Liposome-based diclofenac for the treatment of inflammation in an acute synovitis model in horses.

Lameness as a result of joint disease is a major source of decreased athletic performance in the horse. Most treatment protocols include the administration of nonsteroidal anti-inflammatory drugs (NSAIDs). Phenylbutazone, alone or in combination with other treatments, is the most commonly and widely used NSAID, however it has the potential for serious side effects. The introduction of the liposome-based formulation of the NSAID diclofenac has shown promising effect as a safe and convenient treatment for lameness associated with osteoarthritis. The purpose of this study was to evaluate the effect of topical liposome-based diclofenac in an acute inflammation model using subjective lameness scores and objective lameness evaluation, carpal surface temperature and circumference, synovial fluid cell count and total protein content, and the biochemical markers interleukin-1 (IL-1), IL-6, and prostaglandin E(2) as determinants of inflammation. In this acute inflammation model, there was no overall difference between treatment and control groups.

Characterization of urinary metabolites of testosterone, methyltestosterone, mibolerone and boldebone in greyhound dogs.

Androgenic steroids are used in female greyhound dogs to prevent the onset of estrus; moreover, these steroids also have potent anabolic activity. As anabolic steroids increase muscle mass and aggression in animals, the excessive use of these agents in racing greyhounds gives an unfair performance advantage to treated dogs. The biotransformation of most anabolic steroids has not been determined in greyhound dogs. The objective of the present study was to identify the urinary metabolites of testosterone, methyltestosterone, mibolerone, and boldenone in greyhound dogs. These steroids were administered orally (1 mg/kg) to either male or female greyhound dogs and urine samples were collected pre-administration and at 2, 4, 8, 12, 24, 72, and 96 h post-administration. Urine extracts were analyzed by high-performance liquid chromatography/mass spectrometry (HPLC/MS) to identify major metabolites and to determine their urinary excretion profiles. Major urinary metabolites, primarily glucuronide, conjugated and free, were detected for the selected steroids. Sulfate conjugation did not appear to be a major pathway for steroid metabolism and excretion in the greyhound dog. Phase I biotransformation was also evaluated using greyhound dog liver microsomes from untreated dogs. The identification of several in vivo steroid metabolites generated in this study will be useful in detecting these steroids in urine samples submitted for drug screening.

Development of analytical methods for the detection of metaraminol in the horse.

Aramine (metaraminol bitartrate) has been found in the possession of horse trainers and veterinarians who have been investigated for possible inappropriate drug administration to racing horses. Metaraminol (3-hydroxyphenylisopropanolamine) is a sympathomimetic amine that directly and indirectly affects adrenergic receptors, with alpha effects being predominant. Because it has the potential to affect the performance of a racing horse, its use is prohibited. In the present study, methods for the detection of metaraminol were developed. Metaraminol was found to be extracted with poor recovery (< 50%) from aqueous solutions by routine basic extraction or cation exchange/reversed-phase solid-phase extraction techniques. However, an extractive acetylation method gave good (> 90%) recovery of metaraminol from aqueous samples. Sequential urine samples collected from horses administered metaraminol intramuscularly at 0.02, 0.10, and 0.23 mg/kg were extracted by the developed extractive acetylation procedure and analyzed by gas chromatography-mass spectrometry (GC-MS) in full-scan and selected ion monitoring modes. Norphenylephrine was used as an internal standard for quantitative analysis. The maximum concentration of metaraminol occurred between 1 and 2 h postadministration. Metaraminol was detected in the 0.23 mg/kg administration urine for 24 h postadministration. Metaraminol was detected for the 0.10 and 0.02 mg/kg doses for approximately 8 h postadministration. No apparent biotransformation products were observed in a reaction mixture of metaraminol and horse liver microsomal reaction mixture. Comparison of gas chromatograms of the extracts of the postadministration urine samples with those of the pre-administration samples failed to reveal any exogenous compound other than metaraminol.

Effects of temperature, incubation period and substrate on production of fusaproliferin by Fusarium subglutinans ITEM 2404.

The kinetics of the production of fusaproliferin by Fusarium subglutinans ITEM 2404 in maize and rice cultures was investigated at various incubation temperatures. The growth rate of F. subglutinans was highest at 20 degrees C and 25 degrees C in maize cultures and at 15 degrees C in rice cultures. Although the growth rate was higher in rice than in maize, the maximal production of fusaproliferin was obtained in maize cultures, with a maximum yield (4309 microg g(-1)) at 20 degrees C for 6 weeks. In rice cultures the optimal incubation regimen was at 15 degrees C for 6 weeks, with a fusaproliferin level of 1557 microg g(-1). The production of fusaproliferin at 25 degrees C and 30 degrees C in both substrates was very low, with maximal yield at 25 degrees C of 979 microg g(-1) after 2 weeks and 143 microg g(-1) after 3 weeks in maize and rice cultures, respectively.

Detection of flunixin in greyhound urine by a kinetic enzyme-linked immunosorbent assay.

A two-step kinetic enzyme-linked immunosorbent assay was developed to detect the presence of flunixin in the urine of greyhound dogs. The assay system was developed using polyclonal antiflunixin antisera, a rabbit albumin-flunixin conjugate adsorbed onto polystyrene microtiter strips, and flunixin reference standards for calibration. The assay parameters were optimized and the performance characteristics were determined. The quantitative intra- and inter-run precisions (%CV) of the analysis of replicate (n = 10) flunixin-spiked urine samples were 9.9-12.5% and 10.2-13.6%, respectively. The linear dynamic range was 1-100 ng/mL, and the quantitative accuracy, as determined by calculation of percent error of measured flunixin in flunixin-spiked drug-free greyhound urine, was -16% to +14% over this range. The I50 of the ELISA was 17.3 ng/mL. The limit of detection was 25 ng/mL in greyhound urine. The reactivity in the assay system relative to flunixin (100%) was 147% for flunixin glucuronide, 25% for clonixin, and 5% for niflumic acid. The ELISA was capable of detecting total flunixin for up to 72 h in dogs administered flunixin at 0.55 mg/kg orally and up to 96 h in a dog that was administered flunixin at 1.0 mg/kg orally.