Effect of positive end-expiratory pressure on left ventricular mechanics in patients with hypoxemic respiratory failure

Evaluation of Left Ventricular Volumes and Ejection Fraction from Gated Myocardial Perfusion SPECT Processed with "Myovation Evolution": Comparison of Three Automated Software Packages using Cardiac Magnetic Resonance as Reference

BACKGROUND

The development of resolution recovery (RR) algorithms has made it possible to preserve the good quality of cardiac images despite a reduced number of counts during study acquisition.

OBJECTIVE

Our purpose was to evaluate the performance of three different software packages in the quantification of left ventricular (LV) end-diastolic volume (EDV), end-systolic volume (ESV), and ejection fraction (EF) from gated perfusion SPECT, applying a resolution recovery (RR) algorithm (GE Myovation Evolution), with respect to cardiac MRI (cMRI) as a gold standard.

METHODS

We retrospectively enrolled 21 patients, with suspected or known coronary heart disease. Images at rest were reconstructed by filtered back projection (FBP) and by an iterative protocol with the RR algorithm. EDV, ESV, and LVEF were automatically computed employing Quantitative Gated SPECT (QGS), Myometrix (MX), and Corridor 4DM (4DM). Any difference in EDV, ESV, and LVEF calculation between cMRI and the three packages (with FBP and iterative reconstruction with RR) was tested using Wilcoxon or paired t-test, with the assumption of normality assessed using the Shapiro-Wilk test. Agreement between imaging reconstruction algorithms and between gated-SPECT software packages and cMRI was studied with Pearson's (r) or Spearman's (R) correlation coefficients and Lin's concordance correlation coefficient (LCC).

RESULTS

Intra-software evaluation always revealed very strong correlation coefficients (R, r ≥ 0.8) and excellent LCC coefficients (LCC > 0.95), except for the LCC coefficient between MX-FBP and MX-RR in EDV evaluation, nevertheless considered very good (LCC = 0.94). EDV and ESV had significantly lower value when calculated with the RR algorithm with respect to FBP reconstruction in QGS and MX. LVEF estimation did not show significant differences for QGS-FBP, QGS-RR, MX, and 4DM-RR with respect to cMRI.

CONCLUSION

All reconstruction methods systematically underestimate EDV and ESV, with higher underestimation applying only the RR. No significant differences were observed between 4DM - RR and 4DM-FBP, for each parameter, when the 4DM package was used.

Analytic Reviews : Hemodynamic Management of the Adult Respiratory Distress Syndrome

Hemodynamic management is an essential aspect of the care of patients with adult respiratory distress syn drome (ARDS). On the basis of current knowledge, our proposed goals of management are to maximize pe ripheral oxygen delivery while attempting to minimize further lung damage or dysfunction. The major patho physiologic abnormalities of ARDS are an increased lung vascular permeability, right-to-left intrapulmonary shunting, and pulmonary vascular resistance. These abnormalities must be understood to select the proper therapy. Although all patients with ARDS share these abnormalities, they differ in their associated clinical conditions and underlying cardiovascular status. Be cause each ARDS patient may respond differently to therapy, hemodynamic management must be selected empirically with the goal of therapy as a guide. We have considered available therapeutic options including posi tive end-expiratory pressure, volume depletion, volume expansion, vasopressors, and vasodilators. In the future hemodynamic management of patients with ARDS will likely change as better methods of patient assessment and treatment are developed.

In silico study of the haemodynamic effects induced by mechanical ventilation and biventricular pacemaker

In silico modeling of the cardiovascular system (CVS) can help both in understanding pharmacological or pathophysiological process and in providing information which could not be obtained by means of traditional clinical research methods due to practical or ethical reasons. In this work the numerical CVS was used to study the effect of interaction between mechanical ventilation and biventricular pacemaker by haemodynamic and energetic point of view. Starting from literature data on patients with intra and/or inter-ventricular activation time delay and treated using biventricular pacemaker, we used in silico simulator to analyse the effects induced by mechanical ventilatory assistance (MVA). After reproducing baseline and CRT conditions, the MVA was simulated changing the mean intrathoracic pressure value. Results show that simultaneous application of CRT and MVA yields a reduction of cardiac output, left ventricular end-diastolic and end-systolic volume when positive mean intrathoracic pressure is applied. In the same conditions, when MVA is applied, left ventricular ejection fraction, mean left (right) atrial and pulmonary arterial pressure increase.

Gated myocardial perfusion SPECT underestimates left ventricular volumes and shows high variability compared to cardiac magnetic resonance imaging -- a comparison of four different commercial automated software packages

Background

We sought to compare quantification of left ventricular volumes and ejection fraction by different gated myocardial perfusion SPECT (MPS) programs with each other and to magnetic resonance (MR) imaging.

Methods

N = 100 patients with known or suspected coronary artery disease were examined at rest with ^{99 m}Tc-tetrofosmin gated MPS and cardiac MR imaging. Left ventricular end-diastolic volume (EDV), end-systolic volume (ESV), stroke volume (SV) and ejection fraction (EF) were obtained by analysing gated MPS data with four different programs: Quantitative Gated SPECT (QGS), GE MyoMetrix, Emory Cardiac Toolbox (ECTb) and Exini heart.

Results

All programs showed a mean bias compared to MR imaging of approximately -30% for EDV (-22 to -34%, p < 0.001 for all), ESV (-12 to -37%, p < 0.001 for ECTb, p < 0.05 for Exini, p = ns for QGS and MyoMetrix) and SV (-21 to -41%, p < 0.001 for all). Mean bias ± 2 SD for EF (% of EF) was -9 ± 27% (p < 0.01), 6 ± 29% (p = ns), 15 ± 27% (p < 0.001) and 0 ± 28% (p = ns) for QGS, ECTb, MyoMetrix, and Exini, respectively.

Conclusions

Gated MPS, systematically underestimates left ventricular volumes by approximately 30% and shows a high variability, especially for ESV. For EF, accuracy was better, with a mean bias between -15 and 6% of EF. It may be of value to take this into consideration when determining absolute values of LV volumes and EF in a clinical setting.

Changes in mean airway pressure during HFOV influences cardiac output in neonates and infants

BACKGROUND

Changes in mean airway pressure affect cardiac output during conventional positive pressure ventilation. The effect of high-frequency oscillation ventilation (HFOV) on cardiac output is less studied.

METHODS

A prospective study in a university hospital pediatric intensive care unit. Fourteen patients aged <1 year and weighing <10 kg who were on HFOV were included. All patients had been on HFOV for >12 h and were considered to be in a stable condition. In the study group (n = 9) the mean proximal airway pressure (Paw) was increased and decreased by +5 and -3 cmH2O, respectively, from baseline in each patient. Measurements were made at each level including baseline settings between each change. In a control group (n = 5) no changes in ventilatory parameters were made. Cardiac output was assessed with echocardiography and the Doppler technique at each level of Paw and at similar intervals in the control group.

RESULTS

Cardiac output changed significantly when Paw was changed in the study group (P = 0.02), with the greatest change at the highest Paw at -11% (range: -19 to -9) compared with baseline. We found no significant changes over time in the control group.

CONCLUSION

This study shows that CO is affected by changes in mean airway pressure during HFOV in concordance with the known effects of mean airway pressure during conventional positive pressure ventilation. The mean changes are smaller than expected compared with earlier studies of conventional mechanical ventilation. Further studies are needed to better understand these relationships.

An improved in vivo rat model for the study of mechanical ventilatory support effects on organs distal to the lung

OBJECTIVE

To study the influence of different mechanical ventilatory support strategies on organs distal to the lung, we developed an in vivo rat model, in which the effects of different tidal volume values can be studied while maintaining other indexes.

DESIGN

Prospective, randomized animal laboratory investigation.

SETTING

University laboratory of Ospedale Maggiore di Milano-Instituto di Ricovero e Cura a Carattere Scientifico.

SUBJECTS

Anesthetized, paralyzed, and mechanically ventilated male Sprague-Dawley rats.

INTERVENTIONS

Two groups of seven rats each were randomized to receive tidal volumes of either 25% or 75% of inspiratory capacity (IC), calculated from a preliminary estimation of total lung capacity. Ventilation strategies for the two groups were as follows: a) 25% IC, 9.9+/-0.8 mL/kg; frequency, 59+/-4 beats/min; positive end-expiratory pressure, 3.6+/-0.8 cm H2O; and peak inspiratory airway pressure (Paw), 13.2+/-2 cm H20; and b) 75% IC, 29.8+/-2.9; frequency, 23+/-13; positive end-expiratory pressure, 0; peak inspiratory Paw, 29.0+/-3.

MEASUREMENTS AND MAIN RESULTS

Mean arterial pressure (invasively monitored) remained well above adequate perfusion pressure values throughout, and no significant difference was seen between the two groups. PaO2, pHa, and PaCO2 values were compared after 60 mins of ventilation and again, no significant difference was seen between the two groups (PaO2, 269+/-25 and 260+/-55 torr; pHa, 7.432+/-0.09 and 7.415+/-0.03; PaCO2, 35.4+/-8 and 32.5+/-2 torr, for the 25% IC and 75% IC groups, respectively). Mean Paws were not different (6.4+/-0.8 cm H2O in the 25% IC groups, and 6.1+/-1.2 in the 75% IC groups, respectively). At the end of the experiment, animals were killed and the liver and kidney isolated, fixed in 4% formalin, cut, and stained for optic microscopy. Kidneys from rats ventilated with 75% IC showed increased Bowman's space with collapse of the glomerular capillaries. This occurred in a greater percentage of rats ventilated with 75% IC (0.67+/-0.2 vs. 0.29+/-0.2, 75% IC vs. 25% IC, respectively; p < .05). Perivascular edema was also present in rats ventilated with 75% IC (p < .05). Morphometric determinations of the empty zones (index of edema) demonstrated a trend toward differences between 75% IC livers and 25% IC (0.14+/-0.05 vs. 0.11+/-0.02, respectively).

CONCLUSION

We conclude that it is possible to study the effects of mechanical ventilatory support on organs distal to the lung by means of an in vivo rat model.

Positive pressure inspiration differentially affects right and left ventricular outputs in postoperative cardiac surgery patients

PURPOSE

The purpose of this study was to determine the dynamic changes in right ventricular (RV) and left ventricular (LV) output during positive airway pressure inspiratory hold maneuvers so as to characterize the interaction of processes in creating steady-state cardiac output during positive pressure ventilation.

MATERIALS AND METHODS

We examined the disparity of RV and LV outputs at 5 seconds (early) and 20 seconds (late) into a 24-second inspiratory hold maneuver in 14 subjects in the intensive care unit immediately following coronary artery bypass surgery. RV output was measured by the thermodilution technique, whereas LV output was measured by the arterial pulse contour method. RV and LV volumes were also measured by thermal and radionuclide ejection fraction techniques, respectively.

RESULTS

As P(aw) was progressively increased from 0 to 20 cm H2O in sequential inspiratory hold maneuvers, both RV and LV outputs changed differently both at 5 seconds and 20 seconds into the inspiratory hold maneuvers. When expressed as change in cardiac output (L/min) for every cm H2O P(aw) increase relative to end-expiratory values, RV output increased at 5 seconds (0.05 +/- 0.15 L/min) then decreased at 20 seconds (-0.08 +/- 0.21, P < .05). LV output decreased slightly at 5 seconds (-0.14 +/- 0.22) and did not change from this minimal depressed level at 20 seconds (P < .05). Changes in RV and LV output were paralleled by changes in RV and LV end-diastolic volumes, respectively.

CONCLUSION

Positive pressure inspiration induces time-dependent changes in central hemodynamics, which are dissimilar between RV and LV function. Initially, inspiration increases RV output but decreases LV output, such that intrathoracic blood volume increases. However, sustained inspiratory pressures induce proportionally similar decreases in both RV and LV outputs. Thus, the hemodynamic effects of positive pressure ventilation will depend on the degree of lung inflation, the inspiratory time, and when measurements are made within the ventilatory cycle. These data also suggest that positive pressure ventilation with up to 20 cm H2) P(aw) does not significantly impair ventricular performance in humans.

Positive end-expiratory pressure-induced hemodynamic changes are reflected in the arterial pressure waveform

OBJECTIVE

To examine whether the hemodynamic changes due to mechanical ventilation with positive end-expiratory pressure (PEEP) can be assessed by the respiratory-induced variations in the arterial pressure waveform during normovolemia and experimental acute ventricular failure.

DESIGN

Prospective, controlled experimental study.

SETTING

Institutional experimental laboratory.

SUBJECTS

Adult mongrel dogs.

INTERVENTIONS

Experimental acute ventricular failure was induced by the infusion of pentobarbital (a cardiodepressant) and methoxamine (a vasoconstrictor), combined with volume loading. Both the control and acute ventricular failure groups were subjected to ventilation with incremental levels of PEEP up to 20 cm H2O.

MEASUREMENTS AND MAIN RESULTS

Cardiac function was evaluated by cardiac output and left and right ventricular change in pressure over time (dP/dt) measurements. Arterial pressure waveform analysis was performed by measuring the systolic pressure variation, which is the difference between the maximal and minimal systolic blood pressure values during one mechanical breath. The components of the systolic pressure variation, namely, dUp and dDown, which are the increase and decrease in the systolic pressure during the mechanical breath relative to the systolic pressure during apnea, were also measured at each PEEP level. PEEP caused significant reduction of cardiac output in normovolemic dogs, and was associated with significant increases in systolic pressure variation and dDown. Acute ventricular failure decreased the variations in the systolic pressure and caused the dDown component to disappear. The application of PEEP did not affect cardiac output in dogs with acute ventricular failure, nor did it change systolic pressure variation and the dDown.

CONCLUSIONS

Analysis of arterial pressure waveforms during mechanical ventilation reflected the decrease in cardiac output in dogs with normal cardiac function subjected to incremental PEEP. In dogs with acute ventricular failure in which PEEP did not affect cardiac output, the systolic pressure variation was similarly unaffected by PEEP. In the absence of cardiac output measurement during mechanical ventilation with PEEP, the analysis of the respiratory variations in the arterial pressure waveform may be useful in assessing changes in cardiac output.

Risks and hazards of mechanical ventilation: a collective review of published literature

A collective, analytic review was undertaken of all available published scientific papers that reported data about risks, hazards, adverse effects, or complications from augmentation of blood gas exchange by means of intensive closed system positive pressure mechanical ventilation. On the basis of the data collected, the adverse effects of intensive positive pressure mechanical ventilation were classified into the following groups: oxygen toxicity; adverse effects from excessive ventilatory pressures, volumes, and flow rates; adverse effects from tracheal intubation; dangers from adjuvant drugs; stress-related sequelae; altered enzyme and hormone systems; nutritional problems; and psychologic trauma. A bibliography pertaining to each group of adverse effects has been prepared. In addition, the reported incidence of adverse effects resulting from intensive mechanical ventilation in patients in clinical intensive care is shown. Clinical and laboratory observations of patients who receive intensive positive pressure mechanical ventilation in respiratory intensive care units have yielded some data, and findings from experimental studies in normal volunteers and laboratory animals have also been collected and reviewed. Tables, charts, and graphs that summarize the pertinent findings are presented and discussed. The following conclusions are drawn from critical evaluation of the collected data: (1) Closed system positive pressure mechanical ventilation applied at mild to moderate levels of intensity is a safe and effective method for augmenting deficient blood gas exchange in most patients who are in acute respiratory failure. (2) On the other hand, intensive levels of mechanical ventilator support or inappropriate methods of applying mechanical ventilation may be accompanied by a variety of risks, hazards, adverse effects, and complications that may further injure the failing lungs or may add significantly to the morbidity and mortality rates of patients in whom it is applied. (3) Because of the unfavorable risk/benefit ratio of intensive positive pressure mechanical ventilation, physicians should consider the use of alternative methods that are now available for augmenting blood gas exchange in patients in acute respiratory failure who are not adequately treated by safe (mild to moderate) levels of positive pressure mechanical ventilation instead of electing to increase the intensity of positive pressure mechanical ventilation to more dangerous (intensive) levels.

Transesophageal pulsed-Doppler echocardiographic evaluation of transmitral and pulmonary venous flow during ventilation with positive end-expiratory pressure

During mechanical ventilation with high levels of positive end-expiratory pressure (PEEP) several hemodynamic changes occur, the mechanism of which has been the subject of various previous studies. The effects of increasing levels of PEEP during mechanical ventilation were measured on left atrial and left ventricular filling dynamics, as assessed by pulmonary venous and transmitral flow velocities, respectively. Using transesophageal echocardiography in 12 patients, Doppler flow velocities of pulmonary venous and transmitral flow were studied at baseline (0 cmH2O PEEP) and at 5, 10, 15, and 20 cm H2O with 10-minute intervals, and once more after removal of PEEP. In 2 of the 12 patients, PEEP could not be increased beyond 15 cmH2O, because cardiac index fell below 2.0 L/min/m2. Pulmonary venous flow velocity and velocity time integral during systole significantly decreased from 48 +/- 7 cm/s and 10.3 +/- 2.2 cm at baseline to 35 +/- 6 cm/s and 5.7 +/- 2.5 cm at 20 cmH2O PEEP, respectively (P < 0.01). In contrast, early and late diastolic velocities and velocity time integrals did not change. In regard to transmitral flow, both early and late diastolic velocities significantly decreased from 51 +/- 7 cm/s and 50 +/- 9 cm/s at baseline to 38 +/- 7 cm/s at 20 cmH2O PEEP, respectively (P < 0.01). Early and late diastolic velocity time integrals decreased from 6.1 +/- 1.8 cm and 4.7 +/- 1.0 cm to 4.5 +/- 1.0 cm (NS) and 3.4 +/- 0.7 cm (P < 0.05), respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of peep-ventilation on cardiac function in closed chest pigs

OBJECTIVE

Does ventilation with positive end-expiratory pressure (PEEP) depress myocardial contractility?

DESIGN

Ten piglets were anaesthetized and prepared for the measurement of cardiac output (SV) and right (MRAPtm) and left (MLAPtm) mean transmural atrial pressure, the latter serving as indices of preload. 500 ml of autologous blood was re-transfused during intermittent positive pressure ventilation without PEEP (IPPV) and continuous positive pressure ventilation with 15 cm H2O PEEP (CPPV).

MEASUREMENTS AND RESULTS

Right and left ventricular function curves were drawn by plotting MRAPtm and MLAPtm respectively versus the corresponding strokevolumes before and after re-transfusion. Similar inclinations were obtained during IPPV and CPPV on either side of the heart.

CONCLUSIONS

Although the ventricular function curves during IPPV and CPPV covered partially different preload levels, the results suggest that CPPV i.e. PEEP does not affect myocardial contractility.

Physiologic effects of positive end-expiratory pressure in patients with chronic obstructive pulmonary disease during acute ventilatory failure and controlled mechanical ventilation

Dynamic hyperinflation and intrinsic positive end-expiratory pressure (PEEPi) are observed in patients with chronic obstructive pulmonary disease (COPD) and flow limitation. Several reports suggest that PEEP levels approaching PEEPi reduce inspiratory load due to PEEPi, without further hyperinflation. Hence PEEP should not increase intrathoracic pressure or affect hemodynamics and gas exchange. To verify this hypothesis, the effects of PEEP (0 to 15 cm H2O) on respiratory mechanics, hemodynamics, and gas exchange were studied in nine COPD patients during controlled mechanical ventilation. PEEP levels approaching PEEPi (9.8 +/- 0.5 cm H2O) did not affect the expiratory flow/volume relationship, confirming the presence of flow limitation. PEEP levels of 5 and 10 cm H2O did not change lung volume and PEEPi in the respiratory system (PEEPtot,rs) and chest wall (PEEPtot,cw) or affect hemodynamics and gas exchange. When applied PEEP overcame PEEPi, changes in lung volume and the expiratory flow/volume relationship were observed. PEEPtot,rs and PEEPtot,cw also increased. Under these circumstances, PEEP increased static elastance in both the respiratory system and the chest wall, reducing cardiac index and affecting hemodynamics and gas exchange. Our data show that in mechanically ventilated COPD patients with PEEPi due to flow limitation, PEEP levels exceeding the 85% of PEEPi (Pcrit) caused further hyperinflation and compromised hemodynamics and gas exchange.

Normal pulmonary venous flow characteristics as assessed by transesophageal pulsed Doppler echocardiography

Twenty-seven subjects without apparent cardiac abnormalities underwent transesophageal echocardiography to evaluate normal Doppler characteristics of pulmonary venous flow. In particular, the effects of normal respiration and straining during the Valsalva maneuver were analyzed. Pulmonary venous flow during systole consisted of one forward flow wave in 15 cases (56%) and of two forward flow waves in 12 cases (44%). In all instances one forward flow wave was seen during early diastole and in 23 subjects (85%) a retrograde wave related to atrial contraction was present. Maximal velocity during systole was 57 +/- 13 cm/sec (mean +/- SD), during early diastole was 58 +/- 19 cm/sec, and during late diastole was 16 +/- 9 cm/sec. Velocity time integral during systole was significantly higher than during early diastole (11.8 +/- 4.9 vs 9.5 +/- 3.9 cm, p < 0.05), while velocity time integral during late diastole was 1.1 +/- 0.7 cm. During normal inspiration both early diastolic velocity and velocity time integral significantly decreased from 59 +/- 15 to 54 +/- 15 cm/sec (p < 0.01) and from 9.5 +/- 3.9 to 8.5 +/- 4.2 cm (p < 0.05), respectively. During normal expiration, systolic and early diastolic velocity time integral significantly increased, from 11.0 +/- 4.1 to 11.8 +/- 4.5 cm (p < 0.001) and from 9.5 +/- 3.9 to 10.1 +/- 4.3 cm (p < 0.05), respectively. Although statistically significant, the differences were small and do not seem of clinical importance. Straining during the Valsalva maneuver, however, obviously decreased pulmonary venous flow velocities. Systolic and early diastolic velocity decreased from 57 +/- 15 to 32 +/- 10 cm/sec and from 59 +/- 18 to 34 +/- 15 cm/sec, respectively, while velocity time integral during systole, early, and late diastole decreased from 12.0 +/- 5.6 to 4.3 +/- 2.6 cm, from 9.9 +/- 4.4 to 5.2 +/- 3.7 cm, and from 1.3 +/- 0.8 to 0.8 +/- 0.7 cm, respectively. In conclusion, pulmonary venous Doppler characteristics can adequately be analyzed with transesophageal echocardiography. Normal respiration only minimally influences pulmonary venous flow velocities in contrast to straining during the Valsalva maneuver; this should be considered when these variables are applied for clinical purposes.

Hemodynamic effects of different ventilatory patterns. A prospective clinical trial

We compared the hemodynamic effects of three different ventilatory patterns including two variations of the I:E ratio (2:1 and 3:1) and a PEEP-pattern with the MAWP being equal in all three patterns. The study was performed on 15 patients without lung or cardiovascular disease who were ventilated after elective abdominal surgery. Each of the patients was subjected to the three different pressure wave curves. The IPPV served as control. Hemodynamic measurements included TEE registration of the LV cross-sectional areas, diameters and wall thickness as well as arterial blood pressure and heart rate. As a result, we found no significant differences in the hemodynamic effects of all three patterns. Compared with IPPV, they showed a reduction of systolic and diastolic blood pressure, LV dimensions and systolic wall stress. Assessed with the end systolic quotient, LV contractility remained constant.

Optimisation of positive and expiratory pressure for maximal delivery of oxygen to tissues using oesophageal Doppler ultrasonography

OBJECTIVE

To assess oesophageal Doppler ultrasonography as a convenient means of optimising positive end expiratory pressure for maximal delivery of oxygen to tissues.

DESIGN

Measurements of blood flow, arterial oxygen saturation, and cardiac output by thermodilution (when available) at baseline and at 20-30 minutes after each incremental increase (2.5-5.0 cm H2O) in positive and expiratory pressure to a maximum of 20.0 cm H2O. If the cardiac output fell by more than 15% measurements were repeated after stepwise decreases in positive end expiratory pressure. No other manoeuvre such as endotracheal suction or changing ventilator settings, drug or fluid dosage, or the patient's position was performed for at least one hour before the start of the study or during it.

SETTING

Intensive care unit.

PARTICIPANTS

10 Patients being mechanically ventilated for acute respiratory failure who had stable haemodynamic and blood gas values and required a fractional inspired oxygen concentration of greater than or equal to 0.45. They were assessed on a total of 11 occasions.

INTERVENTIONS

Incremental increases in positive end expiratory pressure followed when indicated by stepwise decreases.

END POINT

The positive end expiratory pressure providing maximal delivery of oxygen to tissues.

MEASUREMENTS AND MAIN RESULTS

Arterial oxygen saturation increased with positive end expiratory pressure in all patients by an average of 6.1%. In nine of the 11 studies, however, cardiac output fell by 15% to 30% after the second increment. On the two other occasions cardiac output and oxygen delivery rose by up to 54%. Positive end expiratory pressure was decreased on seven occasions; there was considerable individual variation in the time taken for cardiac output to rise and arterial oxygen saturation to fall. In six patients good agreement was seen between the results from Doppler ultrasonography and thermodilution, the mean of the differences being -0.3% with narrow limits of agreement (-14.4% to 13.9%).

CONCLUSIONS

Oesophageal Doppler ultrasonography is a rapid, safe, and reliable technique for optimising positive end expiratory pressure to obtain maximal delivery of oxygen to tissues. The results show the need to consider haemodynamic consequences when altering positive end expiratory pressure.

The right ventricle and critical illness: a review of anatomy, physiology, and clinical evaluation of its function

This paper reviews right ventricular anatomy and physiology in the critically ill patient. The role of right ventricular function during acute pulmonary artery hypertension and the effect of acute myocardial injury upon right ventricular performance are examined. Clinical methods of assessing right ventricular function at the bedside in acutely ill patients are critically reviewed.

Potential mechanisms of improved left ventricular function with enoximone in severe congestive heart failure

Enoximone, a phosphodiesterase inhibitor, is a potent inotropic vasodilator agent that causes a marked improvement in systemic hemodynamics in patients with severe chronic congestive heart failure. Cardiac index, stroke volume index and stroke work index increase, and there is a significant decrease in pulmonary capillary wedge pressure. Left ventricular dP/dt increases, despite a decrease in arterial pressure and systemic vascular resistance and without any significant change in heart rate, indicating a positive inotropic effect. A marked decrease in systemic vascular resistance indicates that decreased left ventricular outflow resistance resulting from peripheral vasodilation also contributes to improvement in left ventricular function. In some patients, left ventricular end-diastolic volume increases despite a marked decrease in pulmonary capillary wedge pressure, suggesting an improvement in apparent left ventricular compliance, which may also be contributory to improved left ventricular function.

Left ventricular external constraint: relationship between pericardial, pleural and esophageal pressures during positive end-expiratory pressure and volume loading in dogs

Left ventricular (LV) diastolic filling is limited by the constraining effects exerted by the pericardium (PE) and the lung/chest wall. The aim of the present study was to assess the validity of various estimates of external cardiac constraint, compared to pericardial surface pressure (Ppe) measured lateral to the LV myocardium. In nine anesthetized dogs we measured Ppe, pleural surface pressure (Ppt) (lateral to the pericardium) and esophageal pressure (Pes) under conditions of volume loading and positive end-expiratory pressure (PEEP). We measured Ppe and Ppl with flat, liquid-containing silastic rubber balloons and Pes with an air-containing cylindrical balloon. After instrumentation, the chest was resealed and continuous suction (-5 mm Hg, 1 mm Hg = 0.133 kPa) was maintained. Volume loading with incremental intravenous infusions of saline was used to increase LV end-diastolic pressure to 20-25 mm Hg. PEEP of 0, 10 and 20 mm Hg were applied at baseline and after each increment of volume loading. At low volume, increases in PEEP caused simultaneous increases in LV end-diastolic pressure (P less than 0.01) and in Ppe (P less than 0.0001) but a reduction in transmural LV pressure (P less than 0.0005). Ppl and Pes both increased with PEEP (P less than 0.001 and P less than 0.01, respectively). However, Ppe always exceeded Ppl, while Pes remained at only approximately 1/3 Ppl throughout. Volume loading caused a significant increase in Ppe (P less than 0.0001) and a smaller, but significant increase in Ppl (P less than 0.05). Pes remained unchanged during volume loading. Thus external cardiac constraint increased markedly during volume loading and PEEP as evidenced by a marked elevation of Ppe. Both Ppl and Pes markedly underestimated this increase. Therefore, calculation of transmural LV pressure by subtracting pleural or esophageal pressure from intracavitary pressure can lead to overestimation of LV preload. The decrease in cardiac output during PEEP occurs secondary to decreased preload, i.e. decreased transmural pressure and end-diastolic dimension. Analysis of performance using cardiac function curves does not suggest a change in contractility with PEEP.

Transesophageal two-dimensional echocardiographic evaluation of biventricular dimension and function during positive end-expiratory pressure ventilation after coronary artery bypass grafting

Transesophageal 2-dimensional echocardiography was performed in 21 patients soon after uncomplicated coronary artery bypass grafting to determine the mechanism of positive end-expiratory pressure (PEEP) ventilation-induced decreased cardiac output. End-diastolic and end-systolic short-axis area and percent area reduction of right and left ventricles were determined during 5-cm H2O stepwise increments of PEEP ventilation. Simultaneously, cardiac output and right- and left-sided hemodynamic values were determined. Cardiac output, mean arterial pressure and end-diastolic area of both ventricles gradually decreased, and right and left atrial and pulmonary arterial pressures (mainstem and capillary wedge) increased. Left ventricular end-systolic area did not change, whereas right ventricular area decreased. Percent area reduction of both ventricles decreased (p less than 0.01). Thus, decrease in cardiac output during PEEP ventilation is primarily caused by decrease of preload rather than compromised contractility.

The influence of positive end-expiratory pressure on intrapericardial pressure and cardiac function after coronary artery bypass surgery

The hemodynamic effects of positive end-expiratory pressure (PEEP) were studied in coronary artery bypass patients by recording intrapericardial and intracardiac pressures, measuring cardiac output by thermodilution, and determining left ventricular volumes by nuclear radiography. An elevation of PEEP to 5, 10, and 15 cm H2O led to a decrease in cardiac output (15% decrease at PEEP 15) as intrapericardial pressure increased and transmural left atrial pressure decreased. Modest volume loading (an increase in left atrial pressure of 3 mm Hg) greatly attenuated the deleterious effects of 15 cm H2O PEEP. There was an excellent correlation between pulmonary capillary wedge pressure and left atrial pressure at PEEP 0 and 5 (r = .85 and r = .83). This correlation was not nearly as reliable at PEEP 15 (r = .54). A predictable increase in intrapericardial pressure was observed as PEEP was applied in these patients. The magnitude of this increase can be estimated by multiplying the change in PEEP (in cm H2O) by 0.4 to estimate the change in intrapericardial pressure (in mm Hg). Using this estimation as a guide, modest volume loading can be used to maintain transmural filling pressures (and cardiac output) when PEEP is used after coronary artery bypass surgery.

Hemodynamic management in clinical acute hypoxemic respiratory failure. Dopamine vs dobutamine

We investigated short-term hemodynamic effects of dopamine and dobutamine in eight patients with acute hypoxemic respiratory failure. We tested the hypothesis that for a similar increase in cardiac output, left ventricular filling pressure (pulmonary capillary wedge pressure [PCWP]) would increase with dopamine and decrease with dobutamine. Dopamine increased cardiac output (p less than 0.05), stroke volume (p less than 0.05), and PCWP (p less than 0.01). Cardiac output increased almost 20 percent when PCWP increased 50 percent with dopamine. In contrast, despite a mean 30 percent increase in cardiac output with dobutamine (p less than 0.01), PCWP decreased. In six of these patients, left ventricular end-diastolic volumes and end-systolic volumes were measured using scintigraphic techniques. In all patients, end-diastolic volume increased with dopamine (p less than 0.05); and in four of six, end-systolic volume increased. In contrast, with dobutamine, in five of six patients, end-diastolic volume decreased; and in all six patients, end-systolic volume decreased. There was a small increase in intrapulmonary shunt with both drugs. We conclude that if an inotropic agent is required to increase cardiac output in patients with acute hypoxemic respiratory failure, dobutamine is probably preferred over dopamine.

Assisted ventilation in patients with preexisting cardiopulmonary disease. The effect on systemic oxygen consumption, oxygen transport, and tissue perfusion variables

We have evaluated systemic oxygen consumption (VO2), systemic oxygen transport, and tissue perfusion variables in 30 patients with preexisting cardiac and underlying pulmonary disease during continuous positive-pressure ventilation and positive end-expiratory pressure [PEEP], during intermittent mandatory ventilation (IMV and PEEP), and during spontaneous ventilation (continuous positive airway pressure [CPAP]), with end-expiratory pressure held constant during all ventilatory modes. Using radionuclide angiography together with invasive determinations of pressure and flow, we also measured left and right ventricular ejection fractions and calculated the end-systolic (ESVI) and end-diastolic (EDVI) volume indices of both ventricles. We found that oxygen transport was significantly greater during CPAP (583 +/- 172 ml/min/M2)(mean +/- SD) than during either IMV and PEEP (543 +/- 151 ml/min/sq; p less than 0.01) or CPPV and PEEP (526 +/- 159 ml/min/M2; p less than 0.01); however, we found no significant change in systemic VO2 with conversion from CPPV and PEEP to CPAP. The increase in oxygen transport was related to a greater cardiac index and, more specifically, to a higher heart rate during CPAP (CPAP, 106 +/- 16 beats per minute; CPPV and PEEP, 97 +/- 14 beats per minute) (p less than 0.01). Enhanced oxygen transport during CPAP was also associated with an increase in mixed venous oxygenation and a decrease in arterial lactate. Although neither the mean left ventricular EDVI nor ESVI changed from CPPV and PEEP to CPAP, the mean pulmonary capillary wedge pressure increased (CPPV and PEEP, 12 +/- 5 mm Hg; CPAP, 14 +/- 7 mm Hg) (p less than 0.01), suggesting the possibility of a decrease in left ventricular compliance with the spontaneous ventilatory mode. This study suggests that in the absence of ventilatory failure, spontaneous ventilation provides for better systemic oxygen transport and overall tissue perfusion than either controlled ventilation or IMV; however, this benefit of enhanced oxygen delivery with spontaneous ventilation may potentially be offset by a decrease in left ventricular compliance.

Mechanisms of improved left ventricular function following intravenous MDL 17,043 in patients with severe chronic heart failure

To evaluate the mechanisms for improved left ventricular function with MDL 17,043 in patients with severe chronic heart failure, 24 patients were evaluated by simultaneous determination of hemodynamics by right heart catheterization and ejection fraction by computerized nuclear probe before and following intravenous administration of MDL 17,043 (mean cumulative dose 3.6 mg/kg). Following MDL 17,043, there was an increase in cardiac index (+62%), stroke volume index (+42%), and stroke work index (+68%), together with a decrease in pulmonary capillary wedge pressure (-46%), indicating improved left ventricular pump function. There was a marked reduction in systemic vascular resistance (-40%) and a modest reduction in arterial pressure, indicating decreased left ventricular outflow resistance. The ratio of peak systolic blood pressure to calculated left ventricular end-systolic volume tended to increase, but the change was not statistically significant. Despite a marked increment in stroke volume index, left ventricular ejection time corrected for heart rate was shortened, suggesting enhanced contractility. In the group as a whole, the calculated left ventricular end-diastolic volume remained unchanged, but it increased in 14 patients. Since pulmonary capillary wedge pressure fell in each patient, this suggests improved overall left ventricular distensibility. Thus, decreased left ventricular outflow resistance, and possibly increased contractile function, and improved left ventricular diastolic compliance may all contribute to improved left ventricular pump function with MDL 17,043 in patients with severe heart failure.

Military antishock trouser (MAST). Application as a reversible fluid challenge in patients on high PEEP

Fluid management in the critically ill patient receiving high levels of positive end-expiratory pressure (PEEP) can be difficult. PEEP may cause the cardiac index to fall due to a decrease in left ventricular preload. However, the high intrathoracic pressures produced by PEEP negate the usefulness of the pulmonary artery occlusion pressure (PAo) as a measurement of left ventricular preload. The military antishock trouser (MAST), which has been presumed to compress the venous capacitance reservoir and auto-transfuse 500 to 1,000 ml to the central circulation, was used as a reversible predictor of the effects of fluids on 12 critically ill patients receiving PEEP greater than 10 cm H2O with a decreased cardiac index. Hemodynamic variables were measured before, during, and after MAST inflation. Fluids were given in a quantity sufficient to maintain the same PAo after MAST deflation as achieved with the initial inflation. A significant improvement of cardiac performance and a high correlation between MAST and post-MAST variables was observed. Application of MAST as a reversible fluid challenge is a useful method for predicting optimal fluid management.

Biventricular volumes and function in patients with adult respiratory distress syndrome ventilated with PEEP

The ventricular volume and function changes induced by the addition of 12 cm H2O of positive end-expiratory pressure (PEEP) during mechanical ventilation were studied in 11 patients with the adult respiratory distress syndrome. Cardiac output was measured by thermodilution and ventricular ejection fraction by the multiple gated equilibrated cardiac blood pool scintigraphy. Right and left end-diastolic volumes were then calculated by dividing stroke volume by ejection fraction. The PEEP caused a 14 percent decrease of the cardiac output secondary to a decrease in stroke volume. On the basis of the relationship between stroke volume and ventricular end-diastolic volume, we conclude that reduction in preload was the major component of the decrease in cardiac output. After removal of PEEP, we observed a rebound phenomenon characterized by higher values for stroke volume and cardiac output than before the application of PEEP.