Accuracy of a portable blood gas analyzer incorporating optodes for canine blood

The accuracy of a portable blood gas analyzer (OPTI 1) was evaluated using canine blood and aqueous control solutions. Sixty-four arterial blood samples were collected from 11 anesthetized dogs and were analyzed for pH, partial pressure of carbon dioxide (PCO2) partial pressure of oxygen (PO2), and bicarbonate concentration ([HCO3-]) values by the OPTI 1 and a conventional blood gas analyzer (GASTAT 3). The conventional analyzer was considered as a standard against which the OPTI 1 was evaluated. Comparison of OPTI 1 results with those of GASTAT 3 by linear regression analysis revealed a high degree of correlation with the GASTAT 3 (r = .90-.91). The mean +/- SD of the differences between OPTI 1 and GASTAT 3 values was -0.008 +/- 0.017 for pH, -0.88 +/- 3.33 mm Hg for PCO2, 3.71 +/- 6.98 mm Hg for PO2, and -0.34 +/- 1.45 mEq/L for [HCO3-]. No statistically significant difference was found between the OPTI 1 and the GASTAT 3. Agreement between these 2 methods is within clinically acceptable ranges for pH, PCO2, PO2, and [HCO3-]. The coefficients of variation for measured pH, PCO2, and PO2 values of 3 aqueous control solutions (acidic, normal, and alkalotic) analyzed by the OPTI 1 ranged from 0.047 to 0.072% for pH, 0.78 to 1.81% for PCO2, and 0.73 to 2.77% for PO2. The OPTI 1 is concluded to provide canine blood gas analysis with an accuracy that is comparable with that of conventional benchtop blood gas analyzers.     

Partial pressures of oxygen and carbon dioxide, pH, and concentrations of bicarbonate, lactate, and glucose in pleural fluid from horses

Samples of pleural fluid from 20 horses with effusive pleural diseases of various causes were evaluated; samples from 19 horses were used for the study. There were differences for pH (P = 0.001) and partial pressure of oxygen (PO2) between arterial blood and nonseptic pleural fluid (P = 0.0491), but there were no differences for pH, PO2, partial pressure of carbon dioxide (PCO2), and concentrations of bicarbonate (HCO3-), lactate, and glucose between venous blood and nonseptic pleural fluid. Paired comparisons of venous blood and nonseptic pleural fluid from the same horse indicated no differences. There were differences (P = 0.0001, each) for pH, PO2, PCO2, and concentrations of HCO3- between arterial blood and septic pleural fluid. Differences also existed for pH (P = 0.0001), PCO2 (P = 0.0003), and concentrations of HCO3- (P = 0.0001), lactate (P = 0.0051), and glucose (P = 0.0001) between venous blood and septic pleural fluid. Difference was not found for values of PO2 between venous blood and septic pleural fluid, although 4 samples of septic pleural fluid contained virtually no oxygen. Paired comparisons of venous blood and septic pleural fluid from the same horse revealed differences (P less than 0.05) for all values, except those for PO2. These alterations suggested functional and physical compartmentalization that separated septic and healthy tissue. Compartmentalization and microenvironmental factors at the site of infection should be considered when developing therapeutic strategies for horses with septic pleural disease.     

Comparison of PO2, PCO2, and pH in blood collected from the femoral artery and a cut claw of cats

A technique for collection of blood samples from the cut claw of the cat was developed. Forty-six blood samples were collected simultaneously from the cut claw and the femoral artery of 7 healthy cats. Blood gas and pH values were measured and compared. There was no difference between sample pairs for blood PO2 and PCO2, but the pH values were significantly (P less than 0.001) higher in the capillary samples (7.432 +/- 0.033) than in the samples from the femoral artery (7.419 +/- 0.031).     

Sampling and storage of blood for pH and blood gas analysis.

Techniques used in sampling and storage of a blood sample for pH and gas measurements can have an important effect on the measured values. Observation of these techniques and principles will minimize in vitro alteration of the pH and blood gas values. To consider that a significant change has occurred in a pH or blood gas measurement from previous values, the change must exceed 0.015 for pH, 3 mm Hg for PCO2, 5 mm Hg for PO2, and 2 mEq/L for [HCO-3] or base excess/deficit. In vitro dilution of the blood sample with anticoagulant should be avoided because it will alter the measured PCO2 and base excess/deficit values. Arterial samples should be collected for meaningful pH and blood gas values. Central venous and free-flowing capillary blood can be used for screening procedures in normal patients but are subject to considerable error. A blood sample can be stored for up to 30 minutes at room temperature without significant change in acid-base values but only up to 12 minutes before significant changes occur in PO2. A blood sample can be stored for up to 3.5 hours in an ice-water bath without significant change in pH and for 6 hours without significant change in PCO2 or PO2. Variations of body temperatures from normal will cause a measurable change in pH and blood gas values when the blood is exposed to the normal water bath temperatures of the analyzer.     

Blood gas and acid-base analysis of arterial blood in 57 newborn calves

The pH, partial pressure of oxygen (pO(2)), partial pressure of carbon dioxide (pCO(2)), concentration of bicarbonate (HCO(3)(-)), base excess and oxygen saturation (SO(2)) were measured in venous and arterial blood from 57 newborn calves from 55 dams. Blood samples were collected immediately after birth and 30 minutes, four, 12 and 24 hours later from a jugular vein and a caudal auricular artery. The mean (sd) pO(2) and SO(2) of arterial blood increased from 45.31 (16.02) mmHg and 64.16 (20.82) per cent at birth to a maximum of 71.89 (8.32) mmHg and 92.81 (2.32) per cent 12 hours after birth, respectively. During the same period, the arterial pCO(2) decreased from 57.31 (4.98) mmHg to 43.74 (4.75) mmHg. The correlation coefficients for arterial and venous blood were r=0.86 for pH, r=0.85 for base excess and r=0.76 for HCO(3)(-). The calves with a venous blood pH of less than 7.2 immediately after birth had significantly lower base excess and HCO(3)(-) concentrations for 30 minutes after birth than the calves with a venous blood pH of 7.2 or higher. In contrast, the arterial pO(2) was higher in the calves with a blood pH of less than 7.2 than in those with a higher pH for 30 minutes after birth.     

The Effect of Resuscitation Technique and Pre-Arrest State of Oxygenation on Blood–Gas Values during Cardiopulmonary Resuscitation in Dogs

Large mongrel dogs were anesthetized, instrumented, and subjected to electrically induced ventricular fibrillation after breathing either 100% oxygen (O2) or 10% O2 and 90% nitrogen for 10 minutes before arrest. Four minutes after arrest, open chest cardiopulmonary resuscitation (CPR) or intermittent abdominal compression closed chest CPR was initiated and continued for 20 minutes, at which time defibrillation was attempted. Central arterial and mixed venous blood samples were collected serially for the measurement of pH, carbon dioxide partial pressure (PCO2), and O2 partial pressure (PO2), and calculation of bicarbonate concentration and base excess. Mixed venous blood was collected serially for the measurement of lactate concentration. Hemodynamically variable resuscitation techniques and pre-arrest hypoxia or hyperoxia did not significantly influence blood-gas values during CPR. Mixed venous lactate concentrations after 20 minutes of CPR were significantly higher when hypoxia preceded the arrest and when intermittent abdominal compression closed chest CPR was used for resuscitation. Mixed venous PCO2 was significantly higher than arterial PCO2 in all dogs during CPR but was not significantly different before arrest.     

Blood oxygen binding in hypoxaemic calves

Blood oxygen transport and tissue oxygenation were studied in 28 calves from the Belgian White and Blue breed (20 healthy and 8 hypoxaemic ones). Hypoxaemic calves were selected according to their high respiratory frequency and to their low partial oxygen pressure (PaO2) in the arterial blood. Venous and arterial blood samples were collected, and 2,3-diphosphoglycerate, adenosine triphosphate, chloride, inorganic phosphate and hemoglobin concentrations, and pH, PCO, and PO2 were determined. An oxygen equilibrium curve (OEC) was measured in standard conditions, for each animal. The arterial and venous OEC were calculated, taking body temperature, pH and PCO2 values in arterial and venous blood into account. The oxygen exchange fraction (OEF%), corresponding to the degree of blood desaturation between the arterial and the venous compartments, and the amount of oxygen released at the tissue level by 100 mL of blood (OEF Vol%) were calculated from the arterial and venous OEC combined with the PO2 and hemoglobin concentration. In hypoxaemic calves investigated in this study, the hemoglobin oxygen affinity, measured under standard conditions, was not modified. On the contrary, in vivo acidosis and hypercapnia induced a decrease in the hemoglobin oxygen affinity in arterial blood, which combined to the decrease in PaO2 led to a reduced hemoglobin saturation degree in the arterial compartment. However, this did not impair the oxygen exchange fraction (OEF%), since the hemoglobin saturation degree in venous blood was also diminished.     

Evaluation of Toenail Blood Samples for Blood Gas Analysis in the Dog

Blood gas values were compared in blood collected from cut toenails and femoral arteries in 50 healthy crossbred dogs that were sedated and allowed to breathe room air spontaneously. Blood samples from cut toenails were collected by microcapillary technique with Natelson tubes. Femoral artery samples were collected by arterial puncture. Blood values for PO2, PCO2, pH, and HCO3 were compared. There was good correlation for pH, PCO2, and bicarbonate, but not for PO2. Microcapillary samples should be collected in 10 seconds or less for the most accurate results. A metal mixing "flea" was unnecessary. When properly handled, the Natelson tube technique provides an alternative method for collection of blood gas samples.     

Mechanisms controlling the oxygen consumption in experimentally induced hypochloremic alkalosis in calves

The study was carried out on healthy Friesian calves (n = 10) aged between 10 and 30 days. Hypochloremia and alkalosis were induced by intravenous administration of furosemide and isotonic sodium bicarbonate. The venous and arterial blood samples were collected repeatedly. 2,3-diphosphoglycerate (2,3-DPG), hemoglobin and plasmatic chloride concentrations were determined. The red blood cell chloride concentration was also calculated. pH, PCO2 and PO2 were measured in arterial and mixed venous blood. The oxygen equilibrium curve (OEC) was measured in standard conditions. The correspondence of the OEC to the arterial and mixed venous compartments was calculated, taking blood temperature, pH and PCO2 values into account. The oxygen exchange fraction (OEF%), corresponding to the degree of blood desaturation between the arterial and mixed venous compartments and the amount of oxygen released at the tissue level by 100 mL of blood (OEF Vol%) were calculated from the arterial and mixed venous OEC, combined with PO2 and hemoglobin concentration. Oxygen delivery (DO2) was calculated using the arterial oxygen content, the cardiac output measured by thermodilution, and the body weight of the animal. The oxygen consumption (VO2) was derived from the cardiac output, OEF Vol% and body weight values. Despite the plasma hypochloremia, the erythrocyte chloride concentration was not influenced by furosemide and sodium bicarbonate infusion. Due to the alkalosis-induced increase in the 2,3-DPG, the standard OEC was shifted to the right, allowing oxygen to dissociate from hemoglobin more rapidly. These changes opposed the increased affinity of hemoglobin for oxygen induced by alkalosis. Moreover, respiratory acidosis, hemoconcentration, and the slight decrease in the partial oxygen pressure in mixed venous blood (Pvo2) tended to improve the OEF Vol% and maintain the oxygen consumption in a physiological range while the cardiac output, and the oxygen delivery were significantly decreased. It may be concluded that, despite reduced oxygen delivery, oxygen consumption is maintained during experimentally induced hypochloremic alkalosis in healthy 10-30 day old calves.     

Effects of electroimmobilisation on blood gas and pH status in sheep

Arterial blood gases, pH and haemoglobin concentrations were monitored for 20 minutes before, during and for 120 minutes after 60 seconds of electroimmobilisation (E-IM) at current strengths of 0 mA (control), 40 mA and 60 mA in 17 Merino ewes (36.3 +/- 1.0 kg) previously prepared with unilateral carotid artery loops. E-IM elicited whole body rigidity. During E-IM, breathing was stopped for 50 +/- 3 seconds (40 mA) and 56 +/- 2 seconds (60 mA). Arterial PO2 decreased to 43.2 +/- 2.4 mmHg (5.68 +/- 0.32 kPa) (40 mA) and 36.4 +/- 1.8 mmHg (60 mA) while arterial PCO2 rose to 59.7 +/- 1.9 mmHg (40 mA) and 69.8 +/- 2.0 mmHg (60 mA). There was a significant fall in arterial pH to 7.272 +/- 0.014 (40 mA) and 7.233 +/- 0.011 (60 mA) during E-IM and arterial haemoglobin increased by 34 +/- 3 per cent and 35 +/- 3 per cent at 40 mA and 60 mA, respectively. All the arterial blood gas and pH changes were significantly greater (P less than 0.05) during E-IM at 60 mA than at 40 mA. Multiple regression analysis indicated that the decrease in arterial PO2 during E-IM was directly related to the latency to breathe while the changes in arterial PCO2 and pH during E-IM were not.2+off     

Blood gas analyses on equine blood: required correction factors [see comment]

Correction factors have been determined to obtain the best estimates of PO2, PCO2 and pH in equine blood with standard blood gas and pH electrodes. There was a significant difference between the PO2 readings for tonometred blood of most horses and the equilibrating gas. Thus, if the PO2 electrode is calibrated with a gas, an electrode correction factor should be obtained by tonometring a blood sample from each horse. This factor was not dependent on packed cell volume. No such correction is required for the PCO2 electrode. If the animal's temperature differs from that of the analyser, the PO2, PCO2 and pH values must be corrected to the animal's body temperature. Temperature correction factors determined for equine blood were similar to those for human blood. Failure to make temperature corrections can result in errors for PO2 and PCO2 of 6 to 7 per cent per degree of temperature difference.     

Acid-base measurements of arterial, venous and capillary blood in the dog.

A method of arterial blood sampling acceptable for clinical purposes for acid-base estimations in dogs is described. A comparison of acid-base variables from fourteen canine arterial, venous and capillary blood samples revealed in most cases that venous and capillary blood samples showed unsatisfactory agreement with corresponding arterial blood samples. Two commercial automatic pH and blood-gas analysing systems are compared.     

Blood-gas and acid-base parameters in nontranquilized Arabian oryx (Oryx leucoryx) in the United Arab Emirates.

Arterial and venous blood-gas and acid-base values were established from a herd (n = 19; 14 male, 5 female) of semi-free-ranging Arabian oryx (Oryx leucoryx) in the United Arab Emirates. The animals were restrained with the use of a modified raceway incorporating a commercially available handling crate. Statistically significant differences were found between arterial and venous values for PO2 (p < 0.001), PCO2 (p = 0.0141), SO2 (p < 0.001), pH (p = 0.0494), and glucose (p < 0.0001). The results are similar to those reported for the same species under field anesthetic conditions, and to those reported from other species of wild bovidae, both tranquilized and nontranquilized, established under similar methods of restraint. In addition, Bland and Altman plots suggest adequate levels of clinical agreement between venous and arterial pH but not between arterial and venous PCO2.     

Comparison of ventral coccygeal arterial and jugular venous blood samples for pH, pCO2, HCO3, Be(ecf) and ctCO2 values in calves with pulmonary diseases

The aim of this study was to determine whether venous blood samples can be used as an alternative to arterial samples in calves with respiratory problems and healthy calves. Jugular vein and ventral coccygeal artery were used to compare blood gas values. Sampling of the jugular vein followed soon after sampling of the ventral coccygeal artery in healthy calves (group I) and calves with respiratory problems (group II). Mean values of arterial blood for pH, pCO2, HCO3act in healthy calves were 7.475 +/- 0.004, 4.84 +/- 0.2 kPa, 28.45 +/- 1.30 mmol/L compared with venous samples, 7.442 +/- 0.006, 6 +/- 0.3 kPa, 30.93 +/- 1.36 mmol/L, respectively. In group II, these parameters were 7.414 +/- 0.01, 5.93 +/- 0.3, 27.73 +/- 1.96 mmol/L for arterial blood and 7.398 +/- 0.008, 6.85 +/- 0.2 kPa, 29.77 +/- 1.91 mmol/L for venous blood, respectively. There were no statistically significant differences between arterial and venous pH, HCO3act, Be(ecf), ctCO2 values with the exception of pCO2 (P = 0.001) in group II. In group I, correlation (r2) between arterial and venous blood pH, pCO2, HCO3act were 84.5%, 87.5%, 95.7%, respectively compared with the same parameters in group II, 80.8%, 77.1%, 70.3%. In conclusion, venous blood gas values can predict arterial blood gas values of pH, pCO2 and HCO3ecf, Be(ecf) and ctCO2- for healthy calves but only pH values in calves with acute respiratory problems (r2 value>80%).     

Blood acid-base curve nomogram for immature domestic pigs

The purpose in this study was to characterize the acid-base status of arterial blood from healthy young domestic swine and to construct an acid-base curve nomogram appropriate to such animals. Accordingly, 40 immature, 20- to 31-kg domestic pigs were used to establish acid-base characteristics for arterial blood. Samples were collected from chronically implanted catheters while the animals were maintained under steady-state, near-basal conditions. At a measurement temperature of 38 C, pH averaged 7.496; PCO2, 40.6 mm Hg; [HCO3-], 31.6 mEq/L; PO2, 79.1 mm Hg; hemoglobin, 9.65 g/dl; hematocrit, 0.29; plasma albumin, 25.3 g/L; plasma globulin, 32.3 g/L; and plasma buffer base, 45.4 mEq/L. Hourly measurements over a 6-hour period in 6 of these pigs showed a small, but significant decrease in PO2 with time, but no significant change in acid-base status. The data showed that nomograms or other procedures based on blood characteristics of men were invalid when used to estimate base excess concentration of blood from young pigs. The normal pH of arterial blood was higher in immature pigs than in men; thus, reference values defining zero base excess were not equivalent in men and pigs. Constant PCO2 titrations were performed on arterial samples taken from 10 additional pigs, and the data were used to construct an acid-base curve nomogram in which zero base excess was defined for blood with a pH of 7.50 and a PCO2 of 40 mm Hg.(ABSTRACT TRUNCATED AT 250 WORDS)     

End-tidal partial pressure of CO2 as an estimate of arterial partial pressure of CO2 during various ventilatory regimens in halothane-anesthetized dogs

The correlation between end-tidal partial pressure of CO2 (PETCO2) and arterial PCO2 (PaCO2) was studied in six halothane-anesthetized dogs maintained under four different ventilatory regimens: (A) spontaneous breathing; (B) assisted positive-pressure ventilation; (C) intermittent manual inflation; and (D) ventilator-controlled breathing. For procedures A, B, and D together, there was a strong correlation between PETCO2 and PaCO2 (r = 0.8) that was highly significant at P less than 0.0001 for PETCO2 values between 31.3 and 61 mm of Hg. In spontaneous and controlled breathing, PETCO2 is representative of PaCO2 and provides a useful noninvasive tool for monitoring the patient maintained under general anesthesia. Furthermore, data suggest that any ventilatory support of the anesthetized patient markedly improves blood gas and acid-base status compared with that of the unsupported, spontaneously breathing animal.     

Xylazine and xylazine-ketamine in dogs

The cardiopulmonary consequences of IV administered xylazine (1.0 mg/kg) followed by ketamine (10 mg/kg) were evaluated in 12 dogs. Xylazine caused significant decreases in heart rate, cardiac output, left ventricular work, breathing rate, minute ventilation, physiologic dead space, oxygen transport, mixed venous partial pressure of oxygen, and oxygen concentration. It caused significant increases in systemic blood pressure, central venous pressure, systemic vascular resistance, tidal volume, and oxygen utilization ratio. The subsequent administration of ketamine was associated with significant increases in heart rate (transient increase), cardiac output, the alveolar-arterial PO2 gradient and venous admixture (transient increase), and arterial PCO2 (transient increase). It caused significant decreases in stroke volume (transient decrease), left ventricular stroke work (transient decrease), effective alveolar ventilation, arterial PO2 and oxygen content (transient decrease).     

Evaluation of laser Doppler flowmetry for measurement of capillary blood flow in the stomach wall of dogs during gastric dilatation-volvulus

OBJECTIVES: To validate laser doppler flowmetry (LDF) for measurement of blood flow in the stomach wall of dogs with gastric dilatation-volvulus (GDV). ANIMALS: Six purpose-bred dogs and 24 dogs with naturally occurring GDV. STUDY DESIGN: Experimental and clinical. METHODS: Capillary blood flow in the body of the stomach and pyloric antrum was measured with LDF (tissue perfusion unit (TPU) before and after induction of portal hypertension (PH) and after PH plus gastric ischemia (GI; PH + GI) and compared with flow measured by colored microsphere technique. Capillary flow was measured by LDF in the stomach wall of dogs with GDV. RESULTS: PH and PH+GI induced a significant reduction in blood flow in the body of the stomach (P = .019). A significant positive correlation was present between percent changes in capillary blood flow measured by LDF and colored microspheres after induction of PH + GI in the body of the stomach (r = 0.94, P = .014) and in the pyloric antrum (r = 0.95, P = .049). Capillary blood flow measured in the body of the stomach of 6 dogs that required partial gastrectomy (5.00+/-3.30 TPU) was significantly lower than in dogs that did not (28.00+/-14.40 TPU, P = .013). CONCLUSIONS: LDF can detect variations in blood flow in the stomach wall of dogs. CLINICAL RELEVANCE: LDF may have application for evaluation of stomach wall viability during surgery in dogs with GDV.     

氨氟醚吸入麻醉妊娠犬及其胎儿动脉血药浓度和血气分析

选用 10只妊娠犬 ,实施母体及胎儿股动脉血管插管后 ,测定了氨氟醚麻醉期间母犬及胎儿的动脉血药浓度和血液 p H、PO2 (动脉氧分压 )、PCO2 (动脉 CO2 分压 )、T- CO2 (血浆 CO2 总量 )、HCO- 3 (实际碳酸氢盐 )、SB(标准碳酸氢盐 )、BEb(全血碱超 )、Sat.O2 (血氧饱和度 )。结果 :氨氟醚可透过胎盘进入胎儿血液 ,胎儿血药浓度低于母犬 ,但两者上升和消除变化趋势接近 ;麻醉期间 ,母犬及胎儿血液 p H、BEb下降 (P<0 .0 1或 P<0 .0 5 ) ,PO2 、PCO2 、Sat.O2 升高(P<0 .0 1或 P<0 .0 5 ) ,HCO- 3 、T- CO2 表现升高趋势 (P>0 .0 5 ) ,SB表现下降趋势 (P>0 .0 5 )。结果表明 ,氨氟醚吸入麻醉期间 ,母犬及其胎儿呈现轻度呼吸性酸中毒和代谢性酸中毒并存 ,并随氨氟醚血药浓度的降低而逐渐恢复     

The diagnostic value of venous blood gas parameters and pH value in newborn foals with pulmonary diseases.]

Analysis of blood gases in equine neonatology is regarded as a diagnostic tool to study the neonatal adaptation period. Aim of this study therefore was to compare the diagnostic value of venous blood gas parameters to arterial parameters in newborn foals with pulmonary disorders. Venous as well as arterial blood samples were taken from 24 foals (1 to 6 days old) and the partial pressure of oxygen (pO2), partial pressure of carbon dioxide (pCO2), pH, and oxygen parturition (S-O2) of these samples were investigated. In addition, the alveolar (A) to arterial (a) gradients (A-aDO2) were calculated. Due to changes in blood gas parameters during the first week postnatal the age was taken into consideration by using covariance analysis. All arterial parameters except paCO2 showed a significant difference among healthy foals (n = 15) and foals with respiratory disorders (n = 11) with A-aDO2 and paO2 being the most reliable arterial parameters. In venous blood there was a significant difference between healthy and sick foals only in S-O2 and pH.