Formation of the azygos vein / Formación de la vena ácigos

The aim of the present study was to determine the most common origin of the azygos vein. Thirty cadavers male and female, white and non-white adult individuals of different ages fixed in 10 percent formaldehyde and dissected. All cadavers had an undisclosed clinical death and were donated to the Universidade Estadual de Ciências da Saúde de Alagoa s, Brazil. Eleven different formations were found. The right subcostal vein was was only observed in 13 cases (43.33 percent); the azygos vein was formed by the confluence of the right subcostal and right ascending lumbar vein in three cases (10 percent); by the right subcostal vein with a contribution from the inferior vena cava (IVC) in three cases (10 percent); by the right subcostal with contribution from IVC and right ascending lumbar vein in three cases (10 percent); by the right and left subcostal veins in two cases (6.66 percent); by the right and left subcostal veins and contribution from the IVC in one case (3.33 percent); by the right and left subcostal veins and left accessory renal vein in one case (3.33 percent); by the left renal vein in one case (3.33 percent); by the right subcostal and left gonadal veins with contribution from the IVC in one case (3.33 percent); by the right subcostal and left renal veins in one case (3.33 percent); and composed by the continuation of the 11th posterior intercostal vein in one case (3.33 percent). Based on the results, the right subcostal vein was the only structure with a significant presence in the formation of the azygos vein.

El objetivo del estudio fue verificar cual es la disposición más frecuente del origen de la vena ácigos. Fueron disecados 30 cadáveres de individuos adultos, de ambos sexos, de diferentes grupos étnicos, fijados en formaldehído al 10 por ciento, donados a la Universidade Estadual de Ciencias da Saúde de Alagoas. Se encontraron 11 formaciones diferentes. En 13 casos (43,33 por ciento) se observó sólo la vena subcostal derecha; en 3 casos (10 por ciento) la vena ácigos estaba formada por la confluencia de las venas subcostal derecha y lumbar ascendente derecha; en 3 casos (10 por ciento) formado por las venas subcostal derecha y una contribución de la vena cava inferior VCI; en 3 casos (10 por ciento) por las venas subcostal derecha y contribución de la VCI y lumbar ascendente derecha; 2 casos (6,66 por ciento) por las venas subcostales derecha e izquierda; en 1 caso (3,33 por ciento) por las venas subcostal derecha, izquierda y contribución de la VCI; en 1 caso (3,33 por ciento) por las venas subcostal derecha e izquierda y renal accesoria izquierda; en 1 caso (3,33 por ciento) por la vena renal izquierda; en1 caso (3,33 por ciento) por las venas subcostal derecha, gonadal izquierda y contribución de la VCI; en 1 caso (3,33 por ciento) por las venas subcostal derecha y renal izquierda y en 1 caso (3,33 por ciento) por la continuación de la 11 vena intercostal posterior. Con base en los resultados podemos concluir que la vena subcostal derecha fue la única estructura con presencia significativa en la formación de la vena ácigos.

Epicardial neural ganglionated plexus of ovine heart: anatomic basis for experimental cardiac electrophysiology and nerve protective cardiac surgery.

BACKGROUND: Sheep are routinely used in experimental cardiac electrophysiology and surgery. OBJECTIVE: The purpose of this study was to (1) ascertain the topography and architecture of the ovine epicardial neural plexus (ENP), (2) determine the relationships of ENP with vagal and sympathetic cardiac nerves and ganglia, and (3) evaluate gross anatomic differences and similarities of ENP in humans, sheep, and other species. METHODS: Ovine ENP and extrinsic sympathetic and vagal nerves were stained histochemically for acetylcholinesterase in whole heart and/or thorax-dissected preparations from 23 newborn lambs, with subsequent examination by stereomicroscope. RESULTS: Intrinsic cardiac nerves extend from the venous part of the ovine heart hilum along the roots of the cranial (superior) caval and left azygos veins to both atria and ventricles via five epicardial routes: dorsal right atrial, middle dorsal, left dorsal, right ventral, and ventral left atrial nerve subplexuses. Intrinsic nerves proceeding from the arterial part of the heart hilum along the roots of the aorta and pulmonary trunk extend exclusively into the ventricles as the right and left coronary subplexuses. The dorsal right atrial, right ventral, and middle dorsal subplexuses receive the main extrinsic neural input from the right cervicothoracic and right thoracic sympathetic T(2) and T(3) ganglia as well as from the right vagal nerve. The left dorsal is supplied by sizeable extrinsic nerves from the left thoracic T(4)-T(6) sympathetic ganglia and the left vagal nerve. Sheep hearts contained an average of 769 +/- 52 epicardial ganglia. Cumulative areas of epicardial ganglia on the root of the cranial vena cava and on the wall of the coronary sinus were the largest of all regions (P <.05). CONCLUSION: Despite substantial interindividual variability in the morphology of ovine ENP, right-sided epicardial neural subplexuses supplying the sinoatrial and atrioventricular nodes are mostly concentrated at a fat pad between the right pulmonary veins and the cranial vena cava. This finding is in sharp contrast with a solely left lateral neural input to the human atrioventricular node, which extends mainly from the left dorsal and middle dorsal subplexuses. The abundance of epicardial ganglia distributed widely along the ovine ventricular nerves over respectable distances below the coronary groove implies a distinctive neural control of the ventricles in human and sheep hearts.