Ronette Gehring

Plasma concentrations of substance P and cortisol in beef calves after castration or simulated castration

OBJECTIVE To evaluate plasma concentrations of substance P (SP) and cortisol in calves after castration or simulated castration. ANIMALS 10 Angus-crossbred calves. PROCEDURES Calves were acclimated for 5 days, assigned to a block on the basis of scrotal circumference, and randomly assigned to a castrated or simulated-castrated (control) group. Blood samples were collected twice before, at the time of (0 hours), and at several times points after castration or simulated castration. Vocalization and attitude scores were determined at time of castration or simulated castration. Plasma concentrations of SP and cortisol were determined by use of competitive and chemiluminescent enzyme immunoassays, respectively. Data were analyzed by use of repeated-measures analysis with a mixed model. RESULTS Mean +/- SEM cortisol concentration in castrated calves (78.88+/-10.07 nmol/L) was similar to that in uncastrated control calves (73.01+/-10.07 nmol/L). However, mean SP concentration in castrated calves (506.43+/-38.11 pg/mL) was significantly higher than the concentration in control calves (386.42+/-40.09 pg/mL). Mean cortisol concentration in calves with vocalization scores of 0 was not significantly different from the concentration in calves with vocalization scores of 3. However, calves with vocalization scores of 3 had significantly higher SP concentrations, compared with SP concentrations for calves with vocalization scores of 0. CONCLUSIONS AND CLINICAL RELEVANCE Similar cortisol concentrations were measured in castrated and control calves. A significant increase in plasma concentrations of SP after castration suggested a likely association with nociception. These results may affect assessment of animal well-being in livestock production systems.

Health concerns and management of select veterinary drug residues

The aim of this manuscript is to review the potential adverse health effects in humans if exposed to residues of selected veterinary drugs used in food-producing animals. Our other objectives are to briefly inform the reader of why many of these drugs are or were approved for use in livestock production and how drug residues can be mitigated for these drugs. The selected drugs include several antimicrobials, beta agonists, and phenylbutazone. The antimicrobials continue to be of regulatory concern not only because of their acute adverse effects but also because their use as growth promoters have been linked to antimicrobial resistance. Furthermore, nitroimidazoles and arsenicals are no longer approved for use in food animals in most jurisdictions. In recent years, the risk assessment and risk management of beta agonists, have been the focus of national and international agencies and this manuscript attempts to review the pharmacology of these drugs and regulatory challenges. Several of the drugs selected for this review can cause noncancer effects (e.g., penicillins) and others are potential carcinogens (e.g., nitroimidazoles). This review also focuses on how regulatory and independent organizations manage the risk of these veterinary drugs based on data from human health risk assessments.

Pharmacokinetics and effect of intravenous meloxicam in weaned Holstein calves following scoop dehorning without local anesthesia.

BackgroundDehorning is a common practice involving calves on dairy operations in the United States. However, less than 20% of producers report using analgesics or anesthetics during dehorning. Administration of a systemic analgesic drug at the time of dehorning may be attractive to dairy producers since cornual nerve blocks require 10 – 15 min to take effect and only provide pain relief for a few hours. The primary objectives of this trial were to (1) describe the compartmental pharmacokinetics of meloxicam in calves after IV administration at 0.5 mg/kg and (2) to determine the effect of meloxicam (n = 6) or placebo (n = 6) treatment on serum cortisol response, plasma substance P (SP) concentrations, heart rate (HR), activity and weight gain in calves after scoop dehorning and thermocautery without local anesthesia.ResultsPlasma meloxicam concentrations were detectable for 50 h post-administration and fit a 2-compartment model with a rapid distribution phase (mean T½α = 0.22 ± 0.087 h) and a slower elimination phase (mean T½β = 21.86 ± 3.03 h). Dehorning caused a significant increase in serum cortisol concentrations and HR (P < 0.05). HR was significantly lower in the meloxicam-treated calves compared with placebo-treated calves at 8 h (P = 0.039) and 10 h (P = 0.044) after dehorning. Mean plasma SP concentrations were lower in meloxicam treated calves (71.36 ± 20.84 pg/mL) compared with control calves (114.70 ± 20.84 pg/mL) (P = 0.038). Furthermore, the change in plasma SP from baseline was inversely proportional to corresponding plasma meloxicam concentrations (P = 0.008). The effect of dehorning on lying behavior was less significant in meloxicam-treated calves (p = 0.40) compared to the placebo-treated calves (P < 0.01). Calves receiving meloxicam prior to dehorning gained on average 1.05 ± 0.13 kg bodyweight/day over 10 days post-dehorning compared with 0.40 ± 0.25 kg bodyweight/day in the placebo-treated calves (p = 0.042).ConclusionsTo our knowledge, this is the first published report examining the effects of meloxicam without local anesthesia on SP, activity and performance of calves post-dehorning. These findings suggest that administration of meloxicam alone immediately prior to dehorning does not mitigate signs of acute distress but may have long term physiological, behavior and performance effects.

Pharmacokinetics and physiologic effects of intramuscularly administered xylazine hydrochloride-ketamine hydrochloride- butorphanol tartrate alone or in combination with orally administered sodium salicylate on biomarkers of pain in Holstein calves following castration and dehorning

OBJECTIVE To determine the pharmacokinetic parameters of xylazine, ketamine, and butorphanol (XKB) administered IM and sodium salicylate (SAL) administered PO to calves and to compare drug effects on biomarkers of pain and distress following sham and actual castration and dehorning. ANIMALS 40 Holstein bull calves from 3 farms. PROCEDURES Calves weighing 108 to 235 kg (n = 10 calves/group) received one of the following treatments prior to sham (period 1) and actual (period 2) castration and dehorning: saline (0.9% NaCl) solution IM (placebo); SAL administered PO through drinking water at concentrations from 2.5 to 5 mg/mL from 24 hours prior to period 1 to 48 hours after period 2; butorphanol (0.025 mg/kg), xylazine (0.05 mg/kg), and ketamine (0.1 mg/kg) coadministered IM immediately prior to both periods; and a combination of SAL and XKB (SAL+XKB). Plasma drug concentrations, average daily gain (ADG), chute exit velocity, serum cortisol concentrations, and electrodermal activity were evaluated. RESULTS ADG (days 0 to 13) was significantly greater in the SAL and SAL+XKB groups than in the other 2 groups. Calves receiving XKB had reduced chute exit velocity in both periods. Serum cortisol concentrations increased in all groups from period 1 to period 2. However, XKB attenuated the cortisol response for the first hour after castration and dehorning and oral SAL administration reduced the response from 1 to 6 hours. Administration of XKB decreased electrodermal activity scores in both periods. CONCLUSIONS AND CLINICAL RELEVANCE SAL administered PO through drinking water decreased cortisol concentrations and reduced the decrease in ADG associated with castration and dehorning in calves.

Analgesic efficacy of sodium salicylate in an amphotericin B-induced bovine synovitis-arthritis model

This study examined the efficacy of sodium salicylate for providing analgesia in an amphotericin B-induced bovine synovitis-arthritis model using 10 male Holstein calves, 4 to 6 mo old and weighing approximately 250 kg. The study used a repeated measures partial crossover design with 2 phases, consisting of 3 treatment periods within each phase. Calves were blocked by body weight and randomly assigned to the sodium salicylate (50 mg/kg i.v.) or placebo group for phase 1. In period 1, lameness induction was simulated with a needle prick of the coronary band, followed by drug or placebo administration. At predetermined time points, serial blood samples for cortisol and salicylate concentrations, electrodermal activity measurements, heart rates, and pressure mat data were collected. Visual lameness scores were recorded by an observer blinded to treatments. In period 2, lameness was induced with injection of amphotericin B into the distal interphalangeal joint, followed by drug or placebo administration, with sample collection as described previously. In period 3, the drug or placebo was administered to the respective calves with sample collection. After a 10-d washout period, phase 2 was conducted with treatments crossed over between groups. Cortisol and salicylate samples were analyzed by competitive chemiluminescent immunoassay and fluorescence polarization immunoassay, respectively. The pharmacokinetic data were analyzed using compartmental analysis. Mean intravenous salicylate apparent volume of distribution was 0.2 +/- 0.005 L/kg, total body clearance was 4.3 +/- 0.2 mL/min.kg, and elimination half-life was 36.9 +/- 1.2 min. The repeated measures data were analyzed based on a univariate split-plot approach with a random effects-mixed model. Differences in stance phase duration and serum cortisol concentration values were seen both between periods and between treatment group x periods; differences in heart rate, contact surface area, and contact pressure values were seen between periods, suggesting that our lameness model was effective. No differences were seen between treatment groups. When analyzed by visual lameness score, differences were seen in heart rate, contact surface area, contact pressure, and cortisol concentrations. Area under the time-effect curves, determined by using the trapezoidal rule, had results similar to the repeated measures data, except for a difference in period for electrodermal activity. This amphotericin B-induced synovitis-arthritis model is a useful tool for studying changes associated with lameness in cattle. Sodium salicylate was not effective in providing analgesia after lameness.

Pharmacokinetics and milk secretion of gabapentin and meloxicam co-administered orally in Holstein-Friesian cows.

Management of neuropathic pain in dairy cattle could be achieved by combination therapy of gabapentin, a GABA analog and meloxicam, an nonsteroidal anti-inflammatory drug. This study was designed to determine specifically the depletion of these drugs into milk. Six animals received meloxicam at 1 mg/kg and gabapentin at 10 mg/kg, while another group (n=6) received meloxicam at 1 mg/kg and gabapentin at 20 mg/kg. Plasma and milk drug concentrations were determined over 7 days postadministration by HPLC/MS followed by noncompartmental pharmacokinetic analyses. The mean (±SD) plasma C(max) and T(max) for meloxicam (2.89±0.48 μg/mL and 11.33±4.12 h) were not much different from gabapentin at 10 mg/kg (2.87±0.2 μg/mL and 8±0 h). The mean (±SD) milk C(max) for meloxicam (0.41±80.16 μg/mL) was comparable to gabapentin at 10 mg/kg (0.63±0.13 μg/mL and 12±6.69 h). The mean plasma and milk C(max) for gabapentin at 20 mg/kg p.o. were almost double the values at 10 mg/kg. The mean (±SD) milk to plasma ratio for meloxicam (0.14±0.04) was lower than for gabapentin (0.23±0.06). The results of this study suggest that milk from treated cows will have low drug residue concentration soon after plasma drug concentrations have fallen below effective levels.

Effect of sub-anesthetic xylazine and ketamine ('ketamine stun') administered to calves immediately prior to castration.

OBJECTIVE To describe the pharmacokinetics, cortisol response and behavioral changes associated with administration of sub-anesthetic xylazine and ketamine prior to castration. STUDY DESIGN Prospective, randomized experiment. ANIMALS Twenty-two male beef calves (260-310 kg). METHODS Calves were randomly assigned to receive the following treatment immediately prior to surgical or simulated castration; 1) uncastrated, placebo-treated control (CONT) (n=4),2) Castrated, placebo treated control (CAST) (n=6), 3) castrated with intravenous xylazine (X) (0.05 mg kg(-1)) (n=6), and 4) castrated with IV xylazine (X) (0.05 mg kg(-1) ) combined with ketamine (K) (0.1 mg kg(-1)) (n=6). Blood samples collected over 10 hours post-castration were analyzed by LC-MS-MS for drug concentrations and chemiluminescent immunoassay for cortisol determination. RESULTS Drug concentrations during the first 60 minutes post-castration fit a one-compartment open model with first-order elimination. The harmonic mean elimination half-lives (± pseudo SD) for X, X with K and K were 12.9 ± 1.2, 11.2 ± 3.1 and 10.6 ± 2.8 minutes, respectively. The proportion of the total area under the effect curve (AUEC) for cortisol during this period was significantly lower in the X group (13 ± 3%; p=0.006) and the X+K group (14 ± 2%; p=0.016) compared with the CAST calves (21 ± 2%). However, after 300 minutes the AUEC in the X group was higher than CAST. Significantly more calves demonstrated attitude that was unchanged from pre-manipulation behavior in the CONT (p=0.021) and X+K treated calves (p=0.0051) compared with the CAST calves. CONCLUSIONS Behavioral changes and lower serum cortisol concentrations during the first 60 minutes post-castration were associated with quantifiable xylazine and ketamine concentrations. CLINICAL RELEVANCE Low doses of xylazine and ketamine administered immediately prior to castration may offer a safe, efficacious and cost-effective systemically administered alternative or adjunct to local anesthesia.

Development and Application of a Multiroute Physiologically Based Pharmacokinetic Model for Oxytetracycline in Dogs and Humans

Oxytetracycline (OTC) is a commonly used tetracycline antibiotic in veterinary and human medicine. To establish a quantitative model for predicting OTC plasma and tissue exposure, a permeability-limited multiroute physiologically based pharmacokinetic model was developed in dogs. The model was calibrated with plasma pharmacokinetic data in beagle dogs following single intravenous (5 mg/kg), oral (100 mg/kg), and intramuscular (20 mg/kg) administrations. The model predicted other available dog data well, including drug concentrations in the liver, kidney, and muscle after repeated exposure, and data in the mixed-breed dog. The model was extrapolated to humans and the human model adequately simulated measured plasma OTC concentrations after intravenous (7.14 mg/kg) and oral exposures (6.67 mg/kg). The dog model was applied to predict 24-h OTC area-under-the-curve after three therapeutic treatments. Results were 27.75, 51.76, and 64.17 μg/mL*h in the plasma, and 120.93, 225.64, and 279.67 μg/mL*h in the kidney for oral (100 mg/kg), intravenous (10 mg/kg), and intramuscular (20 mg/kg) administrations, respectively. This model can be used to predict plasma and tissue concentrations to aid in designing optimal therapeutic regimens with OTC in veterinary, and potentially, human medicine; and as a foundation for scaling to other tetracycline antibiotics and to other animal species.

Pharmacokinetics of oral meloxicam in ruminant and preruminant calves

The pharmacokinetics of oral meloxicam has been studied in ruminant, but not preruminant calves. Oral meloxicam was administered at 0.5 mg/kg to six ruminant calves via gavage (RG); to six preruminant calves via gavage (PRG); and to six preruminant calves via suckling in milk replacer (PRF). Plasma drug concentrations, determined over 120-h postadministration, were analyzed by compartmental and noncompartmental methods. The rate of drug absorption was faster (P<0.01) in PRF (0.237±0.0478/h) than RG calves (0.0815±0.0188/h), while absorption in PRG calves (0.153±0.128/h) was not different from other groups. C(max) was lower (P=0.03) in PRF (1.27±0.430 μg/mL) than in PRG calves (2.20±0.467 μg/mL), while C(max) of RG calves (1.95±0.955 μg/mL) was not different from other groups. V/F was higher in PRF calves (365±57 mL/kg) than either PRG (177±63 mL/kg, P<0.01) or RG (232±83 mL/kg, P=0.01) calves. These observations were likely due to differences in bioavailability, physiological maturity, and timing of the drug delivery into different compartments of the ruminant gastrointestinal tract. Results suggest that an adjustment in meloxicam dose may be necessary when administered with milk replacer.

Mathematical modeling and simulation in animal health - Part II: principles, methods, applications, and value of physiologically based pharmacokinetic modeling in veterinary medicine and food safety assessment.

This review provides a tutorial for individuals interested in quantitative veterinary pharmacology and toxicology and offers a basis for establishing guidelines for physiologically based pharmacokinetic (PBPK) model development and application in veterinary medicine. This is important as the application of PBPK modeling in veterinary medicine has evolved over the past two decades. PBPK models can be used to predict drug tissue residues and withdrawal times in food-producing animals, to estimate chemical concentrations at the site of action and target organ toxicity to aid risk assessment of environmental contaminants and/or drugs in both domestic animals and wildlife, as well as to help design therapeutic regimens for veterinary drugs. This review provides a comprehensive summary of PBPK modeling principles, model development methodology, and the current applications in veterinary medicine, with a focus on predictions of drug tissue residues and withdrawal times in food-producing animals. The advantages and disadvantages of PBPK modeling compared to other pharmacokinetic modeling approaches (i.e., classical compartmental/noncompartmental modeling, nonlinear mixed-effects modeling, and interspecies allometric scaling) are further presented. The review finally discusses contemporary challenges and our perspectives on model documentation, evaluation criteria, quality improvement, and offers solutions to increase model acceptance and applications in veterinary pharmacology and toxicology.