Cardiac cycle

About: Cardiac cycle is a research topic. Over the lifetime, 3290 publications have been published within this topic receiving 96159 citations.

Instantaneous pressure-volume relationship of the canine right ventricle.

Abstract: SUMMARY The instantaneous isovolumic and ejecting pressure-volume relationship of the right ventricle was studied in 11 cross-circulated, isolated canine hearts to characterize the right ventricular contractile state. Accurate measurement of volume was achieved by the use of a water-filled, thin latex balloon in the right ventricle connected to a special volume loading and transducing chamber. Pressure was measured with a miniature pressure transducer mounted within the balloon. Wide variations in loading conditions were achieved by changing the volume of air above the volumetric chamber. The pressure and volume data were collected from multiple beats under a constant contractile state in the same mode of contraction while the left ventricle was vented to air. Linear regression analysis applied to each of the isochronal pressure-volume data sets at 20-msec intervals from the onset of contraction showed a highly linear correlation between the pressure and the volume. Both the slope and the volume intercept of the regression lines changed with time throughout the cardiac cycle. The maximal slope of the regression line (E,,,,) averaged 2.50 ± 0.49 mm Hg/ml (mean ± SD) for ejecting beats and 2.68 ± 0.55 mm Hg/ml for isovolumic beats. Epinephrine infusions of 12.5 fig/min and 25.0 /ig/min increased E^u by 31% and 82%, respectively (P < 0.005). We conclude that: (1) The instantaneous pressure-volume relationships of the right ventricle in the isovolumic and ejecting modes can be regarded as linear, at least within the physiological range; however, these two modes of contraction did not yield an identical relationship. (2) The slope of these pressure-volume relationship curves changes with a change in the contractile state. Ore Res 44: 309-315, 1979 IT IS WELL KNOWN that there are major anatomical and physiological differences between the right and left ventricles. Compared with the left ventricle, the right ventricle has a greater regional variation in wall thickness and a more complex geometric shape. The developed pressure in systole is much smaller, and intraventricular pressure falls considerably while ejection proceeds. Much recent research has been focussed on left ventricular function, yet there is little quantitative information concerning the right ventricle, particularly with respect to the question of how to characterize contractile state and pumping ability. Those indices of contractile state used in characterizing left ventricular function have not been quantified in and shown to be valid for the right ventricle. Since there are major differences between left and right ventricles, we investigated whether right ventricular contractile state could be described in a similar fashion as left ventricular contractile state. In this study we determined the time-varying ratio of instantaneous pressure to volume, which has been shown to be sensitive to changes in left ventricular contractile state and nearly independent of

Analysis of left ventricular function from multiple gated acquisition cardiac blood pool imaging. Comparison to contrast angiography.

Abstract: Global ventricular function was evaluated by both multiple gated cardiac blood pool scans (MUGA) and contrast ventriculograms in a group of 17 patients with suspected coronary artery disease. The contrast ventriculograms were analyzed frame by frame to generate a volume versus time curve for each patient, while the tracer data were analyzed by two methods: 1) the standard method, in which the left ventricle is identified on the end-diastolic frame and the background corrected activity under the region of interest obtained from the entire cardiac cycle, and displayed as a time versus activity curve; and 2) by a semi-automatic method in which the computer applies a threshold detection program to define the ventricular borders, and activity in the chamber at each point in the cardiac cycle is defined after background correction. The tracer data in each patient were analyzed independently by four observers. The tracer data correlated with the contrast data on a point by point basis r = 0.87 for the standard method, and 0.93 for the semi-automatic technique. An F test of variance revealed the semi-automatic method superior to the standard approach (P less than 0.05).

Reference ranges for fetal venous and atrioventricular blood flow parameters

Abstract: This cross-sectional study establishes reference ranges with gestation for Doppler parameters of fetal venous and atrioventricular blood flow. Color flow Doppler was used to examine 143 normal singleton pregnancies at 20-40 weeks' gestation. Flow velocity waveforms were recorded from the ductus venosus, right hepatic vein and inferior vena cava. The waveforms are triphasic, reflecting ventricular systole, early diastole and atrial contraction. Peak velocities for these parameters were measured with pulsed Doppler and a new index, the peak velocity index for veins (PVIV), was calculated. Similarly, time-averaged maximum velocities for the whole cardiac cycle were measured and the pulsatility index for veins (PIV) was calculated. Flow velocity waveforms were also recorded at the level of the atrioventricular valves and the ratios of peak velocities at early diastolic filling (E) and atrial contraction (A) were calculated. Regression analysis was used to define the association of each measured and calculated Doppler parameter with gestational age. Blood flow velocities in the fetal veins and velocities and E/A ratios across the atrioventricular valves increased significantly with gestation, whereas PVIV and PIV decreased. Blood flow velocities were highest in the ductus venosus and lowest in the right hepatic vein, and PVIV and PIV were highest in the hepatic vein and lowest in the ductus venosus. In the ductus venosus, there was always forward flow throughout the heart cycle, whereas in the inferior vena cava and hepatic vein during atrial contraction, flow was away from or towards the heart or there was no flow. Pulsatility of flow velocity waveforms in the venous system is the consequence of changes in pressure difference between the venous system and the heart during the heart cycle. The finding that PVIV and PIV decrease with gestation is consistent with decreasing cardiac afterload and maturation of diastolic ventricular function.

Reverse Remodeling From Cardiomyoplasty in Human Heart Failure External Constraint Versus Active Assist

Abstract: Background Cardiomyoplasty (CM) is a novel surgical therapy for dilated cardiomyopathy. In this procedure, the latissimus dorsi muscle is wrapped around the heart and chronically paced synchronously with ventricular systole. While studies have found symptomatic improvement from this therapy, the mechanisms by which CM confers benefit remain uncertain. This study sought to better define these mechanisms by means of serial pressure-volume relation analysis. Methods and Results Serial pressure-volume studies were performed by the conductance catheter method in three patients (total to date) with dilated cardiomyopathy (New York Heart Association class III) who underwent CM. Data were measured at baseline (before surgery) and at 6 and 12 months after CM. Chronic left ventricular (LV) systolic and diastolic changes induced by CM were evaluated with the stimulator in its stable pacing mode (every other beat) and after temporarily suspending pacing. CM-stimulated beats were compared with pacing-off beats to evaluate active systolic assist effects of CM. In each patient, CM resulted in a chronic lowering of cardiac end-diastolic volume and an increased ejection fraction. Most notably, the end-systolic pressure-volume relation shifted leftward, consistent with reversal of chronic chamber remodeling. In contrast, the diastolic pressure-volume relation was minimally altered, and the loops shifted down along the same baseline relation. These marked chronic changes in LV function measurable with CM stimulation off contrasted to only minor acute effects observed when the muscle wrap was activated. This suggests that the benefit of CM derived less from active systolic assist than from remodeling, perhaps because of an external elastic constraint. Conclusions These data, while limited to a small number of patients, suggest that CM can reverse remodeling of the dilated failing heart. While systolic squeezing assist effects of CM may play a role in some patients, our study found that this was not required to achieve substantial benefits from the procedure. We speculate that CM may act more passively, like an elastic girdle around the heart, to help reverse chamber remodeling.