Ventricle (heart) | EPFL Graph Search

A ventricle is one of two large chambers toward the bottom of the heart that collect and expel blood towards the peripheral beds within the body and lungs. The blood pumped by a ventricle is supplied by an atrium, an adjacent chamber in the upper heart that is smaller than a ventricle. Interventricular means between the ventricles (for example the interventricular septum), while intraventricular means within one ventricle (for example an intraventricular block). In a four-chambered heart, such as that in humans, there are two ventricles that operate in a double circulatory system: the right ventricle pumps blood into the pulmonary circulation to the lungs, and the left ventricle pumps blood into the systemic circulation through the aorta. Structure Ventricles have thicker walls than atria and generate higher blood pressures. The physiological load on the ventricles requiring pumping of blood throughout the body and lungs is much greater than the pressure generated by the a

Coronary waves during valsalva maneuver measured during catheterization

Maria Cristina Rolandi

The mechanical interactions between heart contraction and perfusion of the heart are difficult to study in humans because of the restrictions in inducing changes in hemodynamic and cardiac mechanics parameters during catheterization. We hypothesize that the Valsalva maneuver can induce such alterations in the cardiac-coronary mechanical interaction and that these variations can be studied with the Wave Intensity Analysis. In order to interpret eventual changes in the wave intensity, a deep understanding of the effect of the Valsalva maneuver on the coronary circulation is needed. A particular attention has to be payed on the effect of the control of the microvascular resistance that is known to compensate for eventual alterations in the surrounding hemodynamic conditions when vessel tone is intact. In the catheterization laboratory, coronary pressure and flow velocity signals were recorded simultaneously by a new guidewire developed by Volcano Corporation. Aortic pressure, left ventricular pressure and ECG were acquired by the catheterization laboratory setup and recorded together with coronary hemodynamic signals. Left ventricular performance parameters were derived per beat from the noninvasive recording of the finger pressure using the Nexfin monitor developed by BMEYE B.V. In order to match the output data of coronary hemodynamic and left ventricular performance parameters, a dedicated program has been written in Delphi. An analysis of the per-beat data was performed in order to study the relative dependence of the parameters during the Valsalva maneuver. Pilot results of the Wave Intensity Analysis were obtained with an existing custom-made program also written in Delphi. Our study shows that the Valsalva maneuver caused a profound stress in the whole cardiovascular system. The well-known changes of the aortic pressure were transmitted also to the left ventricle and the coronary microcirculation. The data show that this stress caused a small but significant decrease in the flow velocity. As expected, the microvascular resistance varied with the same pattern as the coronary pressure trying to keep the flow constant. With respect to the decrease in stroke volume, cardiac output and contractility, the left ventricular performance was strongly compromised: pulse pressure generation and cardiac contraction were almost annulled. The decrease in systolic left ventricular pressure of almost 40% and the 2 fold increase in the end-diastolic left ventricular pressure confirm the decrease in the pumping action. Consequentially, the oxygen consumption of the heart decreased to 40% of the baseline level but only after an initial increase at the onset of the strain by 10%. The results also show that the timing of variation of the parameters was not the same. Especially the left ventricular end-diastolic pressure changed more rapidly than the perfusion pressure. Pilot results on Wave Intensity Analysis (WIA) show that the Valsalva maneuver gave rise to changes in the Wave Intensity pattern suggesting that the speed of the reflected waves has indeed been altered. Our results agree with previous studies that reveal a slight decrease in the flow velocity due to the Valsalva maneuver. Nevertheless, our results contradict the belief that ascribes the decrease in flow velocity to the decrease in oxygen consumption. We assume that the flow decrease is due to mechanical factors, especially the rise of left ventricular end-diastolic pressure. The results shown on WIA are pilot results and some work is still needed in this direction to obtain more information on the coronary-cardiac interaction. However, these results give confidence about the use of the Valsalva maneuver as an intervention affecting external parameters and thus they are useful in the study of coronary-cardiac interaction in humans.

2009

p-Aminobenzamidine attenuates cardiovascular dysfunctions in spontaneously hypertensive rats

Allancer Divino De Carvalho Nunes, Fabiana Pereira Da Costa Fraga, Nikolaos Stergiopulos

Aims:Diminazene aceturate, a putative ACE2 activator, is susceptible to cleavage resulting in the formation of paminobenzamidine (PAB). This study aimed to investigate the effects of PAB in addressing cardiovascular dysfunctions in spontaneously hypertensive rats (SHR). Main methods:Acute effects of PAB on mean arterial pressure (MAP), heart rate (HR), and aortic (AVC) and mesenteric vascular conductance (MVC) were evaluated in anesthetized SHR. Isolated aortic rings and the Langendorff technique were used to investigate the acute and chronic effects of PAB in the artery and heart. Chronic treatment with PAB (1 mg/kg, gavage) was carried out for 60 days. During this period, systolic blood pressure (SBP) and HR were measured by tail-cuff plethysmography. After the treatment, the left ventricle was collected for histology analyses, western blotting, and ACE2 activity. Key findings:Bolus infusion of PAB acutely reduced MAP and increased both AVC and MVC in SHR. Additionally, PAB induced coronary and aorta vasodilation in isolated organs from Wistar and SHR in an endothelialdependent manner. The chronic PAB treatment in SHR significantly attenuated the increase of SBP and improved the aorta vasorelaxation induced by acetylcholine and bradykinin-induced coronary vasodilation. In addition, chronic treatment with PAB attenuated the cardiomyocyte hypertrophy and extracellular matrix deposition in hearts from SHR. PAB did not alter the protein expression of the AT1, AT2, Mas, ACE, ACE2, or ACE2 activity. Significance:PAB induced beneficial effects on cardiovascular dysfunctions induced by hypertension, suggesting that this molecule could be used in the development of new drugs for the treatment of cardiovascular diseases.

PERGAMON-ELSEVIER SCIENCE LTD2022

Effects of a stiffened arterial tree on ventricular-arterial coupling in healthy and diseased hearts

David Jegger

In this thesis we study ventricular-arterial coupling in rodents under the influence of arterial stiffening and myocardial infarction (MI), combination of the two considered as a novel cardiovascular research model for diseased hearts pumping against an aged, stiffened arterial tree. The stiffened arterial tree yields isolated systolic hypertension and is obtained by administration of vitamin D and nicotine (VDN). The investigation cardiac performance and ventricular-arterial coupling using such a combined model (VDN/MI) is of particular relevance to cardiac research, as cardiac disease in elderly often takes place in presence of a atherosclerotic or stiff arterial tree.. The thesis consists of an Introduction, 4 scientific papers and a brief Conclusion. The Introduction is an overview of the epidemiology of heart failure, structure and functional changes that occur during MI and VDN, material and methods used in evaluating cardiac function invasively and non-invasively (using trans-thoracic echocardiography, TTE), methods for evaluating arterial function, and finally an overview of the interaction between the heart and vessels. Paper 1: This paper addresses the issue of the universality of the normalized time-varying elastance curve. It is demonstrated that the waveform of the normalized time-varying elastance curve (En(tn)) is qualitatively comparable between the control and MI hearts, however, when En(tn) is compared quantitatively between the two groups, statistical significance is found at the ejection phase and during diastole. These differences need to be taken into account when assessing cardiac contractility based on a generalized En(tn) in different animal models or in the human in different physiological or pathological states. Paper 2: Using trans-thoracic echo (TTE), we were able to follow serial changes of cardiac function post MI using two novel parameters, the myocardioal performance index (MPI) and its ratio to left ventricular fractional shortening (LVFS/MPI), both indices being monitor successfully and as efficiently as other classical TTE parameters. More so, LVFS/MPI visually expressed better the serial modifications in cardiac function. Both MPI and LVFS/MPI were correlated to the load-independent contractile parameter, PRSW, and to the preload parameter, LVEDP, being thus pertinent in following preload changes post MI. Finally, chamber remodeling post MI can successfully be followed due to the fact that ESV and EDV both correlate to MPI and LVFS/MPI. Paper 3: We studied hemodynamics, arterial function, cardiac function and ventricular-arterial coupling in a rat model of reduced arterial compliance. The results show that arterial stiffening after VDN treatment provokes important changes in vascular impedance and wave reflections, leading to isolated systolic hypertension and LV hypertrophy, Ventricular-arterial coupling was also altered. The effects are quantitatively similar to those of arterial stiffening with age. Paper 4: We studied changes in cardiac geometry, structure and function in response to MI in control and VDN-treated (stiffened aorta) rats. The combined VDN/MI model showed the largest compromise in cardiac structure and function and exhibited the strongest biochemical signs of heart failure as compared to all other groups. The addition of MI on top of a raised afterload, seems to have accelerated the progression of heart failure. Vascular alterations also reflected well a model of ageing and calcification. This combined pathology model of failing hearts in presence of a stiff arterial tree might be fruitful in better understanding the evolution of disease and may help improving or developing novel treatment therapies. The Conclusion chapter summarizes the findings of the thesis and brings into perspective their importance and future relevance into cardiovascular research models.

EPFL2006