmentioning

confidence: 99%

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The AV junction region of the heart: a comprehensive study correlating gross anatomy and direct three-dimensional analysis. Part II. Morphology and cytoarchitecture

Racker

2004

American Journal of Physiology-Heart and Circulatory Physiology

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Racker, Darlene K. The AV junction region of the heart: a comprehensive study correlating gross anatomy and direct threedimensional analysis. Part II. Morphology and cytoarchitecture. Am J Physiol Heart Circ Physiol 286: H1853-H1871, 2004; 10.1152/ ajpheart.01205.2003.-This "Part II morphology and cytoarchitecture" study is based on paraffin-embedded specimens in which the extracellular and intracellular matrix are preserved; single parallel, perpendicular, and transverse serial sections of the entire atrioventricular (AV) junction region (AVJR) and their correlation with photographs of the tissue blocks. As in Part I, the same major new findings are: 1) a coronary sinus fossa is formed by the superoposterior right medial atria wall (MAW), the left atrium, and the coronary sinus roof; 2) the posterior MAW forms two myocardial bridges and is isolated from the sinus venarum by the floor of the inferior vena cava; 3) the tendon of Todaro terminates in the superior lip of the coronary sinus ostium; 4) only ordinary myocardium contacts the annulus fibrosus, and there is little to no collagen separating its myofibers and tissues; 5) the ventricular septum shoulder is humped shaped, completely overlaid by annular myocardium, and joined by struts of papillary muscle; 6) the membranous septum joining the ventricular septum shoulder to the crista supraventricularis forms part of the aortic valve sinus walls; and 7) myocardium of the atrionodal bundles is aggregated into numerous small fascicles encased by collagen and is outside of the MAW as are the other specialized tissues. The proximal AV bundle and medial atrionodal bundle are aligned to the medial leg of Koch's triangle and the tendon of Todaro. These data show, therefore, that the AVJR contains two overlapping atrial circuits. In the MAW, acivation of the posterior region is delayed because of the two myocardial bridges. Puncture of the AVJR can produce communication with an extracardiac space, posteriorly and medially, and with the aorta, anteriorly.

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Section: Atrial Approaches To the Av Node: Atrionodal And Proximal Avmentioning

confidence: 64%

Section: Specialized Conduction Tissues Of the Av Junction Regionmentioning

confidence: 98%

Section: Physiological Significance For Transmissionmentioning

confidence: 99%

See 1 more Smart Citation

The AV junction region of the heart: a comprehensive study correlating gross anatomy and direct three-dimensional analysis. Part II. Morphology and cytoarchitecture

Racker

2004

American Journal of Physiology-Heart and Circulatory Physiology

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“…1 Although arguments still continue about their number 15 and whether they constitute functional or anatomic substrates, 14,16,17 the dual pathways are commonly considered to be atrionodal entities. The penetrating bundle is usually considered a cable-like structure surrounded by the CFB [12][13][14] and distanced from the supraventricular reentrant loop by an interposed common final pathway.…”

Section: Dual Inputs Into the His Bundlementioning

confidence: 99%

His Electrogram Alternans Reveal Dual-Wavefront Inputs Into and Longitudinal Dissociation Within the Bundle of His

et al. 2001

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Background-His electrogram (HE) amplitude and morphology changes were observed in our previous studies during transition from "fast" to "slow" atrioventricular nodal (AVN) conduction. This phenomenon and its significance for the dual-AVN electrophysiology are not well recognized and have not been studied. Methods and Results-Experiments were performed on 17 healthy rabbit atrial-AVN preparations during standard programmed electrical pacing. HEs were mapped along the His bundle with roving surface electrodes, along with recording of cellular action potentials (APs). HEs recorded from the superior margin of the His bundle were of greater amplitude during basic beats and decreased substantially, by 42Ϯ19% (PϽ0.01), when premature A 1 A 2 shortened to 178Ϯ20 ms. In contrast, the HEs from the inferior margin increased dramatically, 2.9Ϯ1.7 times (PϽ0.01), during short A 1 A 2 and remained high until AVN block occurred. In addition, during long A 1 A 2 , the superior HEs consistently preceded the inferior by 1.9Ϯ0.7 ms. In contrast, at short A 1 A 2 , the superior HEs occurred 2.7Ϯ0.8 ms after the inferior. Cellular AP recordings demonstrated clearly the presence of and the transition between early (fast) and late (slow) excitation wavefronts that accompanied HE alternans. Conclusions-The

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“…In the AV node, so-called "dead-end" pathways could play this role by shunting a fraction of electrotonic current. 16,17 Furthermore, in parts of the AV node consisting of myocardial fascicles interspersed with collagen, 18,19 branchings of these fascicles could form sites of source-to-load mismatch. In the myocardium, structural complexities can develop during chronic infarction: the infarct border zone consists of interconnected islands and strands of surviving myocytes intermingled with scar tissue and is known to support very slow conduction.…”

mentioning

confidence: 99%

Mechanistic Insights Into Very Slow Conduction in Branching Cardiac Tissue

Kučera

Rudy²

2001

Circulation Research

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Abstract-It is known that branching strands of cardiac tissue can form a substrate for very slow conduction. The branches slow conduction by acting as current loads drawing depolarizing current from the main strand ("pull" effect). It has been suggested that, upon depolarization of the branches, they become current sources reinjecting current back into the strand, thus enhancing propagation safety ("push" effect). It was the aim of this study to verify this hypothesis and to assess the contribution of the push effect to propagation velocity and safety. Conduction was investigated in strands of Luo-Rudy dynamic model cells that branch from either a single branch point or from multiple successive branch points. In single-branching strands, blocking the push effect by not allowing current to flow retrogradely from the branches into the strand did not significantly increase the branching-induced local propagation delay. However, in multiple branching strands, blocking the push effect resulted in a significant slowing of overall conduction velocity or even in conduction failure. Furthermore, for certain slow velocities, the safety factor for propagation was higher when slow conduction was caused by branching tissue geometry than by reduced excitability without branching. Therefore, these results confirm the proposed "pull and push" mechanism of slow, but nevertheless robust, conduction in branching structures. Slow conduction based on this mechanism could occur in the atrioventricular node, where multiple branching is structurally present. It could also support reentrant excitation in diseased myocardium where the substrate is structurally complex.

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Proximal Atrioventricular Bundle, Atrioventricular Node, and Distal Atrioventricular Bundle Are Distinct Anatomic Structures With Unique Histological Characteristics and Innervation

Cited by 36 publications

References 23 publications

The AV junction region of the heart: a comprehensive study correlating gross anatomy and direct three-dimensional analysis. Part II. Morphology and cytoarchitecture

The AV junction region of the heart: a comprehensive study correlating gross anatomy and direct three-dimensional analysis. Part II. Morphology and cytoarchitecture

His Electrogram Alternans Reveal Dual-Wavefront Inputs Into and Longitudinal Dissociation Within the Bundle of His

Mechanistic Insights Into Very Slow Conduction in Branching Cardiac Tissue

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