Myocardial metabolism and adaptation during extreme hemodilution in humans after coronary revascularization.

OBJECTIVE: This study was designed to evaluate the oxygen transport adjustments and myocardial metabolic adaptation that occurs with different levels of hemodilution during normothermia after cardiopulmonary bypass. DESIGN: Prospective, nonrandomized study. SETTING: Operating room in a university hospital. PATIENTS: Eight patients with ejection fractions (> 40%) undergoing elective coronary artery bypass grafting. METHODS: Before the institution of cardiopulmonary bypass, blood was withdrawn from patients to a target hematocrit of 15%. After coronary artery bypass grafting, a catheter was inserted directly into the coronary sinus. After the patients were rewarmed to 37 degrees C, they were weaned from cardiopulmonary bypass. Hemodynamic indices were measured, as well as measurements of myocardial oxygen consumption (VO2) and myocardial metabolism (lactate extraction and coronary sinus hypoxanthine). Measurements were made at three different hematocrit values: 15%, 20%, and 25%. Hematocrit was increased by autologous blood transfusion. MEASUREMENTS AND MAIN RESULTS: The three levels of hemodilution (hematocrit: 17.4 +/- 3.4%; 23.0 +/- 3.7%; 27.8 +/- 4.8%) were significantly different from baseline (hematocrit 37 +/- 2.6%; p < .05). Oxygen delivery, which increased with autologous transfusion, exceeded 350 mL/min/m2 at each level of dilution. The myocardial VO2 increased significantly after autologous transfusion compared with the most dilute condition (7.0 +/- 3.7 mL/min at hematocrit 17.4% vs. 11.2 +/- 4.8 mL/min at hematocrit 23.0% and 12.4 +/- 4.0 mL/min at hematocrit 27.8%). This transfusion-induced increase was also true of myocardial oxygen extraction. Lactate extraction and hypoxanthine release were normal and unchanged at each level of hemodilution. Systemic oxygen extraction ratio increased with hemodilution and decreased with autologous transfusion. CONCLUSIONS: Hemodilution to a hematocrit of approximately 15% is tolerated in anesthetized humans after coronary artery bypass surgery. There was no evidence of myocardial ischemia, as demonstrated by absence of S-T depression on the electrocardiogram, lactate extraction, or hypoxanthine release. In selected patients, postoperative transfusion may be based on systemic physiologic end-points, such as oxygen extraction ratio, rather than set hematocrit values.     

Sequential cardiorespiratory patterns in septic shock

Sequential hemodynamic and oxygen transport monitoring was performed in 33 patients with septic shock to define the temporal pattern of physiologic events. Measurements taken over a 24-h period before the hypotensive crisis, defined as the lowest initial mean arterial pressure (MAP), were compared to those taken during the 48 h thereafter. In the 24-h period before the hypotensive crisis, there were increases in cardiac index (CI), central venous pressure (CVP), pulmonary capillary wedge pressure (WP), pulmonary vascular resistance index (PVRI), and pulmonary shunt (Qsp/Qt), but decreases in MAP, systemic vascular resistance index (SVRI) and oxygen delivery (Do2). When sequential cardiorespiratory patterns were examined, oxygen consumption (VO2) fell transiently to significantly low values 12 h before as well as at the time of the hypotensive crisis. SVRI fell and CI rose to values significantly different from normal in the 4 h before the low MAP. During the subsequent 48 h after the hypotensive crisis, CI, CVP, WP, PVRI and Qsp/Qt remained elevated. Values for MAP, SVRI, DO2, and VO2 were significantly reduced. These results demonstrate the existence of antecedent cardiorespiratory alterations that precede the hypotensive episode in septic shock and suggest that flow maldistribution in the systemic circulation is an early event with possible pathogenic significance.     

Respiratory index/pulmonary shunt relationship: quantification of severity and prognosis in the post-traumatic adult respiratory distress syndrome

The relationship between the respiratory index (RI = alveolar-arterial oxygen gradient [P(A-a)O2] normalized by PaO2) and the pulmonary shunt (Qsp/Qt) has been examined in 929 studies from 240 critically ill post-traumatic patients. Of these, 88 patients (443 studies) were individuals who developed post-traumatic adult respiratory distress syndrome (ARDS) and 152 were patients (486 studies) who did not develop ARDS. This study demonstrates that the RI to Qsp/Qt [RI/(Qsp/Qt)] relationship was significantly (p less than .0001) increased in patients who developed fatal ARDS compared with those who did not develop ARDS, or with those whose ARDS resolved. Because of the increased oxygen consumption (VO2) in ARDS patients in association with their severe limitations in gas exchange (RI) and increased Qsp/Qt, surviving ARDS patients had a significant increase in the cardiac index which resulted in a higher oxygen delivery to VO2 ratio. ARDS patients showed significant (p less than .0001) evidence of increased pulmonary vascular tone, correlated with the increase in the RI/(Qsp/Qt) relationship. In addition, those patients with high RI/(Qsp/Qt) also had increased right ventricular (RVSW) to left ventricular work (LVSW) ratios which were shown to be a direct function of the rise in RI. This increase in both RVSW/LVSW and RI/(Qsp/Qt) ratios was significantly (p less than .0001) correlated with an increased mortality. Thus, the RI/(Qsp/Qt) relationship, which can be obtained from arterial and mixed venous blood gases and saturations only, can be used to predict the severity of the ARDS process as well as important pulmonary vascular and right ventricular overload consequences.     

Stable and reproducible porcine model of acute lung injury induced by oleic acid

BACKGROUND AND METHODS: Previous studies on acute lung injury induced with oleic acid did not attempt to limit the influence of secondary changes on pulmonary circulation, and cardiopulmonary variable data were only collected and processed intermittently. Our study was designed to continuously monitor the following variables in five swine: systemic and pulmonary pressure; mixed venous oxygen saturation (SVO2) and arterial oxygen saturation (SaO2); minute oxygen consumption and CO2 production before, during, and for 4 hr after the infusion of oleic acid. A personal computer was programmed to produce 20-sec updates of deadspace ratio (VD/VT), venous admixture (Qsp/Qt), pulmonary (PVR) and systemic vascular resistance (SVR), and cardiac output (Qt) from these data. RESULTS: During the oleic acid infusion, there were increases in PVR, SVR, heart rate (HR), mean pulmonary arterial pressure (MPAP), Qsp/Qt, and VD/VT, and a decrease in Qt, SaO2, and SVO2. Thirty minutes after the oleic acid infusion, there was a further increase in HR, Qsp/Qt, and VD/VT, while MPAP, PVR, and SVR gradually decreased to pre-oleic acid infusion levels. No further decrease in SaO2, SVO2, and Qt was observed during that time. After the 30-min period, there was no further change in the cardiopulmonary variables. CONCLUSION: Our method of continuous monitoring was able to demonstrate in swine both the dynamic changes during, and stability after, the oleic acid infusion.     

Unreliability of oxygen tension-based indices in reflecting intrapulmonary shunting in critically ill patients

Measurement of intrapulmonary shunting (Qsp/Qt), a widely used method for monitoring disturbances of pulmonary oxygen transfer in critically ill patients, involves calculation of arterial and mixed venous oxygen contents. In circumstances where mixed venous blood samples are not readily available, oxygen tension-based indices such as the alveolar to arterial oxygen tension differences (P[A-a]O2), arterial oxygen tension to alveolar oxygen tension ratio (PaO2/PAO2), PaO2 to FIO2 ratio (PaO2/FIO2) and respiratory index (RI) are widely utilized to reflect Qsp/Qt. Oxygen content-based indices such as the estimated shunt are not as widely utilized as the oxygen tension indices. In 75 critically ill patients in whom a pulmonary artery catheter was being utilized to augment clinical care, comparisons were made between Qsp/Qt and P(A-a)O2, PaO2/PAO2, PaO2/FIO2, RI, and estimated shunt to determine which index best reflected Qsp/Qt. Correlations between Qsp/Qt and estimated shunt were good (r = .94) and poor for the P(A-a)O2 (r = .62), PaO2/PAO2 (r = .72), PaO2/FIO2 (r = .71), and RI (r = .74). We conclude that there are no real substitutes for venous oxygen contents in critically ill patients. When pulmonary artery blood is not available for analysis, oxygen tension-based indices are unreliable reflectors of Qsp/Qt while the estimated shunt, an oxygen content-based index, provides a more reliable reflection of Qsp/Qt.     

Gastric-arterial PCO2 gradient does not reflect systemic and splanchnic hemodynamics or oxygen transport after cardiac surgery

Gastric mucosal-arterial PCO2 gradient (P(g-a)CO2) is used to assess splanchnic perfusion and oxygenation. We evaluated whether P(g-a)CO2 reflects whole body (Q) and splanchnic (Qsp) blood flow, oxygen delivery (DO2) and consumption (VO2) after coronary artery by pass graft (CABG) operation. Thirty patients received dobutamine or dopexamine to increase cardiac index, 15 patients enalapril or sodium nitroprusside to lower blood pressure, and 30 patients were controls. We measured Q, Qsp (hepatic vein catheter and indocyanine green), and gastric mucosal PCO2 (nasogastric tonometer) before and after interventions. Multiple linear regression model showed that none of the changes in Q, Qsp, and splanchnic or systemic DO2 and VO2 significantly explained changes in P(g-a)CO2 (deltaP(g-a)CO2). All independent variables together explained only 7% of deltaP(g-a)CO2. Increased splanchnic blood flow (0.65 +/- .19 vs. 0.94 +/- .31 L/min/m2, P < 0.001) and increased splanchnic DO2 (101 +/- 28 vs. 143 +/- 42 mL/min/m2, P < 0.001) during catecholamine infusions were associated with increased P(g-a)CO2 (8 +/- 8 vs. 11 +/- 7 mmHg, P = 0.003). P(g-a)CO2 does not reflect whole body or splanchnic blood flow, DO2 or VO2 after CABG operations. The physiology of P(g-a)CO2 is complex and therefore it is difficult for clinicians to interpret changes in gastric mucosal-arterial PCO2 gradient in individual patients after cardiac surgery.     

Effect of hydralazine on intrapulmonary shunt

We compared the acute effects of bilateral arteriovenous may be related to levels of PvO2. The hydralazine-associated (p less than .05) decrease in resistance. Mixed venous oxygen fistulas to those of hydralazine infusion on hemodynamics and pulmonary gas exchange in dogs with pulmonary edema induced by administration of oleic acid. Oleic acid significantly (p less than .01) increased intrapulmonary shunt (Qsp/Qt) and pulmonary and systemic vascular resistance, and reduced cardiac output. Once the lesion stabilized, both opening the fistula and infusing hydralazine produced a similar and significant (p less than .01) increase in cardiac output, and a significant (p less than .05) decrease in resistance. Mixed venous oxygen tension (PvO2) closely followed the changes in cardiac output; however, PaO2 did not change. Qsp/Qt significantly (p less than .01) increased with the fistulas open and with hydralazine infusion. Closure of the fistulas or bleeding the animal at the end of the experiment reversed the changes in cardiac output and Qsp/Qt. The comparable increases in cardiac output and Qsp/Qt produced by opening the fistulas or infusing hydralazine may be related to levels of PvO2. The hydralazine-associated PvO2 increase indicates that this drug increased oxygen transport to the tissues even as Qsp/Qt became larger.     

Reduced venous admixture in hemorrhagic hypovolemia: maintenance of arterial oxygenation by selective pulmonary vascular collapse

In nine anesthetized and ventilated swine, a microcomputer calculated cardiac output, venous admixture (Qsp/Qt) and physiologic deadspace (VD/VT) every 20 sec, utilizing dual oximetry and a gas exchange analyzer. After lung injury with ethchlorvynol (ECV), animals were bled 40% blood volume over 40 min. Mean cardiac output decreased 7.0 to 2.2 L/min (p less than .05) accompanied by a decrease in mean Qsp/Qt from 0.28 to 0.14 (p less than .05) and an increase in mean VD/VT from 0.39 to 0.54 (p less than .05). Arterial Hgb saturation (Sao2) increased from 88 +/- 7% to 90 +/- 6%. On regression of all data points for each variable, Qsp/Qt had a positive correlation with cardiac output (r = .90), mean arterial pressure (MAP, r = .87), mean pulmonary artery pressure (MPAP, r = .86), and mixed venous Hgb saturation (Svo2, r = .89, p less than .001). VD/VT had an inverse correlation with cardiac output (r = -.90), MAP (r = -.82), Qsp/Qt (r = -.83), MPAP (r = -.77), and Svo2 (r = -.92, p less than .001). The decreasing Qsp/Qt and increasing VD/VT, with decreasing pulmonary perfusion pressures, were attributed to selective loss of perfusion to alveoli with low ventilation/perfusion ratios.     

Sequential cardiopulmonary changes after oleic-acid injury in dogs

Oleic acid (OA) administered to experimental animals increases pulmonary vascular permeability and produces a condition that pathophysiologically resembles adult respiratory distress syndrome (ARDS) in humans. The present study examined the sequence of cardiorespiratory changes after OA infusion and their similarity to ARDS. After a baseline period, mechanically ventilated and anesthetized dogs were administered 0.18 ml/kg body weight OA into the pulmonary artery while hemodynamic and respiratory changes were monitored. After OA infusion, cardiac output fell by 39%, paralleling a 26% decrease in heart rate. Pulmonary vascular resistance (PVR) increased over 200% without a change in pulmonary capillary wedge pressure and initially without an increase in pulmonary artery pressure (PAP). Within 30 min after OA infusion, dynamic pulmonary compliance (Cdyn) was reduced 32% from baseline values, with a coincident increase in the alveolar-arterial PO2 gradient (P[A-a]O2) but without a significant change in the pulmonary shunt fraction (Qsp/Qt). This was followed in 30 min by a further 27% decrease in Cdyn, with a Qsp/Qt in excess of 50%. Both the hematocrit and hemoglobin concentration increased progressively after OA infusion, without a change in plasma protein concentration. The results suggest that the sequence of cardiopulmonary changes after OA injury are initially marked by a decrease in Cdyn and an increase in PVR and P(A-a)O2. This is followed by an increase in Qsp/Qt, PAP, hemoglobin concentration and PCO2. The changes appear related to progressive flooding of the alveolar air space with edema fluid. These findings parallel the sequential cardiorespiratory changes reported to occur in ARDS.     

Assessing pulmonary function in acute respiratory insufficiency: a clinical charting sheet

A sheet to chart the clinical respiratory variables relevant to acute respiratory insufficiency (ARI) therapy is presented. The chart permits plotting shunt fraction (Qsp/Qt) and efficiency (E or 1--Qsp/Qt) vs. load (L). L is the volume of oxygen (combined and dissolved) that would be exchanged in the lung per minute, if venous blood became fully equilibrated with alveolar gas. L relates cardiac output (Qt), hemoglobin concentration, alveolar oxygen tension, venous oxygen saturation and tension, and the oxygen-hemoglobin combining and oxygen solubility constants. Oxygen consumption (VO2) isopleths are added to the sheet (VO2 = L X E). Qt, VO2, and hence L are indexed per m2 (body surface area), and the approximate normal VO2 range is indicated. Using this sheet hopefully simplifies the correlation of complex pulmonary oxygen exchange data and enhances information recognition and analysis. It provides special help in determining the optimal PEEP in difficult ARI cases. To illustrate its use, a case is detailed.     

Arterial blood gas derived variables as estimates of intrapulmonary shunt in critically ill children

Oxygen transport data, prospectively collected from 52 critically ill children, were analyzed to determine whether any derived variable accurately estimated intrapulmonary shunt (Qsp/Qt). Arterial hemoglobin saturation was more closely correlated with Qsp/Qt than was PaO2, alveolar-arterial oxygen gradient, arterial mixed venous oxygen difference (C[a-v]O2), arterial/alveolar oxygen ratio, and the ratio of PaO2 to inspired oxygen (FIO2) (r = 0.8, p less than .0001). When C(a-v)O2 was normal, hemoglobin saturation became a very accurate (r = 0.96) assessment of Qsp/Qt. We conclude that various arterial blood gas derived variables do not accurately reflect Qsp/Qt in critically ill children. In these patients, a pulmonary artery catheter is needed to accurately assess intrapulmonary shunt.     

Hepatic and splanchnic oxygen consumption during acute hypoxemic hypoxia in anesthetized pigs

OBJECTIVE: To compare the hepatosplanchnic oxygen consumption (VO2) with the hepatic and splanchnic VO2 and to calculate the critical oxygen delivery (DO2crit) below which VO2 decreases in the hepatic, splanchnic, and hepatosplanchnic regions in a model of hypoxemic hypoxia. DESIGN: Prospective animal study. SETTING: University research laboratory. SUBJECTS: Anesthetized and ventilated pigs (n = 7). INTERVENTIONS: The right carotid artery was cannulated to measure mean arterial pressure. A pulmonary artery catheter was inserted to measure mean pulmonary arterial pressure and cardiac output. After a midline abdominal incision, two flow probes were positioned around the portal vein and the hepatic artery to measure portal vein blood flow and hepatic artery blood flow. Oxygen and lactate contents in the carotid artery, the portal vein, and the hepatic vein were measured in blood samples obtained from the appropriate catheters. MEASUREMENTS AND MAIN RESULTS: After a 2-hr stabilization period, hemodynamic and biological variables were recorded during acute hypoxemic hypoxia (FIO2 = 0.5, 0.4, 0.3, 0.21, 0.15, 0.10, and 0.07). VO2, DO2, and DO2crit were determined in the hepatic, splanchnic, and hepatosplanchnic regions. The hepatosplanchnic VO2 was 48 +/- 5 mL/min at high FIO2 (40% for the liver and 60% for the splanchnic organs) and decreased below FIO2 of 0.15. Lactate uptake in the whole hepatosplanchnic region remained steady at FIO2 values of 0.5 to 0.15 and then switched to a lactate release at low FIO2. However, the splanchnic region released lactate, whereas lactate was taken up by the liver. DO2crit in the hepatic, splanchnic, and hepatosplanchnic regions was 24 +/- 3, 38 +/- 2, and 49 +/- 4 mL/min, but the systemic DO2crit, below which regional VO2 became oxygen supply dependent, did not differ in the liver, splanchnic, and hepatosplanchnic regions. CONCLUSIONS: The variables of oxygenation and lactate flux measured in the hepatosplanchnic region summarize the metabolic changes of various organs that may vary in different ways during hypoxemic hypoxia.     

End-tidal CO2 pressure determinants during hemorrhagic shock

OBJECTIVES: To examine the relationship between end-tidal CO2 (PETCO2) and its physiological determinants, pulmonary blood flow (cardiac output, CO) and CO2 production (VCO2), in a model of hemorrhagic shock during fixed minute ventilation. DESIGN AND SETTING: Prospective, observational study in a research laboratory at a university center. SUBJECTS AND INTERVENTIONS: Six anesthetized, intubated, and mechanically ventilated mongrel dogs. Progressive stepwise bleeding. MEASUREMENTS AND RESULTS: We continuously measured PETCO2 with a capnograph, pulmonary artery blood flow with an electromagnetic flow probe, arterial oxygen saturation (SaO2) with a fiberoptic catheter, and oxygen consumption (VO2) and VCO2 by expired gases analysis. Oxygen delivery (DO2) was continuously calculated from pulmonary blood flow and SaO2. We studied the correlation of PETCO2 with CO and VCO2 in each individual experiment. We also calculated the critical point in the relationships PETCO2/ DO2 and VO2/DO2 by the polynomial method. As expected, PETCO2 was correlated with CO. The best fit was logarithmic in all experiments (median r2 = 0.90), showing that PETCO2 decrease is greater in lowest flow states. PETCO2 was correlated with VCO2, but the best fit was linear (median r2 = 0.77). Critical DO2 for PETCO2 and VO2 was 8.0 +/- 3.3 and 6.3 +/- 2.5 ml x min(-1) kg(-1), respectively (NS). CONCLUSIONS: Our data reconfirm the relationship between PETCO2 and CO during hemorrhagic shock. The relatively greater decrease in PETCO2 at lowest CO levels could represent diminished CO2 production during the period of VO2 supply dependency.     

Sequential cardiopulmonary variables of infants and children in septic shock

Sequential cardiopulmonary variables were analyzed in 32 infants and children with septic shock. Variables were staged by a system based on therapeutic efforts to control blood pressure. There were 14 survivors and 18 nonsurvivors. Systemic circulation variables (MAP, cardiac index [CI], systemic vascular resistance index [SVRI], wedge pressure [WP], left cardiac work index [LCWI]) and pulmonary circulation variables (mean pulmonary artery pressure [MPAP], pulmonary vascular resistance index [PVRI], CVP, right cardiac work index [RCWI]) were similar in survivors and nonsurvivors. Pulmonary variables (intrapulmonary shunt [Qsp/Qt], fraction of inspired oxygen [FIO2], Pao2, PaCO2) revealed significantly more dysfunction in nonsurvivors than survivors during the postresuscitation (PR) and middle (M) shock stages. Even though oxygen delivery was equivalent in survivors and nonsurvivors, nonsurvivors demonstrated decreased oxygen utilization variables (oxygen consumption [Vo2], arteriovenous oxygen content difference [C(a-v)O2], O2 extraction index, core temperature) during the resuscitation (RS) and PR stages.     

The oxygen debt during routine cardiac surgery: illusion or reality?

BACKGROUND: Patients undergoing cardiac surgery with the use of cardiopulmonary bypass (CPB) are often thought to have tissue hypoxia and intraoperative oxygen debt accumulation despite the lack of sufficient data to support this assumption. METHODS AND RESULTS: Oxygen uptake and related parameters, including the plasma lactate and pyruvate concentrations, were studied during the perioperative period in a group of 15 consecutive patients who underwent coronary artery bypass graft surgery. The actual oxygen uptake (VO2) and delivery (DO2) were compared with the individual expected (computed) oxygen transport values. The mean values of DO2 and VO2 were in the range of the expected values. Our results demonstrate a leading role for body temperature in perioperative changes of oxygen consumption rate (r2=0.65, p<0.001). Plasma lactate and pyruvate did not exceed the physiological range in any patient. However, with initiation of CPB, the lactate to pyruvate (LA/PVA) ratio increased (from 9.87 +/- 2.43 at T1 to 12.08 +/- 1.51 at T2, p<0.05). The mean value of the LA/ PVA ratio was elevated during surgery. Later, upon lowering of the plasma lactate concentration in the postoperative period, the LA/PVA ratio decreased to normal values. Without any other evidence of hypoxia, this increase in the LA/PVA ratio could be explained by washout of lactate from previously hypoperfused tissues and intraoperative decrease of lactate clearance. CONCLUSION: Systemic oxygenation was not impaired during CPB, or during 18 h after surgery in the studied group of patients.     

The influence of cardiopulmonary bypass on respiratory function in an early postoperative period

AIM: To investigate the influence of cardiopulmonary bypass (CPB) on pulmonary function early after the operation by evaluating Qs/Qt. MATERIAL AND METHODS: Twenty one patients after elective myocardial revascularization surgery have been analysed. Group 1 included 11 patients who have undergone cardiac surgery with CPB. Group 2 included 10 patients who have undergone cardiac surgery without CPB. Blood gas analysis for intrapulmonary shunt calculations was made 20 minutes after the induction of anesthesia and 4 hours after surgery. Qs/Qt was also calculated. RESULTS: Four hours after surgery Qs/Qt increased compared to preoperative data in group 1 (from 8.6 +/- 2.1 to 16.8 +/- 2.6%, p < 0.02). Intrapulmonary shunt was greater in group 1 vs group 2 four hours after the surgery (16.8 +/- 2.6 and 7.8 +/- 2.1%, p < 0.02). In group 1, alterations in a pulmonary function (81.8%) were caused by atelectasis detected by chest x-ray. In group 2 neither increase in intrapulmonary shunt nor atelectasis were determined. CONCLUSION: Arterial hypoxemia and an increase in the intrapulmonary shunt (due to atelectasis) have proven that alterations in the pulmonary function occur more often and are more pronounced in patients after surgery with cardiopulmonary bypass.     

Hemodynamic and metabolic effects of dobutamine in 18 patients after open heart surgery

Low cardiac output syndrome frequently follows cardiopulmonary bypass (CPB) surgery. In the present study, we used dobutamine to increase cardiac index (CI) and oxygen delivery (DO2) in 18 patients after open heart surgery. Using increasing doses of dobutamine up to 10 micrograms/kg.min-1, we observed statistically significant (p less than .01) increases in mean CI (2.50 +/- 0.10 to 3.56 +/- 0.18 L/min.m2) and in mean heart rate (HR) (83 +/- 3 to 105 +/- 3 beat/min). Mean systemic vascular resistance index decreased significantly (p less than .01) in all patients (2271 +/- 101 to 1648 +/- 83 dyne.sec/cm5.m2). Pulmonary vascular resistance index did not change in the ten coronary artery bypass graft patients, but decreased significantly (p less than .01) in the eight valve replacement patients (561 +/- 98 to 421 +/- 79 dyne.sec/cm5.m2). Mean DO2 increased in all patients, although there was no concomitant increase in oxygen consumption (VO2) in four patients. We observed a significant (p less than .01) increase in mean VO2 in the remaining 14 patients (110 +/- 6 to 148 +/- 12 ml/min.m2), in spite of significant decreases in PaO2 and increases in right-to-left intrapulmonary shunting. Although increases in HR and ventricular arrhythmias may limit its use, dobutamine increases CI and DO2 in patients after CPB. In the present study, dobutamine's varying metabolic effect exemplifies the need for close monitoring of hemodynamic and metabolic variables when using vasoactive drugs in the postoperative period.     

Continuous positive airway pressure is beneficial in treatment of smoke inhalation

This study demonstrates that continuous positive airway pressure (CPAP) improves pulmonary function after smoke inhalation by dogs. Sixteen dogs were anesthetized with iv sodium pentobarbital. Arterial and mixed venous blood gas tensions; carboxyhemoglobin concentration (COHgb); mean systemic arterial (MAP), mean pulmonary arterial (MPAP), and pulmonary arterial wedge (WP) pressures; heart (HR) and respiratory (f) rates; cardiac output (CO); and airway pressure (Paw) were measured. Intrapulmonary physiologic shunt (Qsp/Qt) and pulmonary (PVR) and systemic (SVR) vascular resistances were calculated. The animals then breathed an aerosol of smoke and were divided randomly into 2 groups. The treatment group breathed spontaneously on 8-torr CPAP whereas the control group continued to breathe spontaneously at ambient pressure. After inhalation of smoke, Qsp/Qt, MPAP, PVR, COHgb, HR, and f rose, whereas PaO2 and MAP fell in untreated animals. When CPAP was applied, PaO2 and Qsp/Qt returned nearly to baseline values. Mean f also was significantly lower in the treated animals. We found that the early institution of CPAP improves oxygen exchange in the lungs after the inhalation of smoke.     

Oxygen tensions and oxyhemoglobin saturations in the assessment of pulmonary gas exchange

We studied the theoretical basis for continuous monitoring of pulmonary gas exchange using arterial and mixed venous oximetry by examining the mathematical relationships between the calculated venous admixture (Qsp/Qt) and the ventilation-perfusion index, which is derived from oxyhemoglobin saturations. We compared this relationship with that between Qsp/Qt and its commonly used estimates: inspired oxygen concentration to arterial blood oxygen tension ratio, arterial to alveolar oxygen tension ratio, and alveolar-arterial oxygen tension difference. The relationship between Qsp/Qt and the oxygen tension-based indices is nonlinear and substantially influenced by changes in inspired oxygen concentration and arteriovenous oxygen content difference. Therefore, it is inaccurate within the clinically acceptable range of arterial blood oxygenation. In contrast, calculation of ventilation-perfusion index from arterial and mixed venous blood oxyhemoglobin saturations provides a linear estimate of Qsp/Qt that is minimally affected by alterations in inspired oxygen concentration or oxygen uptake and, therefore, will allow accurate continuous assessment of pulmonary gas exchange.