Hemodynamic effects of spontaneous ventilation, intermittent positive-pressure ventilation (IPPV), and high-frequency oscillatory ventilation (HFOV) were compared in 6 dogs during halothane anesthesia. Anesthesia was induced with IV thiamylal Na and was maintained with halothane (end-tidal concentration, 1.09%). During placement of catheters, dogs breathed spontaneously through a conventional semiclosed anesthesia circuit. Data were collected, and dogs were mechanically ventilated, using IPPV or HFOV in random order. Ventilation was adjusted to maintain PaCO2 between 38 and 43 mm of Hg during IPPV and HFOV. Cardiac index, aortic blood pressure, and maximum rate of increase of left ventricular pressure were significantly (P less than 0.05) less during HFOV than during spontaneous ventilation, whereas right atrial and pulmonary artery pressure were significantly greater during HFOV than during spontaneous ventilation. During IPPV, only the maximum rate of increase of left ventricular pressure was significantly less than that during spontaneous ventilation.

Nintey nonanesthetized 7- to 16-week-old pigs were studied, using 2-dimensional echocardiography that permits orientation of a targeted M-mode beam perpendicular to structures being studied and allows serial studies of the same cardiac regions. Normative data were obtained and included body weight and measurements of left atrial diameter, mitral valve excursion, aortic root diameter, left ventricular end-diastolic and end-systolic diameters, and left ventricular fractional shortening. A positive correlation was found between body weight and measurements of left atrial diameter, mitral valve excursion, aortic root diameter, left ventricular end-diastolic and end-systolic diameters, and fractional shortening. A correlation was found between body weight and age. Best-fit analysis resulted in all measurements fitting either a first- or second-degree polynomial.

To differentiate the origin of high total lactate dehydrogenase (LD) activity in canine sera, a spectrophotometric method based on the preferential inhibition of cardiac LD isoenzymes by pyruvate was performed. Comparison with the electrophoretic separation of LD isoenzyme activities and determination of the hydroxybutyrate dehydrogenase-to-LD ratio indicated that the method proposed gave a better discrimination between cardiac and hepatic LD activities than did the other tests.

Oxymorphone was administered IV to dogs 4 times at 20-minute intervals (total dosage, 1 mg/kg of body weight, IV) on 2 separate occasions. Minute ventilation, mixed-expired carbon dioxide concentration, arterial and mixed-venous pH and blood gas tensions, arterial, central venous, pulmonary arterial, and pulmonary wedge pressures, and cardiac output were measured. Physiologic dead space, base deficit, oxygen transport, and vascular resistance were calculated before and at 5 minutes after the first dose of oxymorphone (0.4 mg/kg) and at 15 minutes after the first and the 3 subsequent doses of oxymorphone (0.2 mg/kg). During 1 of the 2 experiments in each dog, naloxone was administered 20 minutes after the last dose of oxymorphone; during the alternate experiment, naloxone was not administered. In 5 dogs, naloxone was administered IV in titrated dosages (0.005 mg/kg) at 1-minute intervals until the dogs were able to maintain sternal recumbency, and in the other 5 dogs, naloxone was administered IM as a single dose (0.04 mg/kg). Naloxone (0.01 mg/kg, IV or 0.04 mg/kg, IM) transiently reversed most of the effects of oxymorphone. Within 20 to 40 minutes after IV naloxone administration and within 40 to 70 minutes after IM naloxone administration, most variables returned to the approximate values measured before naloxone administration. The effects of oxymorphone outlasted the effects of naloxone; cardiovascular and pulmonary depression and sedation recurred in all dogs. Four hours and 20 minutes after the last dose of oxymorphone, alertness, responsiveness, and coordination improved in all dogs after IM administration of naloxone. Cardiac arrhythmia, hypertension, or excitement was not observed after naloxone administration.

Eight bovine hearts with lesions of eosinophilic myositis (EM) and 2 bovine hearts without EM lesions were collected at slaughter. Blood samples from these 10 hearts, and the heart of a newborn calf also were collected. Histologically, Sarcocystis cruzi was identified in the 8 hearts with EM lesions and the 2 hearts without EM lesions, but not in the heart of the newborn calf. Serum was harvested from the 10 blood samples and was used in homologous, modified, passive cutaneous anaphylaxis test. Antigen was prepared from S cruzi bradyzoites isolated from the 2 hearts without EM lesions. Serum samples from the 8 cattle with EM lesions reacted positively to S cruzi antigen. When heat-inactivated IgE in serum (56 C for 4 hours) was used, all passive cutaneous anaphylaxis responses were considered negative. Using ELISA, serum IgE concentrations from the 10 cattle with and without EM lesions were 2.2 to 9 U/ml. As determined by radial immunodiffusion, IgM concentrations were 80 to 215 mg/dl. Immunoglobulin G concentrations were 420 to 2,050 mg/dl, but most were less than or equal to 1,700 mg/dl. Immunoglobin A concentrations were 0 to 62 mg/dl; 1 steer with EM lesions had 0 mg/dl. Double-gel immunodiffusion confirmed the presence of Sarcocystis-specific precipitating antibodies. Sera from the 10 cattle with and without EM lesions formed at least 1 precipitin band.

Cardiopulmonary function was measured in 6 conscious dogs with progressive degrees of induced pneumothorax. Minute volume, respiratory rate, central venous pressure, systemic arterial pressure, pulmonary arterial pressure, pulmonary arterial occlusion pressure, heart rate, cardiac output, and arterial and mixed venous blood gases were determined before pneumothorax and at progressive volumes of pneumothorax equivalent to 50, 100, and 150% of the calculated lung volume. Tidal volume, pulmonary vascular resistance, alveolar to arterial O2 tension difference, physiologic dead space fraction, and pulmonary venous admixture also were calculated. Linear increases in respiratory rate, central venous pressure, alveolar to arterial O2 tension difference, and pulmonary venous admixture differed significantly (P less than 0.05). Linear decreases in tidal volume, (. . .), pHa, (. . .), and Pa(O2) were also significantly different. Quadratic increases were significantly different for pulmonary arterial pressure and pulmonary vascular resistance. Trends were not significantly different for other values.

The Langendorff isolated heart preparation was adapted to determine the effect of furazolidone (0.5 and 2 migrogram/ml of perfusate) on hearts of 3-week-old broiler chickens. Following 115 minutes of perfusion, both concentrations of furazolidone caused approximately a two-fold increase in myocardial vascular resistance and a six-fold increase in myocardial vascular resistance and a six-fold increase in lactate dehydrogenase release into the effluent fluid, compared with a control perfused group of isolated hearts (P less than 0.01). Ultrastructural alteration differences were not found between the drug-treated and control groups. It was concluded that: (i) furazolidone, at concentrations only moderately above therapeutic plasma concentrations, caused detrimental changes in myocardial vascular resistance and lactate dehydrogenase release and (ii) the isolated chicken heart preparation is an example of a cost-effective, reliable laboratory tool for screening potential cardiotoxins.