journal article
Download Only Collection
Home
doi: 10.1136/bjsm.10.3.109pmid: 1000155
Since procaine has both local anaesthetic and central stimulant actions its presence in the blood or urine of racing horses is forbidden. After rapid intravenous injection of procaine HC1 (2.5 mg/Kg) in thoroughbred mares plasma levels of this drug fell rapidly (t 1/2 alpha = 5 min) and then more slowly (t 1/2 beta = 50.2 min). These kinetics were well fitted by a two compartment open model (Model I). This model gave an apparent Vdbeta for procaine in the horse of about 3,500 litres. Since procaine was about 45% bound to equine plasma protein this gives a true Vdbeta for procaine of about 6,500 litres. After subcutaneous injection of procaine HC1 (3.3 mg/Kg) plasma levels peaked at about 400 ng/ml and then declined with a half-life of about 75 minutes. These data were well fitted by Model I when this was modified to include simple first order absorption (K = 0.048 min-1) from the subcutaneous injection site (Model II). After intramuscular injection of procaine penicillin (33,000 I.U./Kg) plasma levels reached a peak at about 270 ng/ml and then declined with a half-life of about 9 hours. These data were approximately fitted by Model II assuming a first order rate constant for absorption of procaine of 0.0024 min-1. After intramuscular injection of procaine HC1 (10 mg/Kg) plasma levels of procaine peaked rapidly at about 600 ng/ml but thereafter declined slowly (+ 1/2 = 2 hours). A satisfactory pharmaco-kinetic model for this intramuscular data could not be developed. An approximation of these data was obtained by assuming the existence of two intramuscular drug compartments, one containing readily absorbable drug and the other poorly absorbable drug (Model III). After intra-articular administration of procaine (0.33 mg/Kg) plasma levels of this drug reached a peak at about 17 ng/ml and then declined with a half-life of about 2 hours. These data were not modelled.
doi: 10.1136/bjsm.10.3.116pmid: 11864
It is well known that nikethamide (N,N-diethylnicotinamide, CoramineR) is metabolized very rapidly to nicotinamide. Hence, there is difficulty in proving that nikethamide has been used as a doping substance because nicotinamide is a normal physiological metabolite in the organism as well as a vitamin preparation. However, an intermediate metabolite (N-ethylnicotinamide) was found by us in the urine of horses treated with CoramineR. This was characterized by gas chromatography/mass spectrometry, and synthesized and identified as being N-ethylnicotinamide. The excretion and metabolism of nikethamide after intramuscular injection in the horse was followed using quantitative gas chromatography of urine extracts over a period of several hours and the results of these experiments are reported. Changes in urinary pH had no significant effect upon either the metabolism or rate of excretion of the drug.
Evans, J. A.; Lambert, M. B.; Miller, J.
doi: 10.1136/bjsm.10.3.124pmid: 1000156
The anti-inflammatory drug Ibuprofen [(+/-)-2-(p-isobutylphenyl) propionic acid] was estimated in the blood and urine of a horse using gas-liquid chromatography of the silylated derivative. Levels of the drug in the two body fluids were measured over a period of about 24 hours after administering a 12 gm dose of Ibuprofen. Plasma peak levels were observed within 30 to 60 min, and the drug was no longer detectable in the plasma by 8 hr. Urinary peak levels were observed 200 to 300 min after dosing, and the drug was no longer detectable in the urine by about 28 hr. It was observed that only 2% to 6% of the free unchanged drug was excreted in the urine.
Showing 1 to 10 of 37 Articles