Structure and function of the hearts of lizards and snakes

Jensen, Bjarke; Moorman, Antoon F.M.; Wang, Tobias

doi:10.1111/brv.12056

Cited by 100 publications

(192 citation statements)

References 247 publications

(368 reference statements)

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“…By contrast, mammals, birds and crocodilians have two anatomically distinct atria and ventricles, wherein the right atrium exclusively fills the right ventricle with oxygen-poor systemic venous blood, and the left atrium supplies the left ventricle with oxygenated blood returning from the lungs. Anatomically 'intermediate' are the hearts of amphibians and non-crocodilian reptiles (turtles, lizards and snakes), where oxygen-poor and oxygen-rich blood from the right and left atria converge within a single ventricle (Hicks, 2002;Jensen et al, 2014). Reptiles thus present an ideal paradigm to investigate the evolution of ventricular complexity coupled to the double circulatory system.…”

Section: Introductionmentioning

confidence: 99%

“…Blood returning from the lungs arrives at the cavum arteriosum from where it is pumped into the left (LAo) and right (RAo) aortic arches via the cavum venosum (Hicks, 2002). The cavum arteriosum and cavum venosum are partially separated from the cavum pulmonale by a myocardial structure known as the muscular ridge (MR) (van Mierop and Kutsche, 1985;Hicks, 2002;Jensen et al, 2014). The MR can effectively separate pulmonary and systemic venous blood within the ventricle, as illustrated by numerous classical studies demonstrating that blood emanating from the systemic arches and pulmonary artery differ substantially in their oxygen concentrations in turtles (Steggerda and Essex, 1957), snakes (White, 1959) and lizards (Foxon et al, 1956;White, 1959).…”

Section: Introductionmentioning

confidence: 99%

“…Despite the intraventricular compartmentalisation, the single ventricle presents the opportunity for the mixing of oxygen-rich and oxygen-poor blood (intracardiac shunting) (Hicks, 2002;Hicks and Wang, 2012;Jensen et al, 2014). Intracardiac shunting may be described as right to left (R-L), i.e.…”

Section: Introductionmentioning

confidence: 99%

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In situcardiac perfusion reveals interspecific variation of intraventricular flow separation in reptiles

Joyce

Axelsson

Altimiras

et al. 2016

Journal of Experimental Biology

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The ventricles of non-crocodilian reptiles are incompletely divided and provide an opportunity for mixing of oxygen-poor blood and oxygen-rich blood (intracardiac shunting). However, both cardiac morphology and in vivo shunting patterns exhibit considerable interspecific variation within reptiles. In the present study, we develop an in situ double-perfused heart approach to characterise the propensity and capacity for shunting in five reptile species: the turtle Trachemys scripta, the rock python Python sebae, the yellow anaconda Eunectes notaeus, the varanid lizard Varanus exanthematicus and the bearded dragon Pogona vitticeps. To simulate changes in vascular bed resistance, pulmonary and systemic afterloads were independently manipulated and changes in blood flow distribution amongst the central outflow tracts were monitored. As previously demonstrated in Burmese pythons, rock pythons and varanid lizards exhibited pronounced intraventricular flow separation. As pulmonary or systemic afterload was raised, flow in the respective circulation decreased. However, flow in the other circulation, where afterload was constant, remained stable. This correlates with the convergent evolution of intraventricular pressure separation and the large intraventricular muscular ridge, which compartmentalises the ventricle, in these species. Conversely, in the three other species, the pulmonary and systemic flows were strongly mutually dependent, such that the decrease in pulmonary flow in response to elevated pulmonary afterload resulted in redistribution of perfusate to the systemic circuit (and vice versa). Thus, in these species, the muscular ridge appeared labile and blood could readily transverse the intraventricular cava. We conclude that relatively minor structural differences between non-crocodilian reptiles result in the fundamental changes in cardiac function. Further, our study emphasises that functionally similar intracardiac flow separation evolved independently in lizards (varanids) and snakes ( pythons) from an ancestor endowed with the capacity for large intracardiac shunts.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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In situcardiac perfusion reveals interspecific variation of intraventricular flow separation in reptiles

Joyce

Axelsson

Altimiras

et al. 2016

Journal of Experimental Biology

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“…We prefer to address this structure as 'folding septum'. The presence and extent of the vertical septum (homologous to inlet septum) differs among reptiles, being virtually absent in turtles and most non-crocodilian reptiles, but more prominent in varanids and pythonidae [11]. In the python myocardial apical trabeculations traverse the ventricle to partly separate the cavum pulmonale from the cavum arteriosum.…”

Section: Septum Components In Reptilian Heartsmentioning

confidence: 99%

The Epicardium in Ventricular Septation During Evolution and Development

Poelmann

Jensen

Bartelings

et al. 2016

Etiology and Morphogenesis of Congenital Heart Disease

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The epicardium has several essential functions in development of cardiac architecture and differentiation of the myocardium in vertebrates. We uncovered a novel function of the epicardium in species with partial or complete ventricular septation including reptiles, birds and mammals. Most reptiles have a complex ventricle with three cava, partially separated by the horizontal and vertical septa. Crocodilians, birds and mammals, however, have completely separated left and right ventricles, a clear example of convergent evolution. We have investigated the mechanisms underlying epicardial involvement in septum formation in

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“…Therefore, ectothermic animals can be used to understand mechanisms controlling the electrical and contractile functions of the myocardium in response to changes in environmental temperature. (5)(6)(7) At present there are only a few studies of the electrophysiological processes that occur in a frog's heart ventricle under changes in ambient temperature. (8,9) It has been shown that when the body temperature in the frogs is decreased to 10ºС, then HR is diminished and the durations of QRS and ST-T complexes of ECG are lengthened.…”

Section: Introductionmentioning

confidence: 99%

Electrical and Contractile Properties of the Heart Ventricle in Response to Ambient Temperature Changes in Frog Rana temporaria

Kibler¹,

Nuzhny²,

Prosheva³

2017

IJBM

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The aim of the study was to investigate the dynamics of change in the intraventricular pressure, depolarization and repolarization processes on the ventricular epicardium (VE) in Rana temporaria in response to a rise in ambient temperature. By methods of catheterization and electrophysiological mapping the dynamics of the intraventricular pressure change, the processes of depolarization and repolarization on the epicardium of the heart ventricle in adult frogs in a temperature range from 10°C to 20°C were studied. We found that the rise in body temperature by 10°C led to increase of the maximal systolic ventricular pressure (MSVP), maximal value of the MSVP derivative and maximal rate of MSVP decline but to a decrease in dispersion of depolarization time and durations of activation-recovery intervals on the ventral and dorsal sides of VE. The role of the electrical inhomogeneity of the myocardium was shown to be a modulator performing fine adjustment to factors in the external environment of the organism.

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Structure and function of the hearts of lizards and snakes

Cited by 100 publications

References 247 publications

In situcardiac perfusion reveals interspecific variation of intraventricular flow separation in reptiles

In situcardiac perfusion reveals interspecific variation of intraventricular flow separation in reptiles

The Epicardium in Ventricular Septation During Evolution and Development

Electrical and Contractile Properties of the Heart Ventricle in Response to Ambient Temperature Changes in Frog Rana temporaria

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