Comparative cardiac anatomy of the reptilia. I. The chambers and septa of the varanid ventricle

Section: Effects Of Sr Inhibitionmentioning

confidence: 99%

The role of the sarcoplasmic reticulum in the generation of high heart rates and blood pressures in reptiles

Galli

Gesser

Taylor

et al. 2006

“…Webb et al, 1971;Webb, 1979). The vertical septum is large and separates the CA from the left side of the heart.…”

Section: Arterial and Intraventricular Pressures In Anaesthetised Snakesmentioning

confidence: 99%

“…Detailed anatomical descriptions of the ventricle of Python are, unfortunately, not available, but the structural similarities between varanid lizards and ophidians have been noted numerous times for more than a century (e.g. Jacquart, 1855;Robb, 1965;Webb et al, 1971Webb et al, , 1974Webb, 1979;van Mierop and Kutsche, 1985;Farrell et al, 1998). Thus, as in Varanus, the ventricular wall surrounding the CA of Python molurus is much thicker than the wall surrounding the CP and the CA is extensively trabeculated compared to the CP T.…”

Section: Arterial and Intraventricular Pressures In Anaesthetised Snakesmentioning

confidence: 99%

Ventricular haemodynamics inPython molurus: separation of pulmonary and systemic pressures

Wang

Altimiras

Klein

et al. 2003

SUMMARYVascular pressure separation by virtue of a two-chambered ventricle evolved independently in mammals and birds from a reptilian ancestor with a single ventricle, and allowed for high systemic perfusion pressure while protecting the lungs from oedema. Within non-crocodilian reptiles, ventricular pressure separation has only been observed in varanid lizards and has been regarded as a unique adaptation to an active predatory life style and high metabolic rate. The systemic and pulmonary sides of the ventricle in Python molurusare well separated by the muscular ridge, and a previous study using in situ perfusion of the heart revealed a remarkable flow separation and showed that the systemic side can sustain higher output pressures than the pulmonary side. Here we extend these observations by showing that systemic blood pressure Psys exceeded pulmonary pressure Ppul almost seven times (75.7±4.2 versus11.6±1.1 cm H2O). The large pressure difference between the systemic and pulmonary circulation persisted when Psys was altered by infusion of sodium nitroprusside or phenylephrine. Intraventricular pressures, measured in anaesthetised snakes, showed an overlap in the pressure profile between the pulmonary side of the ventricle (cavum pulmonale) and the pulmonary artery, while the higher pressure in the systemic side of the ventricle (cavum arteriosum) overlapped with the pressure in the right aortic arch. This verifies that the pressure differences originate within the ventricle, indicating that the large muscular ridge separates the ventricle during cardiac contraction.

“…Function of the python heart pulmonary chamber (cavum arteriosum and cavum pulmonale, respectively), with a third shallow chamber, the cavum venosum, situated between the other two. Three different septa are responsible for this division and while all three are found in the ventricle of all squamates and testudines, they are particularly conspicuous and well developed in the heart of pythons and varanid lizards (Greil, 1903;Acolat, 1943;Webb et al, 1971;Webb, 1979;Van Mierop and Kutsche, 1985;Farrell et al, 1998;Jensen et al, 2010). The vertical septum runs from the apex approximately threequarters of the length towards the base of the ventricle, and thereby completely partitions the caudal part of the ventricle into a right and left side.…”

Section: The Anatomy Of the Python Heartmentioning

confidence: 99%

“…Hopkinson and Pancoast, 1837;Jacquart, 1855;White, 1959;White, 1968;White, 1976;Webb et al, 1971;Farrell et al, 1998;Jensen et al, 2010). The heart consists of two separate atria, where the right atrium receives oxygen-poor blood carried by the systemic veins, while the left atrium receives oxygen-rich blood from the lungs.…”

Section: The Anatomy Of the Python Heartmentioning

confidence: 99%

How the python heart separates pulmonary and systemic blood pressures and blood flows

Jensen

Nielsen

Axelsson

et al. 2010

SummaryThe multiple convergent evolution of high systemic blood pressure among terrestrial vertebrates has always been accompanied by lowered pulmonary pressure. In mammals, birds and crocodilians, this cardiac separation of pressures relies on the complete division of the right and left ventricles by a complete ventricular septum. However, the anatomy of the ventricle of most reptiles does not allow for complete anatomical division, but the hearts of pythons and varanid lizards can produce high systemic blood pressure while keeping the pulmonary blood pressure low. It is also known that these two groups of reptiles are characterised by low magnitudes of cardiac shunts. Little, however, is known about the mechanisms that allow for this pressure separation. Here we provide a description of cardiac structures and intracardiac events that have been revealed by ultrasonic measurements and angioscopy. Echocardiography revealed that the atrioventricular valves descend deep into the ventricle during ventricular filling and thereby greatly reduce the communication between the systemic (cavum arteriosum) and pulmonary (cavum pulmonale) ventricular chambers during diastole. Angioscopy and echocardiography showed how the two incomplete septa, the muscular ridge and the bulbuslamelle -ventricular structures common to all squamates -contract against each other in systole and provide functional division of the anatomically subdivided ventricle. Washout shunts are inevitable in the subdivided snake ventricle, but we show that the site of shunting, the cavum venosum, is very small throughout the cardiac cycle. It is concluded that the python ventricle is incapable of the pronounced and variable shunts of other snakes, because of its architecture and valvular mechanics. Supplementary material available online at