Metabolism,pharmacokinetics and selected pharmacodynamic effects of codeine following a single oral administration to horses

ObjectiveTo describe the pharmacokinetics and selected pharmacodynamic variables of codeine and its metabolites in Thoroughbred horses following a single oral administration.Study designProspective experimental study.AnimalsA total of 12 Thoroughbred horses, nine geldings and three mares, aged 4–8 years.MethodsHorses were administered codeine (0.6 mg kg^–1) orally and blood was collected before administration and at various times until 120 hours post administration. Plasma and urine samples were collected and analyzed for codeine and its metabolites by liquid chromatography–mass spectrometry, and plasma pharmacokinetics were determined. Heart rate and rhythm, step counts, packed cell volume and total plasma protein were measured before and 4 hours after administration.ResultsCodeine was rapidly converted to the metabolites norcodeine, codeine-6-glucuronide (C6G), morphine, morphine-3-glucuronide (M3G) and morphine-6-glucuronide (M6G). Plasma codeine concentrations were best represented using a two-compartment model. The C_max, t_max and elimination t_½ were 270.7 ± 136.0 ng mL^–1, 0.438 ± 0.156 hours and 2.00 ± 0.534 hours, respectively. M3G was the main metabolite detected (C_max 492.7 ± 35.5 ng mL^–1), followed by C6G (C_max 96.1 ± 33.8 ng mL^–1) and M6G (C_max 22.3 ± 4.96 ng mL^–1). Morphine and norcodeine were the least abundant metabolites with C_max of 3.17 ± 0.95 and 1.42 ± 0.79 ng mL^–1, respectively. No significant adverse or excitatory effects were observed.Conclusions and clinical relevanceFollowing oral administration, codeine is rapidly metabolized to morphine, M3G, M6G, C6G and norcodeine in horses. Plasma concentrations of M6G, a presumed active metabolite of morphine, were comparable to concentrations reported previously following administration of an analgesic dose of morphine to horses. Codeine was well tolerated based on pharmacodynamic variables and behavioral observations.     

Plasma and synovial fluid pharmacokinetics of a single intravenous dose of meropenem in adult horses

The objective of this study was to determine the pharmacokinetics of meropenem in horses after intravenous (IV) administration. A single IV dose of meropenem was administered to six adult horses at 10 mg/kg. Plasma and synovial fluid samples were collected for 6 hr following administration. Meropenem concentrations were determined by bioassay. Plasma and synovial fluid data were analyzed by compartmental and noncompartmental pharmacokinetic methods. Mean ± SD values for elimination half‐life, volume of distribution at steady‐state, and clearance after IV administration for plasma samples were 0.78 ± 0.176 hr, 136.1 ± 19.69 ml/kg, and 165.2 ± 29.72 ml hr^‐1 kg^?1, respectively. Meropenem in synovial fluid had a slower elimination than plasma with a terminal half‐life of 2.4 ± 1.16 hr. Plasma protein binding was estimated at 11%. Based on a 3‐compartment open pharmacokinetic model of simultaneously fit plasma and synovial fluid, dosage simulations were performed. An intermittent dosage of meropenem at 5 mg/kg IV every 8 hr or a constant rate IV infusion at 0.5 mg/kg per hour should maintain adequate time above the MIC target of 1 μg/ml. Carbapenems are antibiotics of last resort in humans and should only be used in horses when no other antimicrobial would likely be effective.     

Pharmacokinetics of amikacin in plasma and selected body fluids of healthy horses after a single intravenous dose

Reasons for performing study: No studies have determined the pharmacokinetics of low‐dose amikacin in the mature horse. Objectives: To determine if a single i.v. dose of amikacin (10 mg/kg bwt) will reach therapeutic concentrations in plasma, synovial, peritoneal and interstitial fluid of mature horses (n = 6). Methods: Drug concentrations of amikacin were measured across time in mature horses (n = 6); plasma, synovial, peritoneal and interstitial fluid were collected after a single i.v. dose of amikacin (10 mg/kg bwt). Results: The mean ± s.d. of selected parameters were: extrapolated plasma concentration of amikacin at time zero 144 ± 21.8 µg/ml; extrapolated plasma concentration for the elimination phase 67.8 ± 7.44 µg/ml, area under the curve 139 ± 34.0 µg*h/ml, elimination half‐life 1.34 ± 0.408 h, total body clearance 1.25 ± 0.281 ml/min/kg bwt; and mean residence time (MRT) 1.81 ± 0.561 h. At 24 h, the plasma concentration of amikacin for all horses was below the minimum detectable concentration for the assay. Selected parameters in synovial and peritoneal fluid were maximum concentration (C_max) 19.7 ± 7.14 µg/ml and 21.4 ± 4.39 µg/ml and time to maximum concentration 65 ± 12.2 min and 115 ± 12.2 min, respectively. Amikacin in the interstitial fluid reached a mean peak concentration of 12.7 ± 5.34 µg/ml and after 24 h the mean concentration was 3.31 ± 1.69 µg/ml. Based on a minimal inhibitory concentration (MIC) of 4 µg/ml, the mean C_max : MIC ratio was 16.9 ± 1.80 in plasma, 4.95 ± 1.78 in synovial fluid, 5.36 ± 1.10 in peritoneal fluid and 3.18 ± 1.33 in interstitial fluid. Conclusions: Amikacin dosed at 10 mg/kg bwt i.v. once a day in mature horses is anticipated to be effective for treatment of infection caused by most Gram‐negative bacteria. Potential relevance: Low dose amikacin (10 mg/kg bwt) administered once a day in mature horses may be efficacious against susceptible microorganisms.     

Pharmacology, pharmacokinetics, and behavioral effects of caffeine in horses

Caffeine (4 mg/kg) was given by rapid IV injection to 4 horses. Plasma concentrations of the drug peaked at 10 micrograms/ml and decreased rapidly at first, and then more slowly, with an apparent beta-phase half-life of 18.2 hours. Urinary concentrations of caffeine were remarkably consistent at about 3 times plasma values of the drug. Caffeine was detectable in both plasma and urine of the horses for up to 9 days after dosing. After oral administration, caffeine was absorbed poorly with an apparent bioavailability of 39%. Although blood concentrations of caffeine peaked rapidly after oral administration, its apparent plasma half-life by this route was about 42 hours. These observations identify the possible existence of a slowly absorbed pool of caffeine in the gastrointestinal tract after oral administration. When caffeine-treated horses were given fentanyl, the locomotor response to fentanyl was enhanced. This potentiation of the fentanyl response peaked at between 0 and 4 hours after dosing and was gone by 72 hours after caffeine dosing. The data indicate that the probability of behavioral stimulation due to caffeine by 72 hours after dosing may be small.     

Intravenous tramadol: effects, nociceptive properties, and pharmacokinetics in horses

ObjectiveTo determine the optimal dose, serum concentrations and analgesic effects of intravenous (IV) tramadol in the horse.Study designTwo-phase blinded, randomized, prospective crossover trial.AnimalsSeven horses (median age 22.5 years and mean weight 565 kg).MethodsHorses were treated every 20 minutes with incremental doses of tramadol HCl (0.1–1.6 mg kg^?1) or with saline. Heart rate, respiratory rate, step frequency, head height, and sweating, trembling, borborygmus and head nodding scores were recorded before and up to 6 hours after treatment. In a second study, hoof withdrawal and skin twitch reflex latencies (HWRL and STRL) to a thermal stimulus were determined 5 and 30 minutes, and 1, 2, 4 and 6 hours after bolus IV tramadol (2.0 mg kg^?1) or vehicle. Blood samples were taken to determine pharmacokinetics.ResultsCompared to saline, tramadol caused no change in heart rate, step frequency or sweating score. Respiratory rate, head height, and head nodding and trembling scores were transiently but significantly increased and borborygmus score was decreased by high doses of tramadol. Following cumulative IV administration of 3.1 mg kg^?1 and bolus IV administration of 2 mg kg^?1, the elimination half-life of tramadol was 1.91 ± 0.33 and 2.1 ± 0.9 hours, respectively. Baseline HWRL and STRL were 4.16 ± 1.0 and 3.06 ± 0.99 seconds, respectively, and were not significantly prolonged by tramadol.Conclusion and clinical relevanceIV tramadol at cumulative doses of up to 3.1 mg kg^?1 produced minimal transient side effects but 2.0 mg kg^?1 did not provide analgesia, as determined by response to a thermal nociceptive stimulus.     

Pharmacokinetics of a single bolus intravenous, intramuscular and subcutaneous dose of disodium fosfomycin in horses

Pharmacokinetic parameters of fosfomycin were determined in horses after the administration of disodium fosfomycin at 10 mg/kg and 20 mg/kg intravenously (IV), intramuscularly (IM) and subcutaneously (SC) each. Serum concentration at time zero (C_S0) was 112.21 ± 1.27 μg/mL and 201.43 ± 1.56 μg/mL for each dose level. Bioavailability after the SC administration was 84 and 86% for the 10 mg/kg and the 20 mg/kg dose respectively. Considering the documented minimum inhibitory concentration (MIC₉₀) range of sensitive bacteria to fosfomycin, the maximum serum concentration (Cmax) obtained (56.14 ± 2.26 μg/mL with 10 mg/kg SC and 72.14 ± 3.04 μg/mL with 20 mg/kg SC) and that fosfomycin is considered a time-dependant antimicrobial, it can be concluded that clinically effective plasma concentrations might be obtained for up to 10 h administering 20 mg/kg SC. An additional predictor of efficacy for this latter dose and route, and considering a 12 h dosing interval, could be area under the curve AUC_0-12/MIC₉₀ ratio which in this case was calculated as 996 for the 10 mg/kg dose and 1260 for the 20 mg/kg dose if dealing with sensitive bacteria. If a more resistant strain is considered, the AUC_0-12/MIC₉₀ ratio was calculated as 15 for the 10 mg/kg dose and 19 for the 20 mg/kg dose.     

Enrofloxacin assay validation and pharmacokinetics following a single oral dose in chickens

The pharmacokinetics of enrofloxacin (ENRO), a fluoroquinolone antimicrobial agent, was studied in male broiler chickens (Cobb) after single oral administration of 10 mg of ENRO/kg b.w. A high-performance liquid chromatography-photodiode array detector (DAD) (HPLC-DAD) method was developed and validated and used for quantitation of ENRO and its major metabolite ciprofloxacin in plasma. The HPLC analyses were carried out using a cationic-octadecyl mixed column and 0.05 mol/L phosphate buffer (pH 2.5)/acetonitrile as mobile phase. The sample preparation of plasma consisted of the precipitation of proteins followed by solid phase extraction on cationic-octadecyl mixed cartridges. The method was validated considering linear range, linearity, selectivity, sensitivity, limit of detection (LOD), limit of quantitation (LOQ), intra- and inter-day precisions and accuracy. The LOD and LOQ for both fluoroquinolones were 60 and 200 ng/mL for plasma. The plasma concentration vs. time graph was characteristic of a two-compartment open model. The maximal plasma concentration of 1.5 +/- 0.2 mg/mL was achieved at 9 +/- 2 h. The elimination half-life and the mean residence time of ENRO were 1.5 +/- 0.2 and 15.64 h, respectively. The area under the concentration-time curve was calculated as 35 +/- 4 mgxh/mL.     

Stereoselective pharmacokinetics of ketorolac in calves after a single intravenous and oral dose

The purpose of this study was to establish the stereospecific pharmacokinetics of ketorolac (KT) in calves following a single 2 mg/kg intravenous (i.v.) and a single 8 mg/kg oral dose. Plasma concentrations were determined using a stereoselective HPLC assay. Pharmacokinetic parameters for both the stereoisomers were estimated by model-independent methods. Following an i.v. dose, the plasma concentration profiles of the stereoisomers were similar with half-lives of 5.9 +/- 5.1 h for R-KT and 6.0 +/- 4.9 h for S-KT. Clearance values for R- and S-KT after an i.v. dose were 0.0470 +/- 0.0370 and 0.0480 +/- 0.0370 L/h/kg respectively. After an oral dose, the terminal half-lives were longer than following i.v. administration with values of 14.77 +/- 3.08 and 14.55 +/- 2.95 h for R-KT and S-KT respectively. The average oral bioavailability was 86.5 +/- 20.6% for R-KT and 86.7 +/- 20.3% for S-KT. The results indicate that the stereoisomers of KT have similar pharmacokinetic profiles in calves. Although, unlike humans, bioinversion between KT stereoisomers appears minimal in calves, studies with individual isomers are needed before any firm conclusions can be drawn about this lack of KT bioinversion.     

Non-linear pharmacokinetics of ofloxacin after a single intravenous bolus dose in pigs

The pharmacokinetics of ofloxacin (OFLX) was investigated after intravenous administration of 3, 10 and 30 mg/kg of body weight in pigs. Plasma OFLX concentration-time course collected from the highest dosage showed a convex decline, indicating a capacity-limited process in drug elimination (Michaelis-Menten elimination). Dose-normalized area under curve (AUC/Dose) and mean resident time (MRT) were dose-dependent, indicating a classical pattern of non-linear elimination pharmacokinetics. Based on simultaneous curve fitting from three doses, non-linear pharmacokinetic parameters were as follows: 0.87 mg/h/kg for maximum velocity, 2.20 microg/mL in Michaelis-Menten constant and 2.06 L/kg for apparent volume of distribution. Based on a model-independent analysis, the apparent volume of distribution at steady-state (Vdss) was dose-independent whereas total body clearance (CLtot) was dose-dependent, mainly contributed by renal clearance (CLr) with the regression line of CLtot=1.14xCLr+0.09 (r=0.92). The intercept of the regression line indicates non-renal clearance (CLnr), corresponding to the value of observed CLnr without dose-dependency. Because of a higher CLr compared with glomerular filtration rate (GFR) in spite of drug reabsorption, the CLr must contain the renal active tubular secretion. With increasing dosage, the level of saturation of tubular secretion of OFLX decreased the CLr, resulting in the decrease in CLtot. The plasma protein binding to OFLX was dose-independent: mean free fraction (fp)=0.73, with probably no influential effect on OFLX disposition. In conclusion, the degree of saturation in the renal active tubular secretion of OFLX could be a major causal factor in the alteration of CLr in an increasing dosage of OFLX. Accordingly, the alteration of CLr could directly induce the non-linear pharmacokinetics of OFLX in pigs, an important consideration in clinical therapeutics.     

Effects of a commercial dose of L-tryptophan on plasma tryptophan concentrations and behaviour in horses

Reasons for performing the study: L‐tryptophan is a common ingredient in equine calmative products, but its effectiveness has not been demonstrated in horses. Hypothesis: To determine whether a commercial dose of L‐tryptophan increases plasma tryptophan and alters behaviour in horses fed a roughage or concentrate meal. Methods: L‐tryptophan (6.3 g) or placebo (water) was administered per os in a cross‐over design, to 12 Thoroughbred horses (503 ± 12.1 kg bwt), just before a meal of lucerne hay or oats. Plasma tryptophan was measured by gas chromatography. Horse behaviour was observed in an empty enclosure, then in the presence of an unfamiliar person and a novel object. Results: Total plasma tryptophan increased 3‐fold in both studies, peaking 1.5‐2 h after dosing. After the peak, tryptophan remained high for several hours if the horses had been fed hay, but fell sharply if fed oats, consistent with the glycaemic responses to these meals. However, the ratio of tryptophan to 4 large neutral amino acids (phenylalanine, tyrosine, leucine and isoleucine) increased in the tryptophan‐treated horses to a similar extent and for a similar duration, with both diets. The presence of a stranger or novel object increased heart rate (P<0.05), but caused no behavioural effects that were altered by tryptophan, regardless of the diet. Conclusions: Plasma tryptophan increases when tryptophan is administered at a dose used in some commercial products, but this is not reflected by marked behavioural changes in the horse. Potential relevance: Further work is required to refine behavioural tests and identify an effective dose of L‐tryptophan in the horse.     

Pharmacokinetics of the calcium-channel blocker diltiazem after a single intravenous dose in horses

The pharmacokinetics of diltiazem were determined in eight healthy horses. Diltiazem HCl, 1 mg/kg i.v., was administered over 5 min. Venous blood samples were collected at regular intervals after administration. Plasma concentrations of diltiazem and desacetyldiltiazem were determined by high-performance liquid chromatography. A second, putative metabolite was detected, but could not be identified due to the lack of an authentic standard. Data were analyzed by nonlinear least-squares regression analysis. The median (minimum-maximum) peak plasma concentration of diltiazem was 727 (539-976) ng/mL. Plasma diltiazem concentration vs. time data were best described by a two-compartment model with first-order drug elimination. The distribution half-life was 12 (6-23) min, the terminal half-life was 93 (73-161) min, the mean residence time was 125 (99-206) min, total plasma clearance was 14.4 (10.4-18.6) mL/kg/min, and the volume of distribution at steady-state was 1.84 (1.46-2.51) L/kg. The normalized ratio of the area under the curve (AUC) of desacetyldiltiazem to the AUC of diltiazem was 0.088 (0.062-0.179). The disposition of diltiazem in horses was characterized by rapid distribution and elimination and a terminal half-life shorter than reported in humans and dogs. Because of the reported low pharmacologic activity, plasma diltiazem metabolite concentrations were not considered clinically important.     

Low dose calcium heparin in horses: plasma heparin concentrations, effects on red blood cell mass and on coagulation variables

Low dose calcium heparin was administered subcutaneously at 12 hourly intervals to six healthy horses at an initial dose of 150 iu of heparin/kg bodyweight (bwt) and at a maintenance dose of 120 iu/kg bwt. All injections were given at 0900 and 2100 h. Blood samples for monitoring plasma heparin concentrations were obtained prior to, at 2 hourly intervals for 84 h (treatment period), and at Hours 24, 32, 48 and 96 of the control period. Blood samples for monitoring red blood cell (RBC) mass, plasma antithrombin III activity (AT III), activated partial thromboplastin time (APTT), and thrombin time (TT) were taken at 8 hourly intervals during the treatment period and at all of the Control Period Hours. Mean plasma heparin concentrations increased significantly (P less than 0.01) from 2 h after the first to 32 h after the last (seventh) injection. Mean values corresponding to the desired range of heparin in plasma (0.05 to 0.20 iu/ml) were achieved at 21 h after initiation of heparin treatment and were maintained during the following 81 h. Great individual variations in the sensitivity to heparin among horses, cumulation of heparin in plasma with prolonged administration and a marked circadian periodicity in the disposition of heparin affected actually measured plasma heparin values. A chronodiagram revealed peak values around 1300 h, trough values around 0500 h. The peak-trough difference amounted to about 50 per cent. Increasing plasma heparin concentrations were associated with erratic prolongations of mean APTT and TT values. The AT III curve was not affected significantly.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pharmacokinetics of gentamicin C1, C1a and C2 in horses after single intravenous dose

Gentamicin pharmacokinetics has not been studied in horses. Pharmacokinetics of gentamicin C1, C1a and C2 components following i.v. administration of total gentamicin at 6.6 mg/kg bwt to 6 healthy mature horses was determined. Significant differences in clearance, half-life (t 1/2), and mean residence time (MRT) between the gentamicin Cia and the 2 other components were found. The total body clearance (CL) of gentamicin C1a was 1.62 +/- 0.50 ml/min x kg and similar to the glomerular filtration rate (GFR) reported for horses. The CL of gentamicin C1 and C2 were 1.03 +/- 0.08 ml/min x kg and 1.10 +/- 0.15 ml/min x kg, respectively, and significantly slower than that of gentamicin C1a. The values of apparent volume of distribution at steady state were 0.22 +/- 0.05, 0.26 +/- 0.12 and 0.23 +/- 0.05 l/kg for gentamicin C1, C1a and C2, respectively. The MRT values were mean +/- s.d. 3.6 +/- 0.5, 2.7 +/- 0.3 and 3.5 +/- 0.4 h and the t 1/2 values were 3.1 (2.5-4.0), 2.4 (2.0-3.2) and 33 (2.4-4.3) h (harmonic mean and range) for gentamicin C1, C1a and C2, respectively. The MRT and t 1/2 values for gentamicin C1a were significantly shorter than those of gentamicin C1 and C2. It was concluded that the difference in pharmacokinetics between the gentamicin components has potential pharmacological and toxicological implications.     

Plasma and urine nitric oxide concentrations in horses given below a low dose of endotoxin.

OBJECTIVE: To quantify plasma and urine nitric oxide (NO) concentrations before and after low-dose endotoxin infusion in horses. ANIMALS: 11 healthy adult female horses. Procedure-Eight horses were given endotoxin (35 ng/kg of body weight,i.v.) over 30 minutes. Three sentinel horses received an equivalent volume of saline (0.9% NaCl) solution over the same time. Clinical signs of disease and hemodynamic variables were recorded, and urine and plasma samples were obtained to measure NO concentrations prior to endotoxin infusion (t = 0) and every hour until postinfusion hour (PIH) 6, then every 2 hours until PIH 24. Blood for hematologic and metabolic analyses and for serum cytokine bioassays were collected at 0 hour, every hour until PIH 6, every 2 hours through PIH 12, and finally, every 6 hours until PIH 24. RESULTS: Differences in plasma NO concentrations across time were not apparent, but urine NO concentrations significantly decreased at 4 and 20 to 24 hours in endotoxin-treated horses. Also in endotoxin-treated horses, alterations in clinical signs of disease, and hemodynamic, metabolic, and hematologic variables were significant and characteristic of endotoxemia. Serum interleukin-6 (IL-6) activity and tumor necrosis factor (TNF) concentrations were increased above baseline values from 1 to 8 hours and 1 to 2 hours, respectively. CONCLUSIONS AND CLINICAL RELEVANCE: Plasma and urine NO concentrations did not increase in horses after administration of a low dose of endotoxin, despite induction of an inflammatory response, which was confirmed by increased TNF and IL-6 values characteristic alterations in clinical signs of disease, and hematologic, hemodynamic and metabolic variables.     

Hypnotic effects and pharmacokinetics of a single bolus dose of propofol in Japanese macaques (Macaca fuscata fuscata). [corrected

ObjectiveTo describe the hypnotic effects of a single bolus dose of propofol in Japanese macaques, and to develop a pharmacokinetic model.Study designProspective experimental trial.AnimalsFour male macaques (5-6 years old, 8.0-11.2 kg).MethodsThe macaque was restrained and 8 mg kg^?1 of propofol was administrated intravenously at 6 mg kg^?1 minute^?1. Behavioural changes without stimuli (first experiment) then responses to external stimuli (the second experiment) were assessed every 2 minutes for 20 minutes. Venous blood samples were collected before and at 1, 5, 15, 30, 60, 120 and 210 minutes after drug administration, and plasma concentrations of propofol were measured (third experiment). Pharmacokinetic modelling was performed using NONMEM VI.ResultsMacaques were recumbent without voluntary movement for a mean 14.0 ± 2.7 SD (range 10.5-16.2) or 10.0 ± 3.4 (7.2-14.5) minutes and recovered to behave as pre-administration by 25.1 ± 3.6 (22.1-30.1) or 22.2 ± 1.5 (21.1-24.3) minutes after the end of propofol administration without or with stimuli, respectively. Respiratory and heart rates were stable throughout the experiments (28-68 breaths minute^?1 and 72-144 beats minute^?1, respectively). Our final pharmacokinetic model included three compartments and well described the plasma concentration of propofol. The population pharmacokinetic parameters were: V₁ = 10.4 L, V₂=8.38 L, V₃=72.7 L, CL₁= 0.442 L minute^?1, CL₂= 1.14 L minute^?1, CL₃= 0.313 L minute^?1, (the volumes of distribution and the clearances for the central, rapid and slow peripheral compartments, respectively).ConclusionsIntravenous administration of propofol (8 mg kg^?1) at 6 mg kg^?1 minute^?1 to Japanese macaques had a hypnotic effect lasting more than 7 minutes. A three-compartment model described propofol plasma concentrations over more than 3 hours.Clinical relevanceThe developed pharmacokinetic parameters may enable simulations of administration protocols to maintain adequate plasma concentration of propofol.