Improved cardiac filling facilitates the postprandial elevation of stroke volume in Python regius

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In animals with functional division of blood systemic and pulmonary pressures, such as mammals, birds, crocodilians and a few non-crocodilian reptiles, the vessel walls of systemic and pulmonary arteries are exquisitely adapted to endure different pressures during the cardiac cycle, systemic arteries being stronger and stiffer than pulmonary arteries. However, the typical non-crocodilian reptile heart possesses an undivided ventricle that provides similar systolic blood pressure to both circuits. This raises the question whether in these species the systemic and pulmonary mechanical vascular properties are similar. Snakes also display large organ plasticity and increased cardiac output in response to digestion, and we speculate how the vascular circuit would respond to this further stress. We addressed these questions by testing the mechanical vascular properties of the dorsal aorta and the right pulmonary artery of fasted and fed yellow anacondas, , a snake without functional ventricular separation that also exhibits large metabolic and cardiovascular responses to digestion. Similar to previous studies, the dorsal aorta was thicker, stronger, stiffer and more elastic than the pulmonary artery. However, unlike any other species studied so far, the vascular distensibility (i.e. the relative volume change given a pressure change) was similar for the two circuits. Most striking, the pulmonary artery elasticity (i.e. its capacity to resume its original form after being stretched) and distensibility increased during digestion, which suggests that this circuit is remodeled to accommodate the larger stroke volume and enhance the Windkessel effect, thus providing a more constant blood perfusion during digestion.

Section: Introductionmentioning

confidence: 99%

Analysis of vascular mechanical properties from the yellow anaconda indicates increased elasticity and distensibility of the pulmonary artery during digestion

Filogonio

Wang

Danielsen

2018

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“…For reptiles, feeding elicits marked elevations in oxygen consumption rate ( _ V O 2 ) that last for several hours (Secor and Diamond, 1999;Hicks et al, 2000;Wang et al, 2001a;Overgaard et al, 2002a;Hicks and Bennett, 2004;Enok et al, 2013;Wearing et al, 2016). This postprandial increase in oxygen demand necessitates increased _ Q to sufficiently supply tissues with oxygen Secor et al, 2000;Wang et al, 2001a;Hicks and Bennett, 2004;Andersen et al, 2005;Secor and White, 2010;Enok et al, 2012Enok et al, , 2013Enok et al, , 2016Wearing et al, 2016). In terrestrial vertebrates, _ Q can be modulated by changes in heart rate ( f H ) and/or V S .…”

Section: Introductionmentioning

confidence: 99%

Embryonic hypoxia programmes postprandial cardiovascular function in adult common snapping turtles (Chelydra serpentina)

Wearing

Conner

Nelson

et al. 2017

Reduced oxygen availability (hypoxia) is a potent stressor during embryonic development, altering the trajectory of trait maturation and organismal phenotype. We previously documented that chronic embryonic hypoxia has a lasting impact on the metabolic response to feeding in juvenile snapping turtles (Chelydra serpentina). Turtles exposed to hypoxia as embryos [10% O 2 (H10)] exhibited an earlier and increased peak postprandial oxygen consumption rate, compared with control turtles [21% O 2 (N21)]. In the current study, we measured central blood flow patterns to determine whether the elevated postprandial metabolic response in H10 turtles is linked to lasting impacts on convective transport. Five years after hatching, turtles were instrumented to quantify systemic ( _ Q sys ) and pulmonary ( _ Q pul ) blood flows and heart rate ( f H ) before and after a ∼5% body mass meal. In adult N21 and H10 turtles, f H was increased significantly by feeding. Although total stroke volume (V S,tot ) remained at fasted values, this tachycardia contributed to an elevation in total cardiac output ( _ Q tot ). However, there was a postprandial reduction in a net left-right (L-R) shunt in N21 snapping turtles only. Relative to N21 turtles, H10 animals exhibited higher _ Q sys due to increased blood flow through the right systemic outflow vessels of the heart. This effect of hypoxic embryonic development, reducing a net L-R cardiac shunt, may support the increased postprandial metabolic rate we previously reported in H10 turtles, and is further demonstration of adult reptile cardiovascular physiology being programmed by embryonic hypoxia.

“…Sandblom et al, 2005;Skals et al, 2005Skals et al, , 2006Enok et al, 2016). By mobilizing blood from the veins, preload pressure may be maintained, or even increased, despite the increased heart rate during activity (Sandblom et al, 2005;Skals et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

Autoregulation of cardiac output is overcome by adrenergic stimulation in the anaconda heart

Joyce

Axelsson

Wang

2016

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Most vertebrates increase cardiac output during activity by elevating heart rate with relatively stable stroke volume. However, several studies have demonstrated 'intrinsic autoregulation' of cardiac output where artificially increased heart rate is associated with decreased stroke volume, leaving cardiac output unchanged. We explored the capacity of noradrenaline to overcome autoregulation in the anaconda heart. Electrically pacing in situ perfused hearts from the intrinsic heart rate to the maximum attainable resulted in a proportional decrease in stroke volume. However, noradrenaline, which increased heart rate to the same frequency as pacing, maintained stroke volume and thus increased cardiac output. In atrial and ventricular preparations, noradrenaline significantly increased the force of contraction and contraction kinetics. Thus, the increased contractility associated with adrenergic stimulation ameliorates filling limitations at high heart rates. Although heart rate appears the primary regulated variable during activity, this may only be achieved with compensatory amendments in myocardial contractility provided by adrenergic stimulation.