Simple computer measurement of pulmonary VCO2 per breath.

Measurements of the volume of CO2 exhaled per breath (VCO2/br) are preferable to end-tidal PCO2, when the exhaled flow and CO2 waveforms may be changing during unsteady states, such as during alterations in positive end-expiratory pressure or alterations in cardiac output. We describe computer algorithms that determine VCO2/br from digital measurements of exhaled flow (including discontinuous signals common in anesthesia circuits) and CO2 concentration at the airway opening. Fractional concentration of CO2 is normally corrected for dynamic response and transport delay (TD), measured in a separate procedure. Instead, we determine an on-line adjusted TD during baseline ventilation. In six anesthetized dogs, we compared the determination of VCO2/br with a value measured in a simultaneous collection of expired gas. Over a wide range of tidal volume (180-700 ml), respiratory rate (3-30 min-1), and positive end-expiratory pressure (0-14 cmH2O), VCO2/br was more accurate with use of the adjusted TD than the measured TD (P less than 0.05).

Right atrial bypass model in the dog.

In gas exchange studies addressing the storage and transport of CO2 in dogs, a model in which cardiac output (QT) can be precisely controlled and measured would be beneficial. We identified problems with described extracorporeal circuits and implemented right atrial bypass (RAB) in dogs. In 6 anesthetized (chloralose and urethane), heparinized dogs (mean +/- SD, 24 +/- 4 kg) with open thorax, cannulas were inserted in both vena cavas to drain venous blood return to a reservoir (anaerobic bag or bubble oxygenator). A roller pump then drove blood through a heat exchanger back to the right atrial appendage. After 1.8 +/- 1.4 hour of RAB, physiologic variables remained within reference limits for dogs (QT, 1.5 +/- 0.3 L/min; blood pressure, 92 +/- 25 mm of Hg; arterial PCO2, 35 +/- 4 mm of Hg; PO2, 513 +/- 39 mm of Hg; pH, 7.39 +/- 0.08; and tissue CO2 production, 126 +/- 56 ml/min). To permit study of gas exchange, venous return (and thus, QT) and venous PCO2 and PO2 could be accurately regulated and measured over a wide range. Maintenance of native pulsatile lung perfusion and cardiogenic oscillations minimizes mismatching of pulmonary ventilation and perfusion and facilitates studies addressing pulmonary gas exchange. This RAB model is designed so that investigators can establish the preparation in a few hours.

Can changes in end-tidal PCO2 measure changes in cardiac output?

In recent studies of cardiopulmonary resuscitation, an increase in end-tidal carbon dioxide tension (PETCO2) signifies an increase in cardiac output (QT) as spontaneous circulation resumes. We hypothesized that changes in QT might generally be measured by changes in PETCO2. In five pentobarbital-anesthetized dogs, we inflated percutaneously inserted vena cava balloons to impede venous return and to decrease QT (measured by pulmonary thermodulation). The PECTCO2 was measured at the airway opening by sidestream infrared capnometry. In 32 vena cava balloon inflation sequences during constant ventilation in five dogs, the percent decrease in PETCO2 directly correlated with the percent decrease in QT (slope = 0.73, R2 = 0.89, P less than 0.001). During decreased QT, reduced CO2 delivery to the lungs decreased alveolar PCO2 to cause part of the decrease in PETCO2. The remaining reduction in PETCO2 resulted from the increase in alveolar dead space (in turn due to lower pulmonary perfusion pressures during reduced QT), which diluted the CO2 from perfused alveolar spaces to further reduce PETCO2. During a sustained reduction in QT, increasing CO2 accumulation in the peripheral tissues and in venous blood began to restore CO2 delivery to the lung and PETCO2 toward baseline levels. Reciprocal changes occurred during increases in QT when the vena cava balloons were deflated. The linear relationship between changes in PETCO2 and QT in animals supports a decision to perform clinical studies necessary to determine whether a change in PETCO2 will be useful as a noninvasive, continuous monitor of a change in QT during anesthesia or intensive care.

Non-steady state monitoring by respiratory gas exchange.

Traditionally, the study of CO2 and O2 kinetics in the body has been mostly confined to equilibrium conditions. However, the peri-anesthesia period and the critical care arena often involve conditions of non-steady state. The detection and explanation of CO2 kinetics during non-steady state pathophysiology have required the development of new methodologies, including the CO2 expirogram, average alveolar expired PCO2, and CO2 volume exhaled per breath. Several clinically relevant examples of non-steady state CO2 kinetics perturbations are examined, including abrupt decrease in cardiac output, application of positive end-expiratory pressure during mechanical ventilation, and occurrence of pulmonary embolism. The lesser known area of non-steady state O2 kinetics is introduced, including the measurement of pulmonary O2 uptake per breath. Future directions include the study of the respiratory quotient per breath, where the anaerobic threshold during anesthesia is identified by increasing respiratory quotient.

Left, but not right, one-lung ventilation causes hypoxemia during endoscopic transthoracic sympathectomy.

OBJECTIVE: To describe the respiratory and cardiovascular effects of one-lung ventilation, using a double-lumen tube, during endoscopic transthoracic sympathectomy. DESIGN: A prospective clinical study. SETTING: A university-affiliated medical center. PARTICIPANTS: Nineteen adult patients (10 men, 1 woman) between 16 and 35 years of age, ASA (American Society of Anesthesiologists) physical status I and II, participated in the study. INTERVENTIONS: Endoscopic transthoracic sympathectomy was performed under general anesthesia, using a double-lumen endobronchial tube, after induction of artificial pneumothorax plus insufflation of CO2 into the operated chest. Via radial artery cannulae, one to three arterial blood gas samples were taken during two-lung ventilation before surgery, at each one-lung ventilation, in most cases during the period of two-lung ventilation when switching between the operated sides, and after surgery. MEASUREMENTS AND MAIN RESULTS: Comparisons were performed using the Wilcoxon matched-pairs single-ranks test. Left-lung ventilation and right-chest operation caused profound decrease of arterial oxygen partial pressure (PaO2), compared with two-lung ventilation before surgery (70.7%, P > 0.0003) and compared with PaO2 at two-lung ventilation during and after surgery (decrease of 80.1% and 75.3%, respectively; P > 0.001 and < 0.005, respectively). Right-lung ventilation and left-chest operation did not cause hypoxemia. Arterial CO2 partial pressure, pH, and bicarbonate, as well as hemodynamic parameters, did not change from baseline values throughout surgery. CONCLUSIONS: Pulse oximetry and repeated blood gas measurements are needed during endoscopic transthoracic sympathectomy in order to detect and treat hypoxemic events, which may jeopardize the patient's life.

Near-sitting position and two-lung ventilation for endoscopic transthoracic sympathectomy.

OBJECTIVE: To control for hypoxemia during endoscopic transthoracic sympathectomy, usually by using double-lumen tube and one-lung ventilation, a different anesthetic technique was adopted. DESIGN: A prospective clinical study. SETTING: A university-affiliated medical center. PARTICIPANTS: Twenty-one adult patients (10 male and 11 female) between 15 and 44 years of age (mean, 22 years), ASA (American Society of Anesthesiologists) physical status I and II, participated in the study. INTERVENTIONS: Under general anesthesia, a single-lumen endotracheal tube was inserted. The radial artery was cannulated for blood pressure monitoring and blood gas sampling. Patients were gradually raised from a supine position to 60 to 70 degrees from the horizontal plane. Mean fractional inspiratory O2 ratio was 0.4 +/- 0.02 (mixture of O2 and air) throughout the operation. Blood gas samples were taken during two-lung ventilation before surgery, at each one-chest operation, and when switching between the operated chest sides. An artificial pneumothorax was established by insufflation of CO2, the sympathetic chain coagulated, the pneumothorax released, and the lung reinflated. MEASUREMENTS AND MAIN RESULTS: Comparisons were performed using one-way analysis of variance and the Bonferroni post-test. Arterial O2 partial pressure at right- and left-chest operation were 209 +/- 83 and 189 +/- 63 mmHg, respectively, compared with 227 +/- 43 and 241 +/- 69 mmHg on two-lung ventilation before and during surgery, respectively. O2 saturation, arterial CO2 partial pressure, bicarbonate, base excess, peak inspiratory pressure, and hemodynamic parameters (in most patients) did not change throughout the operation. CONCLUSIONS: The near-sitting position, a single-lumen tube, and a continuous two-lung ventilation technique is simple and may prevent hypoxemia during endoscopic transthoracic sympathectomy.

Effect of oxygen and sodium thiosulfate during combined carbon monoxide and cyanide poisoning.

In a canine model of combined carbon monoxide (CO) and cyanide (CN) poisoning, cardiac output (QT) and oxygen consumption (Vo2) decreased but recovered to baseline values by 15 min after toxic exposure; elevated blood CN and lactic acidosis persisted for at least another 10 min. Given the rapid spontaneous recovery after cessation of toxic exposure, we questioned the efficacy of usual treatment with oxygen (O2) and sodium thiosulfate (Na2S2O3) for CN poisoning. Accordingly, in seven dogs (26 +/- 3 kg, chloralose and urethane anesthesia), we sequentially administered CO by closed circuit inhalation (231 +/- 42 ml) and potassium CN by intravenous infusion (0.072 mg.kg-1.min-1 for 17 +/- 3 min). Fifteen minutes after toxic exposure, O2 breathing began and Na2S2O3 (150 mg/kg) was infused. Measurements were repeated 10 and 45 min after treatment. At the end of the CN infusion, QT decreased by 43% and Vo2 decreased by 51%, compared to baseline values. Both variables recovered to baseline by 15 min after stopping toxic exposure. Significant lactic (4.8 +/- 2.9 mM) acidosis (7.14 +/- 0.10) persisted for at least another 10 min. Treatment with oxygen and Na2S2O3 did not hasten the recovery of this lactic acidosis or decrease blood cyanide levels compared to nontreated dogs. However, after treatment, plasma thiocyanate significantly increased from 16.3 +/- 12.5 to 94.4 +/- 72.2 microM, as Na2S2O3 participated in the increased metabolism of cyanide to thiocyanate. We conclude that O2 and Na2S2O3 therapy should be continued during combined CO and HCN poisoning. Oxygen increases CO elimination and can enhance anti-CN treatment. After infusion or inhalation of CN, when most CN has already penetrated the intracellular compartment, postexposure sodium thiosulfate increased the metabolism of CN.

Measurement of blood CO2 concentration with a conventional PCO2 analyzer.

OBJECTIVES: CO2 content can be determined from the Pco2 in an acidified (forces all CO2 into solution) and diluted blood sample. However, Pco2 concentrations measured in conventional blood gas analyzers are only correct for samples with a significant buffer capacity (such as whole blood), so that mixing with the Pco2 in the rinse solution and tubing walls does not significantly change the sample Pco2. This study describes a calibration method and validation data for the Radiometer Medical ABL2 CO2 electrode system to accurately measure unbuffered blood samples used in the determination of blood CO2 content (or other aqueous fluids). DESIGN: Prospective, criterion standard. SETTING: Laboratory. MEASUREMENTS AND MAIN RESULTS: Blood samples (0.4 mL) were acidified and diluted with 0.2 M lactic acid. After measuring Pco2, CO2 content was calculated using the CO2 solubility coefficient and the dilution factor of 20. CO2 content was determined in a series of sodium carbonate (Na2CO3) solutions spanning the physiologic range of CO2 content. Regression of the measured vs. the actual CO2 content data generated a straight line with a slope of 0.796 and y-intercept of 12.5 (r2 = .99; n = 48). These coefficients were successfully used to correct CO2 content determined in blood samples into which graduated amounts of sodium carbonate were added. CONCLUSIONS: This calibration procedure allows accurate measurement of Pco2 in aqueous samples using the Radiometer ABL2 electrode system, and should be applicable to other blood gas analyzers. Necessary syringes and chemicals are readily available, the method is fast and simple, and the sample volume is small. In the practice of critical care medicine, accurate Pco2 measurement in aqueous acidified and diluted blood provides direct determination of blood CO2 content (useful in calculations of modified Fick cardiac output or tissue CO2 production). Determinations of absolute CO2 content in blood requiring complex methodology are not necessary. In addition, accurate measurement of aqueous gastric Pco2 can help determine gastric pH, which is an important marker of tissue perfusion.

Protective effect of stroma-free methemoglobin during cyanide poisoning in dogs.

BACKGROUND: During fire exposure, cyanide toxicity can block aerobic metabolism. Oxygen and sodium thiosulfate are accepted therapy. However, nitrite-induced methemoglobinemia, which avidly binds cyanide, decreases oxygen-carrying capacity that is already reduced by the presence of carboxyhemoglobin (inhalation of carbon monoxide in smoke). This study tested whether exogenous stroma-free methemoglobin (SFmetHb) can prevent depression of hemodynamics and metabolism during canine cyanide poisoning. METHODS: In 10 dogs (weighing 18.8 +/- 3.5 kg) anesthetized with chloralose-urethane and mechanically ventilated with air, baseline hemodynamic and metabolic measurements were made. Then, 137 +/- 31 ml of 12 g% SFmetHb was infused into five dogs (SFmetHb group). Finally, the SFmetHb group and the control group (n = 5, no SFmetHb) received an intravenous potassium cyanide infusion (0.072 mg.kg-1.min-1) for 20 min. Oxygen consumption (VO2) was measured with a Datex Deltatrac (Datex Instruments, Helsinki, Finland) metabolic monitor and cardiac output (QT) was measured by pulmonary artery thermodilution. RESULTS: From baseline to cyanide infusion in the control group, QT decreased significantly (p < 0.05) from 2.9 +/- 0.8 to 1.5 +/- 0.4 l/min, mixed venous PCO2 (PvCO2) tended to decrease from 35 +/- 4 to 23 +/- 2 mmHg, PvO2 increased from 43 +/- 4 to 62 +/- 8 mmHg, VO2 decreased from 93 +/- 8 to 64 +/- 19 ml/min, and lactate increased from 2.3 +/- 0.5 to 7.1 +/- 0.7 mM. In the SFmetHb group, cyanide infusion did not significantly change these variables. From baseline to infused cyanide, the increases in blood cyanide (4.8 +/- 1.0 to 452 +/- 97 microM) and plasma thiocyanate cyanide (18 +/- 5 to 65 +/- 22 microM) in the SFmetHb group were significantly greater than those increases in the control group. SFmetHb itself caused no physiologic changes, except small decreases in heart rate and PvO2. Peak SFmetHb reached 7.7 +/- 1.0% of total hemoglobin. CONCLUSIONS: Prophylactic intravenous SFmetHb preserved cardiovascular and metabolic function in dogs exposed to significant intravenous cyanide. Blood concentrations of cyanide, and its metabolite, thiocyanate, revealed that SFmetHb trapped significant cyanide in blood before tissue penetration.

Combined carbon monoxide and cyanide poisoning: a place for treatment.

During fires, victims can inhale significant carbon monoxide (CO) and cyanide (CN) gases, which may cause synergistic toxicity in humans. Oxygen therapy is the specific treatment for CO poisoning, but the treatment of CN toxicity is controversial. To examine the indication for treatment of CN toxicity, we have established a canine model to delineate the natural history of combined CO and CN poisoning. In seven dogs (24 +/- 3 kg), CO gas (201 +/- 43 mL) was administered by closed-circuit inhalation. Then, potassium CN was intravenously (i.v.) infused (0.072 mg.kg-1.min-1) for 17.5 +/- 3.0 min. Cardiorespiratory measurements were conducted before and after these toxic challenges. Despite significant CO poisoning (peak carboxyhemoglobin fractions [COHb] = 46% of total hemoglobin [Hb]; elimination t1/2 = 114 +/- 42 min) with attendant decrease in blood O2 content, CO had essentially little effect on any hemodynamic or metabolic variable. On the other hand, CN severely depressed most hemodynamic and metabolic functions. Compared to baseline values, CN caused significant (P < 0.01) decreases in cardiac output (6.4 +/- 2.0 to 3.1 +/- 0.5 L/min) and heart rate (169 +/- 44 to 115 +/- 29 bpm) and decreases in oxygen consumption (VO2) (133 +/- 19 to 69 +/- 21 mL/min) and carbon dioxide production (VCO2) (128 +/- 27 to 103 +/- 22 mL/min). However, these critical hemodynamic and metabolic variables recovered to baseline values by 15 min after stopping the CN infusion, except lactic acidosis which persisted for at least 25 min after the CN infusion.(ABSTRACT TRUNCATED AT 250 WORDS)