Ten foals of various breeds were deprived of colostrum from birth to 36 hours of age, then were allotted to 2 groups. Foals of group 1 (n = 6) were given 20 g (200 ml) of purified equine IgG IV in a 10% solution, and foals of group 2 (n = 4) were given 30 g (300 ml) of the same preparation. Total administration time for each 10 g of IgG in 100 ml was approximately 10 minutes. Serum IgG concentration in foals was assessed prior to, between 24 and 48 hours, and at 7 and 14 days after IgG administration. Between 24 and 48 hours after IgG administration, mean serum IgG concentration in group-1 foals was 425 mg/dl (range, 350 to 480 mg/dl). Mean body weight for this group of foals was 50.3 kg (range, 43.3 to 54.7 kg). For group-2 foals, mean serum IgG concentration was 768 mg/dl (range, 640 to 920 mg/dl) between 24 and 48 hours after administration of IgG. Foals of this group had mean body weight of 43.2 kg (range, 36.5 to 47.5 kg). Serum IgG concentration in group-2 foals at 24 to 48 hours was significantly (P = 0.005) greater than that in group-1 foals. Mean total IgG recovery at 24 to 48 hours, calculated on the basis of 94.5 ml of plasma volume/kg of body weight, was approximately 100%. Values of IgG measured in all foals 1 and 2 weeks after administration of the IgG concentrate were equivalent to values expected after normal decay of passively acquired IgG. Mild, adverse reactions occurred in 3 of the treated (1 group-1 foal and 2 group-2 foals).

The effects of single IV injections of sodium bicarbonate (0.5 mEq/kg of body weight, 1 mEq/kg, 2 mEq/kg, and 4 mEq/kg) on serum osmolality, serum sodium, chloride, and potassium concentrations, and venous blood gas tensions in 6 healthy cats were monitored for 180 minutes. Serum osmolality increased and remained significantly (P less than 0.05) increased for 120 minutes in cats given 4 mEq of sodium bicarbonate/kg. Serum sodium was increased significantly (P less than 0.05) for 30 minutes in cats given 4 mEq of sodium bicarbonate/kg. Serum sodium decreased and remained significantly (P less than 0.05) decreased for 120 minutes in cats given 1 g of 20% mannitol/kg, and serum osmolality was significantly (P less than 0.05) decreased at 30 and 60 minutes. Serum chloride decreased significantly (P less than 0.05) for 10 minutes in cats given 1 mEq of sodium bicarbonate/kg, and was significantly decreased for 30 minutes in cats given 2 mEq and 4 mEq of sodium bicarbonate/kg. Serum chloride decreased and remained significantly (P less than 0.05) decreased for 30 minutes in cats given 1 g of 20% mannitol/kg. Serum sodium and serum osmolality did not change significantly (P less than 0.05) in cats given 4 ml of 0.9% sodium chloride/kg. Serum potassium decreased significantly (P less than 0.05) for 10 minutes in cats given 1 mEq of sodium bicarbonate/kg, and for 120 minutes in cats given 2 mEq/kg or 4 mEq/kg. There was a significantly (P less than 0.05) greater decrease in serum potassium that lasted for 30 minutes after giving sodium bicarbonate at the dosage of 4 mEq/kg, compared with other dosages given. Serum potassium did not change significantly in cats given 1 g of 20% mannitol/kg, but was significantly (P less than 0.05) decreased 10 minutes following 4 ml of 0.9% sodium chloride/kg. Sodium bicarbonate infusion significantly (P less than 0.05) increased venous blood pH and plasma bicarbonate concentration in all cats. The magnitude and duration of these changes were significantly greater following administration of sodium bicarbonate at dosages of 2 mEq/kg and 4 mEq/kg. Significant (P less than 0.05) increases in PCO2 were associated only with the highest dosage of sodium bicarbonate (4 mEq/kg). Base excess increased significantly (P less than 0.05) in all cats following sodium bicarbonate infusion. There were significantly (P less than 0.05) greater increases in base excess lasting 30 minutes following administration of sodium bicarbonate at dosages of 2 mEq/kg and 4 mEq/kg. Significant (P less than 0.05) changes in venous blood pH, PCO2, or bicarbonate were not observed in cats given 4 ml of 0.9% sodium chloride/kg, or in cats given 1 g of 20% mannitol/kg. Base excess was significantly (P less than 0.05) increased for 10 minutes in cats given 1 g of 20% mannitol/kg. As expected, 4 mEq of sodium bicarbonate/kg induced the most time- and dosage-related effects. Caution should be used when administering sodium bicarbonate IV to cats at dosages greater than 2 mEq/kg, because of the potential for important acid-base and electrolyte changes.

The effect of age on the pharmacokinetics of chloramphenicol was determined after IV administration of chloramphenicol sodium succinate (25 mg/kg of body weight) to 6 foals at 1 day and 3, 7, 14, and 42 days of age. The disposition of chloramphenicol was best described, using a two-compartment open model in all foals at all ages evaluated. Significant age-related changes were observed in values for the major kinetic terms describing the disposition of chloramphenicol in foals; the greatest changes were observed between 1 day and 3 days of age. The mean +/- SD value for elimination rate constant (beta) for chloramphenicol in 1-day-old foals (0.131 +/- 0.06 h-1) was significantly (P < 0.005) lower than the value in 3-day-old foals (0.514 +/- 0.156 h-1), and both values were significantly (P < 0.005) lower than values for beta in 7-, 14-, and 42-day-old foals. With increasing age, the increase in the mean value for beta resulted in decrease in the harmonic mean elimination half-time (t1/2 beta) for chloramphenicol, from 5.29 hours in 1-day-old foals to: 1.35 hours in 3-day-old foals; 0.61 hour in 7-day-old foals; 0.51 hour in 14-day-old foals; and 0.34 hour in 42-day-old foals. At 1, 3, and 7 days of age, values for t1/2 beta of chloramphenicol in a premature foal born after parturition was induced with oxytocin, were considerably longer than comparable t1/2 beta values for term foals born naturally. The mean body clearance (ClB) of chloramphenicol in 1-day-old foals (2.25 +/- 0.67 ml/min.kg of body weight) was significantly lower than values in: 3-day-old (6.23 +/- 2.22 ml/min.kg; P < 0.05); 7-day-old (8.86 +/- 1.90 ml/min.kg; P < 0.0005); 14-day-old (9.63 +/- 1.63 ml/min.kg; P < 0.0005); and 42-day-old (9.68 +/- 2.76 ml/min.kg; P < 0.0001) foals. In foals of all ages, ClB of chloramphenicol in the parturition-induced premature foal was lower than the mean value for term foals born naturally. The volume of distribution (V'd[area]) of chloramphenicol decreased progressively with increasing age between day 1 and day 42, so that the mean value for 42-day-old foals (362 +/- 163 ml/kg) was less than a third the mean value for 1-day-old foals (1,101 +/- 284 ml/kg). The mean value for V'd(area) in 1-day-old foals was significantly greater than values for: 7-day-old (491 +/- 158 ml/kg; P < 0.01); 14-day-old (426 +/- 65 ml/kg; P < 0.005); and 42-day-old (362 +/- 162; P < 0.0005) foals, and the mean value for V'd(area) on day 3 was significantly (P < 0.05) greater than the mean value for V'd(area) on days 7, 14, and 42. Using dosage calculations based on mean values for the pharmacokinetic terms derived for each age group, it was predicted that to maintain plasma chloramphenicol concentration > 8 microgram/ml, chloramphenicol sodium succinate (25 mg/kg) would have to be administered at dose intervals of 10, 3, 1.5, 1.5, and 1 hours in clinically normal foals 1 day and 3, 7, 14, and 42 days, of age, respectively. It was concluded that the marked changes in the disposition of chloramphenicol detectable during the first few days of life, the variation between individuals, the potentially major effect of prematurity, and the potential for compromised liver function in septicemic foals indicate that use of drugs, such as chloramphenicol, which rely heavily on hepatic metabolic processes for elimination, should be avoided whenever possible during the early neonatal period, unless plasma concentration is monitored.

The pharmacokinetic properties of the fluoroquinolone antimicrobial enrofloxacin were studied in New Zealand White rabbits. Four rabbits were each given enrofloxacin as a single 5 mg/kg of body weight dosage by IV, SC, and oral routes over 4 weeks. Serum antimicrobial concentrations were determined for 24 hours after dosing. Compartmental modeling of the IV administration indicated that a 2-compartment open model best described the disposition of enrofloxacin in rabbits. Serum enrofloxacin concentrations after sc and oral dosing were best described by a 1- and 2-compartment model, respectively. Overall elimination half-lives for IV, SC, and oral routes of administration were 2.5, 1.71, and 2.41 hours, respectively. The half-life of absorption for oral dosing was 26 times the half-life of absorption after sc dosing (7.73 hours vs 0.3 hour). The observed time to maximal serum concentration was 0.9 hour after sc dosing and 2.3 hours after oral administration. The observed serum concentrations at these times were 2.07 and 0.452 microgram/ml, respectively. Mean residence times were 1.55 hours for IV injections, 1.46 hours for sc dosing, and 8.46 hours for oral administration. Enrofloxacin was widely distributed in the rabbit as suggested by the volume of distribution value of 2.12 L/kg calculated from the IV study. The volume of distribution at steady-state was estimated at 0.93 L/kg. Compared with IV administration, bioavailability was 77% after sc dosing and 61% for gastrointestinal absorption. Estimates of predicted average steady-state serum concentrations were 0.359, 0.254, and 0.226 microgram/ml for IV, sc, and oral administration, respectively. On the basis of maintaining enrofloxacin serum concentrations at 4 times the minimal inhibitory concentration for Pasteurella multocida, oral dosing resulted in the longest maximal time interval between doses of 15.4 hours vs 9.9 hours and 7.4 hours for IV and SC injections, respectively. Because enrofloxacin is widely dispersed in the rabbit's body, it is estimated from the data in this study that in vivo inhibitory concentrations of enrofloxacin for Pasteurella multocida may be maintained at oral dosage regimens equivalent to 5 mg/kg (q 12 h).

The cardiovascular effects of xylazine and detomidine in horses were studied. Six horses were Liven each of the following 5 treatments, at 1-week intervals: xylazine, 1.1 mg/kg, IV; xylazine, 2.2 mg/kg, IM; detomidine, 0.01 mg/kg, IV; detomidine, 0.02 mg/kg, IV; and detomidine, 0.04 mg/kg, IM. All treatments resulted in significantly decreased heart rate, increased incidence of atrioventricular block, and decreased cardiac output and cardiac index; cardiac output and cardiac index were lowest following IV administration of 0.02 mg of detomidine/kg. Mean arterial pressure was significantly reduced for various periods with all treatments; however, IV administration of 0.02 mg of detomidine/kg caused hypertension initially. Systemic vascular resistance was increased by all treatments. Indices of ventricular contractility and relaxation, + dP/dt and - dP/dt, were significantly depressed by all treatments. Significant changes were not detected in stroke volume or ejection fraction. The PCV was significantly reduced by all treatments. Respiratory rate was significantly decreased with all treatments, but arterial carbon dioxide tension did not change. Arterial oxygen tension was significantly decreased briefly with the 3 IV treatments only.

Pharmacokinetic determinants of spiramycin and its distribution into the respiratory tract were studied in 2 groups of calves, 4 to 10 weeks old. Group-A calves (n = 4) were used to determine pharmacokinetic variables of spiramycin after IV (15 and 30 mg/kg of body weight) and oral administrations of the drug (30 mg/kg) and to measure distribution of spiramycin into nasal and bronchial secretions. Group-B calves (n = 4) were used to determine distribution of spiramycin into lung tissue and bronchial mucosa. Spiramycin disposition was best described by use of an open 3-compartment model. Mean (+/- SD) elimination half-life was 28.7 +/- 12.3 hours, and steady-state volume of distribution was 23.5 +/- 6.0 L/kg. Bioavailability after oral administration was 4 +/- 3%. High and persistent concentrations of spiramycin were achieved in the respiratory tract tissues and fluids. Tissue-to-plasma concentration ratio was 58 for lung tissue and 18 for bronchial mucosa at 3 hours after spiramycin administration and 137 and 49, respectively at 24 hours. Secretion-toplasma concentration ratio was 4 for nasal secretions and 7 for bronchial secretions, and remained almost constant with time. Thus, spiramycin penetrates well into the respiratory tract, although the value in bronchial secretions is lower than that in lung tissues and bronchial mucosa. Calculations indicate that a loading dose of 45 mg/kg, administered IV, followed by a maintenance dose of 20 mg/kg, IV, once daily is required to maintain active concentrations of spiramycin against bovine pathogens in bronchial secretions.