Pericardium modulates left and right ventricular stroke volumes to compensate for sudden changes in atrial volume

The pericardium may modulate acute compensatory changes in stroke volumes seen with sudden changes in cardiac volume, but such a mechanism has never been clearly demonstrated. In eight open-chest dogs, we measured left and right ventricular pressures, diameters, stroke volumes, and pericardial pressures during rapid (approximately 300 ms) systolic infusions or withdrawals of approximately 25 ml blood into and out of the left atrium and right atrium. Control beats, the infusion/withdrawal beat, and 4-10 subsequent beats were studied. With infusions, ipsilateral ventricular end-diastolic transmural pressure, diameter, and stroke volume increased. With the pericardium closed, there was a compensatory decrease in contralateral transmural pressure, diameter, and stroke volume, mediated by opposite changes in transmural end-diastolic pressures. The sum of the ipsilateral increase and contralateral decrease in stroke volume approximated the infused volume. Corresponding changes were seen with blood withdrawals. This direct ventricular interaction was diminished when pericardial pressure was <5 mmHg and absent when the pericardium was opened. Pericardial constraint appears essential for immediate biventricular compensatory responses to acute atrial volume changes.     

A comparative echocardiographic assessment of ventricular function in five species of sharks

A comparative echocardiographic study was carried out on five shark species that differ in heart morphology and in aspects of their behavior and natural history. The study contrasted the ventricular function in the highly active mako shark (heart type IV) and four other sharks (heart type III) that differ in activity levels (i.e. the sedentary horn and swell sharks vs. the moderately active blue and smooth-hound sharks). All five species exhibited biphasic ventricular filling characterized by an early (conduit) and late (atrial systole) phase. In the mako shark, early filling was dominant as indicated by a higher early flow peak velocity, a greater early:late velocity ratio, and a greater early velocity time integral. In contrast, the late filling phase was the more important filling agent in the other species. Indices of systolic function such as ventricular ejection fraction and ventricular fractional shortening also reflect a more efficient cardiac pumping capacity in mako shark relative to the other four sharks. The comparative echocardiographic assessment of in vivo ventricular function integrates structural and functional features with shark activity level to arrive at a new perspective blending the occurrence of biphasic filling with functional concepts based on heart morphological typology and changing views regarding the role of factors such as central filling pressure and pericardial pressure on end-diastolic ventricular volume.     

The pericardium and cardiac transmural filling pressure in the fetal sheep

Fetal pericardial physiology may be important for understanding normal and abnormal circulatory states. Right atrial, pericardial, thoracic, and amniotic fluid pressures were measured simultaneously in chronically-instrumented, near-term fetal sheep. Fourteen experiments were performed in 8 fetuses 4-21 days after surgery. The pressure gradient from the right atrium to the amniotic fluid and its components (transatrial, transpericardial and transthoracic pressures) were measured during control and with rapid infusion and withdrawal of blood. Under control conditions, right atrial minus amniotic pressure was 3.2 +/- 1.8 (SD) torr, right atrial minus pericardial pressure 2.5 +/- 1.7, pericardial minus thoracic pressure 0.6 +/- 0.7, and thoracic minus amniotic pressure 0.1 +/- 1.4. At right atrial pressures above control, pericardial minus thoracic pressure rose linearly with right atrial minus thoracic pressure. The average regression coefficient was 0.50 with an intercept of -1.5 torr. Administration of dextran-saline solution (121% of estimated blood volume) over 2-4 hs in 10 experiments did not reduce the pericardial minus thoracic to right atrial minus thoracic pressure relationship. Fluid added to the pericardium of three lambs progressively shifted the pericardial minus thoracic to right atrial minus thoracic pressure relationship up and to the left. The pericardial minus thoracic to right atrial minus thoracic pressure relationship was unaffected by fetal growth. Thus, the fetal pericardium affects cardiac filling pressures. The affect of the pericardium is increased markedly by pericardial liquid but is unchanged during growth.     

Influence of the pericardium on right and left ventricular filling in the dog

We compared the influence of the pericardium on left and right ventricular (LV, RV) filling by measuring LV and RV pressures and segment lengths (SL, LV free wall, and RV inflow and outflow tracts) in six open-chest, pentobarbital sodium-anesthetized dogs before and after pericardiectomy. End-diastolic pressure (EDP) was varied by partial caval occlusion and dextran infusion. At each site the ln EDP-SL relation was fitted by linear regression and characterized by its slope and 1-Torr EDP intercept. The slope and 1-Torr intercept of the LV ln EDP-SL relation changed variably after pericardiectomy, but in each dog a change occurred that shifted this relation downward. In contrast, the RV inflow tract slope invariably decreased significantly after pericardiectomy, whereas its intercept was unchanged in all but one dog. The RV outflow tract results were similar to the inflow tract but less consistent. By the use of the raw EDP-SL data points, we calculated that the absolute contribution of the pericardium to EDP (i.e., the effective pericardial surface pressure) was similar at the three sites. However, as EDP values increased the proportional contribution of the pericardium to right ventricular end-diastolic pressure (RVEDP) increased, whereas that to left ventricular end-diastolic pressure (LVEDP) remained relatively constant. As a result, at the higher EDP values tested, the pericardium was responsible for a larger proportion of RVEDP than LVEDP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cardiac function of the leopard shark,Triakis semifasciata

Summary The pressure difference between the cardinal sinus and the pericardium, and the transmural ventricular diastolic pressure at rest and during swimming in the leopard shark, Triakis semifasciata, was measured to characterize the mechanism of cardiac filling in chronically-instrumented fish and to evaluate cardiac responses to swimming. Echo-Doppler and radiographic imaging were also used to fully describe the cardiac cycle. Swimming induces an increase in preload as manifested by a large increment of cardinal sinus pressure (0.26/0.20 [systolic/diastolic] to 0.49/0.32 kPa) which always exceeds pericardial pressure. Increases in both mean ventricular diastolic transmural pressure (0.30–0.77 kPa) and cardinal sinus pressure during swimming suggest increased cardiac filling by vis a tergo as the mechanism for augmenting cardiac output. In contrast to mammals, the fluid-filled pericardial space of elasmobranchs is considerably larger and the pericardium itself does not move in concert with the heart throughout the cardiac cycle. Also, modest increases in heart rate drastically curtail the duration of diastole, which becomes much less than that of systole, a phenomenon not found in mammals. In the absence of tachycardia (<40 bpm), ventricular filling is characterized by a period of early rapid filling, and a late period of filling owing to atrial systole, separated by a period of diastasis. Ventricular filling in elasmobranchs is thus biphasic and is not solely dependent on atrial systole. Atrial diastole is characterized by three filling periods associated with atrial relaxation, ventricular ejection, and sinus venosus contraction. The estimated ventricular ejection fraction of Triakis (80%) exceeds that of the mammalian left ventricle.     

Cardiac performance in Turner's syndrome patients on growth hormone therapy.

OBJECTIVES: To investigate possible cardiac morphofunctional alterations observed in 26 Turner's syndrome (TS) patients on prolonged high-dose growth hormone (GH) therapy. STUDY DESIGN: We examined 26 TS subjects treated with rhGH (1 U/kg/week) for a mean period of 4.9 years (range 1-7.8) and 37 age-, weight- and height-matched healthy girls. Left ventricular volume, mass, systolic function, cardiac index, systemic vascular resistance and diastolic function were evaluated by two-dimensional and Doppler echocardiography. RESULTS: Heart rate and systolic blood pressure (BP) were higher in TS patients than in controls, while diastolic BP was lower. Left ventricular volumes, ejection fraction, mass index, M/V ratio and cardiac index did not differ significantly; systemic vascular resistance was slightly decreased. Left ventricular fractional shortening and mean velocity of circumferential shortening were slightly increased while end-systolic meridional stress was decreased in TS. Contractile state was normal in TS. Diastolic function assessment showed a shortening of isovolumetric relaxation and diastolic filling times with an increased atrial contribution and a normal pulmonary venous flow. CONCLUSION: Cardiac morphology in TS patients on GH therapy is similar to controls. The observed changes in left ventricular systolic and diastolic function should be interpreted as an adaptation to the higher heart rate and reduced peripheral vascular resistance induced by GH therapy.     

Exhaustion of the Frank-Starling mechanism in conscious dogs with heart failure induced by chronic coronary microembolization

The role of the Frank-Starling mechanism in the regulation of cardiac systolic function in the ischemic failing heart was examined in conscious dogs. Left ventricular (LV) dimension, pressure and systolic function were assessed using surgically implanted instrumentations and non-invasive echocardiogram. Heart failure was induced by daily intra-coronary injections of microspheres for 3-4 weeks via implanted coronary catheters. Chronic coronary embolization resulted in a progressive dilation of the left ventricle (12+/-3%), increase in LV end-diastolic pressure (118+/-19%), depression of LV dP/dt(max) (-19+/-4%), fractional shortening (-36+/-7%), and cardiac work (-60+/-9%), and development of heart failure, while the LV contractile response to dobutamine was depressed. A brief inferior vena caval occlusion in dogs with heart failure decreased LV preload to match the levels attained in their control state and caused a further reduction of LV dP/dt(max), fractional shortening, stroke work and cardiac work. Moreover, in response to acute volume loading, the change in the LV end-diastolic dimension-pressure (DeltaLVEDD-DeltaLVEDP) curve in the failing heart became steeper and shifted significantly to the left, while the increases in LV stroke work and cardiac work were blunted. Thus, our results suggest that the Frank-Starling mechanism is exhausted in heart failure and unable to further respond to increasing volume while it plays an important compensatory role in adaptation to LV dysfunction in heart failure.     

Prostaglandin E1 increases myocardial contractility in the conscious dog

The systemic and inotropic properties of prostaglandin E1 (PGE1) were investigated in 20 unanesthetized dogs. Pairs of ultrasonic dimension gauges and a micromanometer were implanted in the subendocardium and the apex of the left ventricle (LV), respectively. Seven to ten days later, increasing doses of PGE1 were infused into the left atrium. To appreciate the inotropic effects of the agent, the heart rate was maintained constant at 150 beats/min in a subgroup of dogs while preload was modified by bleeding or saline infusion over matched ranges of end-diastolic segmental length (EDL) during placebo and PGE1 infusions (0.25 microgram . kg-1 . min-1). LV function curves (delta L: systolic segmental shortening versus EDL) were plotted. Increasing doses of PGE1 above 0.031 microgram . kg-1 . min-1 brought a progressive decrease of left ventricular end-diastolic pressure, EDL, delta L, and peak left ventricular systolic pressure. The heart rate increased significantly at dosages from 0.063 to 0.125 microgram . kg-1 . min-1, and peak positive dP/dt after an initial increase fell at the dose of 0.5 microgram . kg-1 . min-1. The LV function curves invariably showed a shift to the left when PGE1 was administered; as the basal EDL was restored during PGE1 infusion, delta L reached a 33% increase (p less than 0.001). Thus, in addition to its potent vasodilating properties that are more prominent on preload than afterload, PGE1 increases myocardial contractility in the conscious dog.     

Passive pericardial constraint protects against stretch-induced vulnerability to atrial fibrillation in rabbits

Atrial fibrillation is more common in conditions with elevated atrial pressure and can be induced experimentally with acute increases in atrial pressure. We examined the effect of increased atrial pressure with and without pericardial constraint to better separate the effects of increased pressure and atrial stretch. In Langendorff-perfused rabbit hearts with intact pericardium, after ligating the pulmonary and caval veins, intra-atrial pressures were increased in a stepwise manner by adjusting the pulmonary outflow cannula. Rapid burst pacing was applied to induce atrial fibrillation at increasing intra-atrial pressures from 0 to 24 cmH(2)O. The atrial refractory period was recorded at each pressure using a single extra stimulus. The protocol was repeated after the pericardium was removed. When the pericardium was intact, atrial stretch was limited by passive constraint, and sustained atrial fibrillation could not be induced despite atrial pressures in excess of 20 cmH(2)O. In contrast, when the pericardium was removed, atrial fibrillation could be reliably induced when atrial pressure exceeded 15 cmH(2)O. This suggests that the electrophysiological effects of acute atrial volume loading rely on atrial stretch rather than increased atrial pressure alone.     

The pericardium facilitates pressure work in the eel heart

An in siru perfused eel (Anguilla dieffenbachü) Gray 1842) heart was used to investigate the role of the pericardium in cardiac function. Hearts with intact pericardia were compared with hearts in which the pericardia were either punctured or opened completely. Cardiac function was assessed at low and high adrenaline levels by determining: maximum cardiac output; maximum sustainable output pressure; power output under maximal filling and output pressures; and maximum power output. Puncturing a small hole in the pericardium equalizing ambient and intrapericardial pressures had little effect on cardiac function and performance. Opening the pericardium, thereby fully exposing the chambers of the heart, severely limited the heart's ability to do pressure work. This effect was reversed at high adrenaline concentrations. Flow related work, and maximum power output levels were maintained after opening the pericardium.     

Opening the pericardium during pulmonary artery constriction improves cardiac function.

During acute pulmonary hypertension, both the pericardium and the right ventricle (RV) constrain left ventricular (LV) filling; therefore, pericardiotomy should improve LV function. LV, RV, and pericardial pressures and RV and LV dimensions and LV stroke volume (SV) were measured in six anesthetized dogs. The pericardium was closed, the chest was left open, and the lungs were held away from the heart. Data were collected at baseline, during pulmonary artery constriction (PAC), and after pericardiotomy with PAC maintained. PAC decreased SV by one-half. RV diameter increased, and septum-to-LV free wall diameter and LV area (our index of LV end-diastolic volume) decreased. Compared with during PAC, pericardiotomy increased LV area and SV increased 35%. LV and RV compliance (pressure-dimension relations) and LV contractility (stroke work-LV area relations) were unchanged. Although series interaction accounts for much of the decreased cardiac output during acute pulmonary hypertension, pericardial constraint and leftward septal shift are also important. Pericardiotomy can improve LV function in the absence of other sources of external constraint to LV filling.     

Determinants of LV diastolic function during atrial fibrillation: beat-to-beat analysis in acute dog experiments

Left ventricular (LV) diastolic function during atrial fibrillation (AF) remains poorly understood due to the complex interaction of factors and beat-to-beat variability. The purpose of the present study was to elucidate the physiological determinants of beat-to-beat changes in LV diastolic function during AF. The RR intervals preceding a given cardiac beat were measured from the right ventricular electrogram in 12 healthy open-chest mongrel dogs during AF. Doppler echocardiography and LV pressure and volume beat-to-beat analyses were performed. The LV filling time (FT) and early diastolic mitral inflow velocity-time integral (E(vti)) were measured using the pulsed Doppler method. The LV end-diastolic volume (EDV), peak systolic LV pressure (LVP), minimum value of the first derivative of LV pressure curve (dP/dt(min)), and the time constant of LV pressure decay (tau) were evaluated with the use of a conductance catheter for 100 consecutive cardiac cycles. Beat-to-beat analysis revealed a cascade of important causal relations. LV-FT showed a significant positive linear relationship with E(vti) (r = 0.87). Importantly, there was a significant positive linear relationship between the RR interval and LV-EDV in the same cardiac beat (r = 0.53). Consequently, there was a positive linear relationship between LV-EDV and subsequent peak systolic LVP (r = 0.82). Furthermore, there were significant positive linear and negative curvilinear relationships between peak systolic LVP and dP/dt(min) (r = 0.95) and tau (r = -0.85), respectively, in the same cardiac beat. In addition, there was a significant negative curvilinear relationship between dP/dt(min) and tau (r = -0.86). We have concluded that the determinants of LV diastolic function in individual beats during AF depend strongly on the peak systolic LVP. This suggests that the major benefit of slower ventricular rate appears related to lengthening of LV filling interval, promoting subsequent higher peak systolic LVP and greater LV relaxation.     

Effect of synchronous increase in intrathoracic pressure on cardiac performance during acute endotoxemia

In the anesthetized closed-chest canine model of Gram-negative endotoxemia (n = 10), we tested the hypothesis that the effect of cardiac cycle-specific intrathoracic pressure pulses delivered by a heart rate-(HR) synchronized high-frequency jet ventilator (sync HFJV) on systolic ventricular performance is dependent on the level of preload. To control for HFJV frequency, hemodynamic responses were also measured at fixed frequency within 15% of HR (async HFJV). Biventricular stroke volumes (SV) were measured by electromagnetic flow probes. Measurements were made before (baseline) and 30 min after infusion of 1 mg/kg Escherichia coli endotoxin (serotype 055:B5) and then after 2 mg/kg propranolol at both low (less than 10 mmHg) left ventricular filling pressure (LVFP) and high (greater than 10 mmHg) LVFP. Ventricular function curves, aortic pressure-flow (P-Q) relationships, and venous return (VR) curves were analyzed. We found that endotoxin did not alter VR curves but shifted the aortic P-Q curves to the left with pressure on the x-axis (P less than 0.05). Volume loading increased SV (P less than 0.01) because of a rightward shift of the VR curve. No specific differences occurred with either sync or async HFJV during endotoxin, presumably because of preserved VR and shifted aortic P-Q. The lack of cardiac cycle-specific effects of ITP appears to be due to the selective endotoxin-induced changes in peripheral vasomotor tone that counterbalance any depressed myocardial contractility.     

Excessive sympathetic nervous system activity decreases myocardial contractility

The objective of this study was to determine whether myocardial contractility is depressed by intense activation of the sympathetic nervous system. A massive sympathetic discharge was produced by injecting veratrine or sodium citrate into the cisterna magna of anesthetized rabbits (n = 10). Two and one-half hr later, the hearts were isolated and their left ventricular (LV) performance evaluated and compared with the LV performance of hearts isolated from control animals (n = 10). LV performance was evaluated from steady-state peak isovolumic systolic and end-diastolic pressures that were generated at various end-diastolic volumes (LV function curves). The relationship between peak LV systolic pressure (or the average peak developed LV wall stress) and LV end-diastolic volume was rotated downward (P less than 0.01) in the hearts removed from rabbits treated with veratrine or citrate. The LV end-diastolic pressure or LV end-diastolic wall stress of these hearts was not different from control at any end-diastolic volume. The diminished ability of the experimental hearts to develop systolic pressure or wall stress suggests that intense sympathetic activation depressed contractility. Severely damaged myofibers, located largely in the subendocardium, were found in these hearts. Furthermore, the depressed contractility was not related to pulmonary edema since only 2 of 10 rabbits developed edema.     

A 2D FE model of the heart demonstrates the role of the pericardium in ventricular deformation

During pulmonary artery constriction (PAC), an experimental model of acute right ventricular (RV) pressure overload, the interventricular septum flattens and inverts. Finite element (FE) analysis has shown that the septum is subject to axial compression and bending when so deformed. This study examines the effects of acute PAC on the left ventricular (LV) free wall and the role the pericardium may play in these effects. In eight open-chest anesthetized dogs, LV, RV, aortic, and pericardial pressures were recorded under control conditions and with PAC. Model dimensions were derived from two-dimensional echocardiography minor-axis images of the heart. At control (pericardium closed), FE analysis showed that the septum was concave to the LV; stresses in the LV, RV, and septum were low; and the pericardium was subject to circumferential tension. With PAC, RV end-diastolic pressure exceeded LV pressure and the septum inverted. Compressive stresses developed circumferentially in the septum out to the RV insertion points, forming an arch-like pattern. Sharp bending occurred near the insertion points, accompanied by flattening of the LV free wall. With the pericardium open, the deformations and stresses were different. The RV became much larger, especially with PAC. With PAC, the arch-like circumferential stresses still developed in the septum, but their magnitudes were reduced, compared with the pericardium-closed case. There was no free wall inversion and flattening was less. From these FE results, the pericardium has a significant influence on the structural behavior of the septum and the LV and RV free walls. Furthermore, the deformation of the heart is dependent on whether the pericardium is open or closed.     

Echocardiographic parameters discriminating myocardial infarction with pulmonary congestion from myocardial infarction without congestion in the mouse.

Our aim was to establish parameters describing systolic and diastolic function in mice after myocardial infarction (MI) that distinguish MI with pulmonary congestion from MI without congestion. Echocardiography, left ventricular (LV) catheterization, and infarct size measurements were performed on days 3, 5, 7, and 14 after ligation of the left coronary artery in C57BL/6 mice. Sham-operated mice were used as controls (Sham). MI mice with lung weight normalized to tibial length >125% of the average in the corresponding Sham group were considered to have pulmonary congestion (MIchf). MI mice with a smaller increase were called MI nonfailing (MInf). An infarct >40% of total LV circumference measured in two-dimensional long axis distinguished MIchf from MInf on both an average and an individual basis. Mean maximum rate of rise of LV pressure, LV fractional shortening, and posterior wall shortening velocity were significantly lower in MIchf compared with Sham at all time points and to MInf at 7 days. The diastolic parameters mitral flow deceleration velocity, LV end-diastolic pressure, and maximum rate of decline in LV pressure (LVdP/dtmin) discriminated the MIchf groups from Sham at all time points. Mitral flow deceleration velocity and LVdP/dtmin separated MIchf from MInf at 7 days. In addition to distinguishing all the groups on an average basis, left atrial diameter distinguished all MIchf animals from Sham and MInf. In conclusion, significantly increased left atrial diameter and infarct size >40% of total LV circumference may serve as major criteria for heart failure with pulmonary congestion after MI in mice.     

Juxtacardiac pressure in closed-chest dogs

We studied pressure (Ppc)-volume (Vpc) relationships of the pericardial sac by inserting air into it at constant end-diastolic heart volume in six dogs. The lungs were inflated by positive alveolar pressure while pleural pressure was monitored using the esophageal balloon technique. Ppc-Vpc relationships were measured at transpulmonary pressures (PL) of 30, 10, and 5 cmH2O in each of three states: closed chest, open chest with lung separation, and open chest with the pericardium dissected free of its mediastinal attachment. Ppc in the closed-chest condition was more positive than Ppc in the open chest with lung separation, with increase of Vpc and PL, which suggests that the lungs compress the pericardium. Ppc in the open-chest condition with lung separation was also more positive than Ppc in the pericardium after it was dissected free, which suggests that mediastinal attachment compresses the pericardium. It is suggested that lungs in the closed-chest condition as well as mediastinal attachment reduce the heart expansion by a similar magnitude.     

Role of impaired myocardial relaxation in the production of elevated left ventricular filling pressure

Although present in many patients with heart failure and a normal ejection fraction, the role of isolated impairments in active myocardial relaxation in the genesis of elevated filling pressures is not well characterized. Because of difficulties in determining the effect of prolonged myocardial relaxation in vivo, we used a cardiovascular simulated computer model. The effect of myocardial relaxation, as assessed by tau (exponential time constant of relaxation), on pulmonary vein pressure (PVP) and left ventricular end-diastolic pressure (LVEDP) was investigated over a wide range of tau values (20-100 ms) and heart rate (60-140 beats/min) while keeping end-diastolic volume constant. Cardiac output was recorded over a wide range of tau and heart rate while keeping PVP constant. The effect of systolic intervals was investigated by changing time to end systole at the same heart rate. At a heart rate of 60 beats/min, increases in tau from a baseline to extreme value of 100 ms cause only a minor increase in PVP of 3 mmHg. In contrast, at 120 beats/min, the same increase in tau increases PVP by 23 mmHg. An increase in filling pressures at high heart rates was attributable to incomplete relaxation. The PVP-LVEDP gradient was not constant and increased with increasing tau and heart rate. Prolonged systolic intervals augmented the effects of tau on PVP. Impaired myocardial relaxation is an important determinant of PVP and cardiac output only during rapid heart rate and especially when combined with prolonged systolic intervals. These findings clarify the role of myocardial relaxation in the pathogenesis of elevated filling pressures characteristic of heart failure.     

Differential impact of short periods of rapid atrial pacing on left and right atrial mechanical function

Current techniques to describe atrial function are limited by their load dependency and hence do not accurately reflect intrinsic mechanical properties. To assess the impact of atrial fibrillation on atrial function, combined pressure-volume relationships (PVR) measured by conductance catheters were used to evaluate the right (RA) and left (LA) atrium in 12 isoflurane-anesthetized pigs. Biatrial PVR were recorded over a wide range of volumes during transient caval occlusion at baseline sinus rhythm (SR), after onset of rapid atrial pacing (RAP), after 1 h of RAP, after conversion to SR, and after 1 h of recovery. Cardiac output decreased by 16% (P = 0.008) with onset of RAP. Mean LA and RA pressures increased by 21 and 40% (P < 0.001), respectively, and remained elevated during the entire recovery period. RA reservoir function increased from 51 to 58% and significantly dropped to 43% after resumption of SR (P = 0.017). Immediately after RAP, a right shift of LA end-systolic PVR-intercept for end-systolic volume required to generate an atrial end-systolic pressure of 10 mmHg (24.4 ± 4.9 to 28.1 ± 5.2 ml, P = 0.005) indicated impaired contractility compared with baseline. Active LA emptying fraction dropped from 17.6 ± 7.5 to 11.7 ± 3.7% (P < 0.001), LA stroke volume and ΔP/Δt(max)/P declined by 22% (P = 0.038 and 0.026, respectively), while there was only a trend to impaired RA systolic function. Stiffness quantified by the ratio of pressure to volume at end-diastole was increased immediately after RAP only in the RA (P = 0.020), but end-diastolic PVR shifted rightward in both atria (P = 0.011 LA, P = 0.045 RA). These data suggest that even short periods of RAP have a differential impact on RA and LA function, which was sustained for 1 h after conversion to SR.     

Dynamic effects of positive-pressure ventilation on canine left ventricular pressure-volume relations.

Positive-pressure ventilation (PPV) may affect left ventricular (LV) performance by altering both LV diastolic compliance and pericardial pressure (Ppc). We measured the effect of PPV on LV intraluminal pressure, Ppc, LV volume, and LV cross-sectional area in 17 acute anesthetized dogs. To account for changes in lung volume independent of changes in Ppc and differences in contractility, measures were made during both open- and closed-chest conditions, during closed chest with and without chest wall binding, and after propranolol-induced acute ventricular failure (AVF). Apneic end-systolic pressure-volume relations (ESPVR) were generated by inferior vena caval occlusions. With the open chest, PPV had no effects. With the chest closed, PPV inspiration decreased LV end-diastolic volume (EDV) along its diastolic compliance curve and decreased end-systolic volume (ESV) such that the end-systolic pressure-volume domain was shifted to a point left of the LV ESPVR, even when referenced to Ppc. The decrease in EDV was greater in control than in AVF conditions, whereas the shift of the ESV to the left of the ESPVR was greater with AVF than in control conditions. We conclude that the hemodynamic effects of PPV inspiration are due primarily to changes in intrathoracic pressure and that the inspiration-induced decreases of LV EDV reflect direct effects of intrathoracic pressure on LV filling. The decreases in LV ESV exceed the amount explained solely by a reduction in LV ejection pressure.