Sedative effects and serum concentrations across time after subcutaneous administration of liposome-encapsulated or standard oxymorphone in healthy dogs

Our lab has developed a slow‐release liposomal formulation of oxymorphone (LEOx). The purpose of this study was to compare sedative effects and serum concentrations of oxymorphone after administration of LEOx and standard oxymorphone (STDOx) to dogs. At baseline, 1 mL of blood was drawn from the cephalic vein and sedation score was recorded. Dogs were divided into four groups (n = 6): (i) LEOx 1.0 mg kg^–1; (ii) LEOx 0.5 mg kg^–1; (iii) STDOx 0.1 mg kg^–1; (iv) STDOx 0.05 mg kg^–1. Unloaded liposomal vehicle (0.5 mL) was used as a control (n = 2). All treatments were given subcutaneously between the scapulae. Sedation score and serum concentration of drug were recorded at 0.5, 1, 2, 4, 8, 12, 16, 24 hours and daily for 5 days. Serum concentrations were measured with ELISA. At all time points, drug was not detected and sedation score was 0 in the control group. Sedation score for group 1 was significantly higher (p < 0.05) at 1 hour than for groups 2,3, and 4. There was no difference in sedation score between treatment groups at any other time. Serum concentrations of drug were significantly higher (p < 0.05) for group 1 at all time points measured after baseline. In groups 2, 3, and 4, serum concentrations of drug fell below the limit of detection (1.5 ng mL^–1) by 24 hours. Serum concentrations after 0.1 mg kg^–1of STDOx were 11.1 ± 3.6 ng mL^–1at 4 hours, which is the recommended time for redosing and presumably reflects the lower end of a therapeutic serum concentration. Serum concentrations were comparable after 1.0 mg kg^–1 of LEOx (10.5 ± 2.4 ng mL^–1) 48 hours after administration. These results suggest that liposomal oxymorphone may provide therapeutic serum concentrations of drug for 2 days after a single subcutaneous administration without undue sedation or other deleterious effects in healthy dogs. Further studies are warranted to assess analgesic efficacy and pharmacokinetics of lipsomal oxymorphone in dogs.     

Bioavailability of detomidine administered sublingually to horses as an oromucosal gel

Kaukinen, H., Aspegrén, J., Hyyppä, S., Tamm, L., Salonen, J. S. Bioavailability of detomidine administered sublingually to horses as an oromucosal gel. J. vet. Pharmacol. Therap. 34 , 76–81. The objective of the study was to determine the absorption, bioavailability and sedative effect of detomidine administered to horses as an oromucosal gel compared to intravenous and intramuscular administration of detomidine injectable solution. The study was open and randomized, with three sequences crossover design. Nine healthy horses were given 40 μg/kg detomidine intravenously, intramuscularly or administered under the tongue with a 7‐day wash‐out period between treatments. Blood samples were collected before and after drug administration for the measurement of detomidine concentrations in serum. The effects of the route of administration on heart rate and rhythm were evaluated and the depth of sedation assessed. Mean (±SD) bioavailability of detomidine was 22% (±5.3%) after sublingual administration and 38.2% (±7.9%) after intramuscular administration. The sedative effects correlated with detomidine concentrations regardless of the route of administration. We conclude that less detomidine is absorbed when given sublingually than when given intramuscularly, because part of it does not reach the circulation. Sublingual administration of detomidine oromucosal gel at 40 μg/kg produces safe sedation in horses. Slow absorption leads to fewer and less pronounced adverse effects than the more rapid absorption after intramuscular injection.     

Pharmacokinetics of procaterol in thoroughbred horses

Procaterol (PCR) is a beta‐2‐adrenergic bronchodilator widely used in Japanese racehorses for treating lower respiratory disease. The pharmacokinetics of PCR following single intravenous (0.5 μg/kg) and oral (2.0 μg/kg) administrations were investigated in six thoroughbred horses. Plasma and urine concentrations of PCR were measured using liquid chromatography–mass spectrometry. Plasma PCR concentration following intravenous administration showed a biphasic elimination pattern. The systemic clearance was 0.47 ± 0.16 L/h/kg, the steady‐state volume of the distribution was 1.21 ± 0.23 L/kg, and the elimination half‐life was 2.85 ± 1.35 h. Heart rate rapidly increased after intravenous administration and gradually decreased thereafter. A strong correlation between heart rate and plasma concentration of PCR was observed. Plasma concentrations of PCR after oral administration were not quantifiable in all horses. Urine concentrations of PCR following intravenous and oral administrations were quantified in all horses until 32 h after administration. Urine PCR concentrations were not significantly different on and after 24 h between intravenous and oral administrations. These results suggest that the bioavailability of orally administrated PCR in horses is very poor, and the drug was eliminated from the body slowly based on urinary concentrations. This report is the first study to demonstrate the pharmacokinetic character of PCR in thoroughbred horses.     

Comparison of two formulations of buprenorphine in cats administered by the oral transmucosal route

This randomised, blinded, cross-over study investigated the ease of oral transmucosal administration of two formulations of buprenorphine using glucose as a control in 12 cats. The cats received three treatments: buprenorphine multi-dose, buprenorphine and the equivalent volume of glucose 5%. Ease of treatment administration, observation of swallowing, changes in pupil size, sedation, salivation, vomiting, behaviour and food intake were assessed. The data were analysed using MLwiN and multi-level modelling. Ease of administration of buprenorphine multi-dose was statistically different from glucose (P <0.001), and the administration of all treatments became easier over the study periods. Swallowing was not statistically different between groups (P >0.05). Mydriasis was evident after the administration of both formulations of buprenorphine. Sedation, salivation, vomiting, behavioural changes or in-appetence were not observed after any treatment. Cats tolerated oral transmucosal administration of glucose better than buprenorphine multi-dose, while buprenorphine administration was tolerated as well as glucose.     

Clinical pharmacokinetics of flumequine in calves

The minimal inhibitory concentration (MIC) of flumequine for 249 Salmonella, 126 Escherichia coli, and 22 Pasteurella multocida isolates recovered from clinical cases of neonatal calf diarrhoea, pneumonia and sudden death was less than or equal to 0.78 microgram/ml. The pharmacokinetics of flumequine in calves was investigated after intravenous (i.v.), intramuscular (i.m.) and oral administration. The two-compartment open model was used for the analysis of serum drug concentrations measured after rapid i.v. ('bolus') injection. The distribution half-life (t1/2 alpha) was 13 min, elimination half-life (t1/2 beta) was 2.25 h, the apparent area volume of distribution (Vd(area)), and the volume of distribution at steady state (Vd(ss)) were 1.48 and 1.43 l/kg, respectively. Flumequine was quickly and completely absorbed into the systemic circulation after i.m. administration of a soluble drug formulation; a mean peak serum drug concentration (Cmax) of 6.2 micrograms/ml was attained 30 min after treatment at 10 mg/kg and was similar to the concentration measured 30 min after an equal dose of the drug was injected i.v. On the other hand, the i.m. bioavailability of two injectable oily suspensions of the drug was 44%; both formulations failed to produce serum drug concentrations of potential clinical significance after administration at 20 mg/kg. The drug was rapidly absorbed after oral administration; the oral bioavailability ranged between 55.7% for the 5 mg/kg dose and 92.5% for the 20 mg/kg dose. Concomitant i.m. or oral administration of probenecid at 40 mg/kg did not change the Cmax of the flumequine but slightly decreased its elimination rate. Flumequine was 74.5% bound in serum. Kinetic data generated from single dose i.v., i.m. and oral drug administration were used to calculate practical dosage recommendations. Calculations showed that the soluble drug formulation should be administered i.m. at 25 mg/kg every 12 h, or alternatively at 50 mg/kg every 24 h. The drug should be administered orally at 30 and 60 mg/kg every 12 and 24 h, respectively. Very large, and in our opinion impractical, doses of flumequine formulated as oily suspension are required to produce serum drug concentrations of potential clinical value.     

Pharmacokinetics of morphine and plasma concentrations of morphine-6-glucuronide following morphine administration to dogs

The purpose of this study was to evaluate the pharmacokinetics of morphine and morphine-6-glucuronide (M-6-G) following morphine administered intravenously and orally to dogs in a randomized crossover design. Six healthy 3–4-year-old Beagle dogs were administered morphine sulfate (0.5 mg/kg) as an i.v. bolus and extended release tablets were administered orally as whole tablets (1.6 ± 0.1 mg/kg) in a randomized crossover design. Plasma concentrations of morphine and M-6-G were determined using high-pressure liquid chromatography and electrochemical coulometric detection. Following i.v. administration all dogs exhibited dysphoria and sedation, and four or six dogs vomited. Mean ± SE values for half-life, apparent volume of distribution, and clearance after i.v. administration were 1.16 ± 0.15 h, 4.55 ± 0.17 L/kg, and 62.46 ± 10.44 mL/min/kg, respectively. One dog vomited following oral administration and was excluded from the oral analysis. Oral bioavailability was 5% as determined from naïve-averaged analysis. The M-6-G was not detected in any plasma samples following oral or i.v. administration of morphine at a 25 ng/mL the limit of quantification. Computer simulations concluded morphine sulfate administered 0.5 mg/kg intravenously every 2 h would maintain morphine plasma concentrations consistent with analgesic plasma concentrations in humans. Oral morphine is poorly and erratically absorbed in dogs.     

Pharmacokinetics and selected pharmacodynamics of romifidine following low‐dose intravenous administration in combination with exercise to quarter horses

Romifidine is an alpha‐2 adrenergic agonist used for sedation and analgesia in horses. As it is a prohibited substance, its purported use at low doses in performance horses necessitates further study. The primary goal of the study reported here was to describe the serum concentrations and pharmacokinetics of romifidine following low‐dose administration immediately prior to exercise, utilizing a highly sensitive liquid chromatography–tandem mass spectrometry assay that is currently employed in many drug testing laboratories. An additional objective was to describe changes in heart rate and rhythm following intravenous administration of romifidine followed by exercise. Eight adult Quarter Horses received a single intravenous dose of 5 mg (0.01 mg/kg) romifidine followed by 1 h of exercise. Blood samples were collected and drug concentrations measured at time 0 and at various times up to 72 h. Mean ± SD systemic clearance, steady‐state volume of distribution and terminal elimination half‐life were 34.1 ± 6.06 mL/min/kg and 4.89 ± 1.31 L/kg and 3.09 ± 1.18 h, respectively. Romifidine serum concentrations fell below the LOQ (0.01 ng/mL) and the LOD (0.005 ng/mL) by 24 h postadministration. Heart rate and rhythm appeared unaffected when a low dose of romifidine was administered immediately prior to exercise.     

Pharmacokinetics of florfenicol following intravenous and intramuscular doses to cattle

The disposition of florfenicol after single intravenous and intramuscular doses of 20 mg of florfenicol/kg of body weight (b.w.) to feeder calves was investigated. Serum florfenicol concentrations were determined by a sensitive high performance liquid chromatographic method with a limit of quantitation of 0.025 μg/ml. The extent of serum protein binding of florfenicol was only 13.2% at a serum florfenicol concentration of 3.0 μg/ml. Serum concentration-time data after intravenous administration were best described by a triexponential equation. Total body clearance and steady state volume of distribution were 3.75 ml/min/kg b.w. and 761 ml/kg b.w., respectively. The terminal half-life after intravenous administration was 159 min. The absolute systemic availability after intramuscular administration was 78.5% (range: 59.3–106%) and the harmonic mean of the terminal half-life was 1098 minutes, indicating slow release of the florfenicol from the formulation at the intramuscular injection site.     

Pharmacokinetics of erythromycin in foals and in adult horses

The pharmacokinetic parameters of erythromycin in foals were determined following intravenous administration of 5.0 mg/kg to animals aged 1, 3, 5 and 7 weeks. The distribution of the drug was described by a two-compartment open model, and no significant differences were observed between coefficients on which the parameters were based. Pharmacokinetic values were also determined for four mares given 5.0 mg/kg intravenously and for six 10–12 week-old foals given 20.0 mg/kg intravenously. The half-life of erythromycin for all groups of animals (foals less than 7 weeks, mares, foals 10–12 weeks) was 1.0–1.1 h; the apparent volume of distribution was between 2.3 and 7.2 l/kg, and the clearance of the drug from the body was between 1.9 and 5.0 mg/kg/h. No drug could be detected in the serum following oral administration of 5.0 mg/kg erythromycin estolate; detectable levels were found for 5 h in mares given 12.5 mg/kg, and for 8 h in foals given 20.0 mg/kg orally. Peak levels in foals given the drug orally were 0.42 μg/ml at 120 min after administration. Foals given 10.0 mg/kg of erythromycin base intramuscularly had serum concentrations detectable 12 h later, the peak level achieved was 1.44 μg/ml serum 90 min after administration and concentrations exceeded 0.25 μg/ml for 6 h. In the mares the milk concentrations were approximately twice those in serum. Recommendations were made for drug dosage to be used in the treatment of Corynebacterium equi pneumonia of foals.     

Pharmacokinetics,pharmacodynamics, and metabolism of acepromazine following intravenous,oral, and sublingual administration to exercised Thoroughbred horses

Acepromazine is a tranquilizer used commonly in equine medicine. This study describes serum and urine concentrations and the pharmacokinetics and pharmacodynamics of acepromazine following intravenous, oral, and sublingual (SL) administration. Fifteen exercised adult Thoroughbred horses received a single intravenous, oral, and SL dose of 0.09 mg/kg of acepromazine. Blood and urine samples were collected at time 0 and at various times for up to 72 hr and analyzed for acepromazine and its two major metabolites (2‐(1‐hydroxyethyl) promazine and 2‐(1‐hydroxyethyl) promazine sulfoxide) using liquid chromatography–tandem mass spectrometry. Acepromazine was also incubated in vitro with whole equine blood and serum concentrations of the parent drug and metabolites determined. Acepromazine was quantitated for 24 hr following intravenous administration and 72 hr following oral and SL administration. Results of in vitro incubations with whole blood suggest additional metabolism by RBCs. The mean ± SEM elimination half‐life was 5.16 ± 0.450, 8.58 ± 2.23, and 6.70 ± 2.62 hr following intravenous, oral, and SL administration, respectively. No adverse effects were noted and horses appeared sedate as noted by a decrease in chin‐to‐ground distance within 5 (i.v.) or 15 (p.o. and SL) minutes postadministration. The duration of sedation lasted 2 hr. Changes in heart rate were minimal.     

Pharmacokinetics of amantadine in cats

Siao, K. T., Pypendop, B. H., Stanley, S. D., Ilkiw, J. E. Pharmacokinetics of amantadine in cats. J. vet. Pharmacol. Therap. 34 , 599–604. This study reports the pharmacokinetics of amantadine in cats, after both i.v. and oral administration. Six healthy adult domestic shorthair female cats were used. Amantadine HCl (5 mg/kg, equivalent to 4 mg/kg amantadine base) was administered either intravenously or orally in a crossover randomized design. Blood samples were collected immediately prior to amantadine administration, and at various times up to 1440 min following intravenous, or up to 2880 min following oral administration. Plasma amantadine concentrations were determined by liquid chromatography–mass spectrometry, and plasma amantadine concentration–time data were fitted to compartmental models. A two‐compartment model with elimination from the central compartment best described the disposition of amantadine administered intravenously in cats, and a one‐compartment model best described the disposition of oral amantadine in cats. After i.v. administration, the apparent volume of distribution of the central compartment and apparent volume of distribution at steady‐state [mean ± SEM (range)], and the clearance and terminal half‐life [harmonic mean ± jackknife pseudo‐SD (range)] were 1.5 ± 0.3 (0.7–2.5) L/kg, 4.3 ± 0.2 (3.7–5.0) L/kg, 8.2 ± 2.1 (5.9–11.4) mL·min/kg, and 348 ± 49 (307–465) min, respectively. Systemic availability [mean ± SEM (range)] and terminal half‐life after oral administration [harmonic mean ± jackknife pseudo‐SD (range)] were 130 ± 11 (86–160)% and 324 ± 41 (277–381) min, respectively.     

Pharmacokinetics of voriconazole after single dose intravenous and oral administration to alpacas

Voriconazole is a new antifungal drug that has shown effectiveness in treating serious fungal infections and has the potential for being used in large animal veterinary medicine. The objective of this study was to determine the plasma concentrations and pharmacokinetic parameters of voriconazole after single-dose intravenous (i.v.) and oral administration to alpacas. Four alpacas were treated with single 4 mg/kg i.v. and oral administrations of voriconazole. Plasma voriconazole concentrations were measured by a high-performance liquid chromatography method. The terminal half-lives following i.v. and oral administration were 8.01 ± 2.88 and 8.75 ± 4.31 h, respectively; observed maximum plasma concentrations were 5.93 ± 1.13 and 1.70 ± 2.71 μg/mL, respectively; and areas under the plasma concentration vs. time curve were 38.5 ± 11.1 and 9.48 ± 6.98 mg·h/L, respectively. The apparent systemic oral availability was low with a value of 22.7 ± 9.5%. The drug plasma concentrations remained above 0.1 μg/mL for at least 24 h after single i.v. dosing. The i.v. administration of 4 mg/kg/day voriconazole may be a safe and appropriate option for antifungal treatment of alpacas. Due to the low extent of absorption in alpacas, oral voriconazole doses of 20.4 to 33.9 mg/kg/day may be needed.     

Tissue concentrations and pharmacokinetics of florfenicol in broiler chickens

1. Florfenicol (30 mg/kg body weight) was administered to broiler chickens via intravenous (iv), intramuscular (im) and oral routes to study its plasma concentrations, kinetic behaviour, systemic bioavailability and tissue content.

2. Following a single iv injection, the kinetic disposition of florfenicol followed a 2‐compartmental open model with an elimination half‐life of 173 min, total body clearance of 26.9 ml/kg/min and a steady state volume of distribution of 5.11 1/kg.

3. The highest plasma concentrations of florfenicol were 3.82 and 3.20 μg/ml following single im and oral administration, respectively. The systemic bioavailability was 96.6% and 55.3% after im and oral administration. The plasma protein binding of florfenicol was 18.5%.

4. Following its administration, the highest tissue concentrations of the drug were found in the kidney bile, lung, muscle, intestine, heart, liver, spleen and plasma. Low concentrations of the drug were found in brain, bone marrow and fat. No florfenicol residues were detected in tissues and plasma after 72 h except in the bile from where it disappeared after 96 h.     

Plasma concentrations,behavioural and physiological effects following intravenous and intramuscular detomidine in horses

Reasons for performing study: Detomidine hydrochloride is used to provide sedation, muscle relaxation and analgesia in horses, but a lack of information pertaining to plasma concentration has limited the ability to correlate drug concentration with effect. Objectives: To build on previous information and assess detomidine for i.v. and i.m. use in horses by simultaneously assessing plasma drug concentrations, physiological parameters and behavioural characteristics. Hypothesis: Systemic effects would be seen following i.m. and i.v. detomidine administration and these effects would be positively correlated with plasma drug concentrations. Methods: Behavioural (e.g. head position) and physiological (e.g. heart rate) responses were recorded at fixed time points from 4 min to 24 h after i.m. or i.v. detomidine (30 μg/kg bwt) administration to 8 horses. Route of administration was assigned using a balanced crossover design. Blood was sampled at predetermined time points from 0.5 min to 48 h post administration for subsequent detomidine concentration measurements using liquid chromatography‐mass spectrometry. Data were summarised as mean ± s.d. for subsequent analysis of variance for repeated measures. Results: Plasma detomidine concentration peaked earlier (1.5 min vs. 1.5 h) and was significantly higher (105.4 ± 71.6 ng/ml vs. 6.9 ± 1.4 ng/ml) after i.v. vs. i.m. administration. Physiological and behavioural changes were of a greater magnitude and observed at earlier time points for i.v. vs. i.m. groups. For example, head position decreased from an average of 116 cm in both groups to a low value 35 ± 23 cm from the ground 10 min following i.v. detomidine and to 64 ± 24 cm 60 min after i.m. detomidine. Changes in heart rate followed a similar pattern; low value of 17 beats/min 10 min after i.v. administration and 29 beats/min 30 min after i.m. administration. Conclusions: Plasma drug concentration and measured effects were correlated positively and varied with route of administration following a single dose of detomidine. Potential relevance: Results support a significant influence of route of administration on desirable and undesirable drug effects that influence case management.     

Some factors influencing the level of clinical sedation induced by medetomidine in rabbits

Rabbits (n=23) received intravenous bolus medetomidine at 100 mug/kg. Prior to medetomidine administration, heart and respiratory rates were measured, arterial blood was collected and analysed for plasma cortisol, glucose and albumin concentrations. Fifteen minutes after medetomidine administration, heart and respiratory rates were measured again and sedation was scored. The rabbit was afterwards anaesthetized with 20 mg/kg ketamine administered intravenously to enable spinal tap and heart puncture. Cerebrospinal fluid (CSF) was collected (this occurred 20 min post medetomidine administration) and analysed for medetomidine concentration. Blood was collected by heart puncture immediately after the spinal tap and analysed for serum medetomidine concentration. Cerebrospinal fluid medetomidine concentration correlated negatively with sedation. Serum medetomidine correlated positively with CSF medetomidine concentration. Cerebro-spinal fluid medetomidine was 17 +/- 13% of serum medetomidine concentration. Plasma cortisol and glucose concentrations correlated negatively with serum medetomidine. We conclude that after an intravenous bolus administration of a low sedative dose of medetomidine to rabbits; CSF concentration of the drug correlate negatively with sedation and that this may be because of the fact that only the free and unbound medetomidine may be available for detection in the CSF, the concentration of medetomidine detected in the CSF was much lower than that in blood and a positive correlation exists between CSF and serum medetomidine concentrations. Stress may have some effect on the distribution or metabolism of medetomidine in rabbits.     

Pharmacokinetics of intravenous and oral methimazole following single-and multiple-dose administration in normal cats

The pharmacokinetics of methimazole (MMI) administered intravenously and orally were determined in six adult domestic shorthaired cats. There was no significant difference between mean serum MMI concentrations after oral and i.v. administration by 30 min post-MMI administration, indicating relatively rapid and complete absorption of the drug. The bioavailability of MMI ranged from 27% to 100% (mean = 81.1 +/- 11.4%). The mean serum elimination half-life was 6.6 +/- 2.0 h, with a wide range of values (1.9 h to 15.1 h). After repeat i.v. administration of MMI following 2 weeks of oral administration of the drug, no significant difference was found between mean serum concentrations after single-dose and multiple-dose administration. No significant change in serum elimination half-life or total body clearance was found after multiple-dose administration of MMI. Two cats with the longest half-lives (9.9 h and 15.1 h), however, did exhibit markedly shorter t1/2 values (3.5 h and 3.3 h, respectively) after multiple-dose administration. Values for central and steady state volumes of distribution also decreased after multiple-dose administration, possibly indicating saturation of thyroid uptake of MMI with chronic administration. These results indicate that MMI has good oral bioavailability and has a longer mean serum elimination half-life than propylthiouracil, the other anti-thyroid drug that has been evaluated in cats. Although no significant change in mean values occurred after multiple-dose administration of MMI, drug-induced acceleration of metabolism may occur in some cats after long-term MMI administration.     

Intravenous disposition kinetics, oral and intramuscular bioavailability and urinary excretion of norfloxacin nicotinate in donkeys

An aqueous solution of norfloxacin nicotinate (NFN) was administered to donkeys (Aquus astnus) intravenously (once at 10 mg/kg), intramuscularly and orally (both routes once at 10 and 20 mg/kg, and for 5 days at 20 mg/kg/day). Blood samples were collected at predetermined times after each treatment and urine was sampled after intravenous drug administration. Serum NFN concentrations were determined by microbiological assay. Intravenous injection of NFN over 45–60 s resulted in seizures, profuse sweating and tachycardia. The intravenous half-life (t_1/2β was 209 ± 36 min, the apparent volume of distribution (V_d(area)) was 3.34 ± 0.58 L/kg, the total body clearance (Cl_E) was 1.092 ± 0.123 ± 10^--²mL/min/kg and the renal clearance (C1_R) was 0.411 ± 0.057 ± 10^--²mL/min/kg. Oral bioavailability was rather poor (9.6% and 6.4% for the 10 and 20 mg/kg doses respectively). Multiple oral treatments did not result in any clinical gastrointestinal disturbances. After intramuscular administration (20 mg/kg), serum NFN concentrations > 0.25 μg/mL (necessary to inhibit the majority of gram-negative bacteria isolated from horses) were maintained for 12 h. The intramuscular bioavailability was 31.5% and 18.8% for the 10 and 20 mg/kg doses respectively. After multiple dosing some local swelling was observed at the injection site. About 40% of the intravenous dose was recovered in the urine as parent drug. The results of comprehensive haematological and blood biochemistry tests indicated no abnormal findings except elevation in serum CPK (creatine phosphokinase) values after multiple intramuscular dosing. On the basis of the in vitro-determined minimum inhibitory concentrations of the drug and serum concentrations after multiple dosing, the suggested intramuscular dosage schedules for the treatment of gram-negative bacterial infections in Equidae are 10 mg/kg every 12 h or 20 mg/kg every 24 h.     

Selection of an aminoglycoside antibiotic for administration to horses

The serum concentrations of the aminoglycosides neomycin, kanamycin and streptomycin were determined after intravenous (iv) and intramuscular (im) administration. These values were then related to the minimum inhibitory concentrations (MIC) of a number of equine pathogenic bacteria to determine the duration of therapeutic serum concentrations of the aminoglycosides in the horse. Pharmacokinetic analysis of the data using neomycin as the example revealed a mean (+/- sd) peak serum concentration of 23.2 +/- 10.2 micrograms/ml present at 30 mins, and at 8 h the serum concentration was 2.8 +/- 0.8 micrograms/ml. From the pharmacological analysis of concentration-time data it was shown that neomycin was very rapidly absorbed from the im injection site, with an absorption half-time of 0.16 +/- 0.05 and was well absorbed (systemic availability was 73.7 +/- 26.9 per cent). A peak tissue level, which represented 40 per cent of the amount of drug in the body, was obtained at 32 mins after injection of the drug. At 8 h, the fractions of the dose in the central and peripheral compartments of the model were 1.5 per cent and 2.5 per cent respectively, and 96 per cent was the cumulative amount eliminated up to that time. Based on the MIC values of the majority of isolates of Corynebacterium equi, and only a few isolates of Klebsiella pneumoniae, Escherichia coli, Salmonella typhimurium and Streptococcus equi, one would expect a serum concentration of more than 2 micrograms neomycin/ml up to 8 h following im dosage (10 mg/kg) to be therapeutically effective.     

Sedative effects of hydromorphone or oxymorphone with or without acepromazine in dogs

Hydromorphone is an agonist opioid with potency approximately five times that of morphine and half that of oxymorphone. The purpose of this study was to compare hydromorphone with oxymorphone, with or without acepromazine, for sedation in dogs, and to measure plasma histamine before and after drug administration. Ten dogs received IM hydromorphone (H; 0.2 mg kg^?1), oxymorphone (O; 0.1 mg kg^?1), hydromorphone with acepromazine (H; 0.2 mg kg^?1, A; 0.05 mg kg^?1) or oxymorphone with acepromazine (O; 0.1 mg kg^?1, A; 0.05 mg kg^?1) in a randomized Latin‐square design. Sedation score, heart rate, respiratory rate, blood pressure, and SpO₂ were recorded at baseline and every 5 minutes after drug administration up to 25 minutes. Plasma histamine was measured at baseline and at 25 minutes post‐drug administration. Data were analyzed with repeated measures anova . Mean ± SD body weight was 21.62 ± 1.54 kg. Mean ± SD age was 1.07 ± 0.19 years. Sedation score was significantly greater for OA after 5 minutes than O alone (4.1 ± 3.5 versus 1.9 ± 1.5) and for HA after 15 minutes than H alone (8.6 ± 2.9 versus 5.9 ± 2.5). There was no significant difference in sedation between H and O at any time point. There was no significant difference between groups at any time with respect to heart rate, respiratory rate, blood pressure or SpO₂. Mean ± SD plasma histamine (nM ml^?1) for all groups was 1.72 ± 2.69 at baseline and 1.13 ± 1.18 at 25 minutes. There was no significant change in plasma histamine concentration in any group. Hydromorphone is effective for sedation in dogs and does not cause measurable increase in histamine. Sedation with hydromorphone is enhanced by acepromazine.     

The pharmacokinetics of midazolam after intravenous,intramuscular, and rectal administration in healthy dogs

Intravenous benzodiazepines are utilized as first‐line drugs to treat prolonged epileptic seizures in dogs and alternative routes of administration are required when venous access is limited. This study compared the pharmacokinetics of midazolam after intravenous (IV), intramuscular (IM), and rectal (PR) administration. Six healthy dogs were administered 0.2 mg/kg midazolam IV, IM, or PR in a randomized, 3‐way crossover design with a 3‐day washout between study periods. Blood samples were collected at baseline and at predetermined intervals until 480 min after administration. Plasma midazolam concentrations were measured by high‐pressure liquid chromatography with UV detection. Rectal administration resulted in erratic systemic availability with undetectable to low plasma concentrations. Arithmetic mean values ± SD for midazolam peak plasma concentrations were 0.86 ± 0.36 μg/mL (C₀) and 0.20 ± 0.06 μg/mL (C_max), following IV and IM administration, respectively. Time to peak concentration (T_max) after IM administration was 7.8 ± 2.4 min with a bioavailability of 50 ± 16%. Findings suggest that IM midazolam might be useful in treating seizures in dogs when venous access is unavailable, but higher doses may be needed to account for intermediate bioavailability. Rectal administration is likely of limited efficacy for treating seizures in dogs.