Anticoagulant profile of subcutaneous enoxaparin in healthy dogs.

Our study objective was to identify a subcutaneous enoxaparin dosage that provided a consistent anticoagulant intensity in dogs. Our hypotheses were that a dose of 0.8 mg/kg would provide inconsistent anticoagulation, a higher dose would provide consistent anticoagulation over a greater duration of time, and viscoelastometry would effectively monitor the anticoagulant status. Six healthy dogs received two subcutaneous enoxaparin doses (0.8 and 2 mg/kg) for anti-Xa activity determinations and pharmacokinetic modeling. Based on calculations derived from these results, 1.3 mg/kg, SC, q8 h was administered for seven doses. Target ranges for anticoagulant intensity were defined as anti-Xa activity of 0.5-1 U/ml, and change from baseline of two viscoelastometric parameters: activated clotting time (ΔACT; ≥40 s), and clot rate (CRpost; ≤20 U/min). Following an initial injection at 1.3 mg/kg, anti-Xa activity of 5/6 dogs reached or exceeded the target range. Following the final dose, anti-Xa activity reached or exceeded the target range in all dogs, and ΔACT and CRpost values exceeded target for 2-6 and 4-12 h, respectively. At an enoxaparin dosage of 1.3 mg/kg, SC, q8 h, anti-Xa activity was consistently above the minimum threshold of the target range; however, the safety of this dosage remains to be determined.

Pharmacokinetics of clindamycin administered orally to pigeons.

To determine the plasma concentration of clindamycin in pigeons after oral administration, 12 rock pigeons (Columba livia) were used in a 2-phase study. In the first phase, 8 pigeons received clindamycin by gavage at 100 mg/kg as a single dose. Blood samples were collected at 0, 0.25, 0.5, 1, 2, 3, 4, and 6 hours, and the plasma was separated, frozen, and subsequently analyzed by liquid chromatography-mass spectrometry for clindamycin and its active metabolites, N-demethylclindamycin (NCLD) and clindamycin sulfoxide. Clindamycin was rapidly absorbed with plasma concentrations peaking at 0.5 hours at 1.43 microg/mL. The terminal half-life (t(1/2)) was 1.25 hours, and the mean residence time was 2.49 hours. N-demethylclindamycin was detected in 7 of 8 birds (88%), whereas clindamycin sulfoxide was not found in any samples. In phase 2, clindamycin was administered to 3 birds by gavage at 100 mg/ kg q6h for 5 doses. Mean peak plasma concentrations were 2.46 and 0.64 microg/mL, with trough concentrations of 0.11 and 0.44 microg/mL for clindamycin and NCLD, respectively. No adverse effects were observed in any birds. Based on an additive antimicrobial effect of NCLD with clindamycin, an oral dosage of 100 mg/kg q6h in pigeons should reach effective plasma concentrations against common susceptible pathogens. If dose proportionality exists, lower doses and longer intervals likely produce subtherapeutic concentrations to treat systemic infections. How well birds would tolerate an extended oral dose regimen, how frequently birds fail to produce the active metabolite critical for an additive effect, and the application of these results to other avian species require further study.

Postexposure management and treatment of anthrax in dogs--executive councils of the American Academy of Veterinary Pharmacology and Therapeutics and the American College of Veterinary Clinical Pharmacology.

Dogs are generally at low risk of developing disease following exposure to anthrax. When disease does occur, it appears associated with oral exposure to the bacteria leading to massive swelling of the head, neck, and mediastinal regions. Death is due to toxemia and shock. For animals at high risk, such as search and rescue dogs with a known exposure, doxycycline at 5 mg/kg orally once daily for 45 to 60 days is suggested as a prophylactic treatment. Additional information on the diagnosis, prevention, and treatment of the disease in dogs is presented.

Relationship between red blood cell thiopurine methyltransferase activity and myelotoxicity in dogs receiving azathioprine.

Thiopurine methyltransferase (TPMT) produces inactive metabolites of azathioprine and, in humans, has a variable amount of activity. Humans with low TPMT activity commonly develop myelotoxicity when receiving azathioprine. Our study sought to characterize the distribution of TPMT activity in a population of dogs and to determine whether the pretreatment knowledge of red blood cell (RBC) TPMT activity could predict myelotoxicity in dogs receiving azathioprine. RBC TPMT activity was measured in 299 healthy dogs, and 9 dogs that represented a wide range of enzyme activity received azathioprine at a standard therapeutic dose for 30 days. TPMT activity in healthy dogs was log normally distributed and varied over an approximately 7-fold range. Geometric mean, minimum, and maximum RBC TPMT activities were 37.1, 16.3, and 115 nmol per gram of hemoglobin (gHb) per hour, respectively. TPMT deficiency was not identified. Two populations of TPMT activity in dogs were detected by statistical modeling (commingling analysis). Dogs with intermediate TPMT activity (14-38 nmol/gHb/h) receiving azathioprine had significantly lower neutrophil counts during week 4 than during weeks 0-3, whereas those with high activity (>39 nmol/gHb/h) did not have a significant change in neutrophil count. An analysis of TPMT activity in 6 dogs with a history of azathioprine-associated myelotoxicity in a clinical setting revealed either intermediate or high TPMT enzyme activity in all dogs, suggesting that TPMT activity, as measured in RBCs, is not the sole cause of severe azathioprine-associated myelosuppression in dogs.

The role of the clinical pharmacologist in animal health.

Like most scientific disciplines, pharmacology is replete with subspecialties. Certainly most scientists recognize the value of animal studies in drug development for human pharmaceuticals. However, animals as the target species also represent a major focus of investigation. According to recent estimates, in the United States for the year 2000, 98.1 million cattle, 59.8 million pigs, and 1.5 billion chickens existed. Added to that estimate were companion animals, including 4 million horses, 59 million cats, and 52.9 million dogs. The estimate does not include the so-called "minor" species, such as 7 million sheep and 320,000 acres of freshwater fish production. In most respects, the medical needs of these animals are addressed in a manner parallel to that of human medicine. One such parallel, with certain distinct differences from its human counterpart, is veterinary clinical pharmacology.