Objective. This study documents and traces the evolution of triple rhythm (Waltz) linking the great veins, corresponding systemic or pulmonary venous sinuses and pectinated right or left atrium in frog, turtle, snake and human hearts. Alternating rhythm (duet) between systemic and pulmonary veins has also been documented in these hearts. Material Studied. The hearts of six dead hammer-head sharks were examined with the naked eye. Air-breathing, fresh-water fish (three Channa striata and three Indian catfish) were anaesthetised with ketamine and their pharynx insufflated with oxygen. Six frogs, three turtles, and two snakes were anaesthetised, intubated and ventilated. Contractions of the exposed hearts of these animals were correlated with their electrocardiograms using superimposed videos. The human heart was observed carefully during surgery through median sternotomy or anterolateral thoracotomy by visual inspection especially during instillation of or recovery from cardioplegia. Digital videos were taken and studied in slow motion replay later. Observations. In the air-breathing fish, Channa striata and Indian catfish and presumably the shark, the cardinal veins and thin walled sinus venosus do not contract. In the frog, turtle, and snake there is sequential contraction of the systemic veins, systemic venous sinus and pectinated right atrium. Likewise, there is waltz on the arterial side. There is a duet between systemic and pulmonary veins, contractions of the former preceding the latter in the frog, turtle and snake. The observations are similar in the human heart except that the inferior vena cava does not contract. Conclusions. There is sequential contraction of the superior vena cava, the systemic venous sinus and the pectinated part of the right atrium in the human heart. Likewise, there is a waltz linking the terminal pulmonary veins, pulmonary venous sinus and pectinated part of the left atrium in the human heart. This waltz or triple rhythm, as well as a duet between the systemic and pulmonary veins are seen in frog, turtle and snake. The duet is also observable in the human heart, during recovery from cardioplegia. It is likely that the waltz and duet are conducted by a neurogenic mechanism. Clinical Implications. The understanding, preservation and restoration of the mechanism sustaining supraventricular waltz and duet is relevant to surgical and interventional procedures for control of atrial arrhythmia, Fontan circulation, technique for cardiac transplantation and planning atriotomies.
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