Salbutamol is a short-acting and selective beta-2 adrenergic agonist. Inhaled (IH) administration of salbutamol is widely used to control lower respiratory tract disease in horses. Here, we estimated the pharmacokinetic parameters of salbutamol after a single intravenous (IV) or IH administration in six horses, and we statistically analysed the detection times with various dosing regimens. Plasma and urine concentrations of salbutamol were measured by liquid chromatography-tandem mass spectrometry, and data were modelled by using a nonlinear mixed effect model followed by Monte Carlo simulation (MCS). With IH salbutamol, the maximum plasma concentration was 0.12 ± 0.06 ng/mL at 0.29 ± 0.17 h after administration. Typical values were, for clearance, 1.53 L/kg/h; distribution volume at steady state, 5.43 L/kg; terminal half-life, 6.06 h; IH bioavailability, 19.0%; and urine to plasma ratio, 2057. Statistically estimated 95th percentile detection times in the urine at levels below the international screening limit (0.5 ng/mL) proposed by the International Federation of Horseracing Authorities, as simulated in 5000 horses by MCS, were 44 h after 1.6 μg/kg q 24 and 54 h after 1.6 μg/kg q 4 h over a 3-day IH administration period.

The number of available antiseizure medications with demonstrated efficacy in cats is limited. As such, there is a need to evaluate the pharmacokinetics of newer medications so that proper dosing regimens can be made. Brivaracetam (BRV) is a more potent analogue of levetiracetam, and is Food and Drug Administration approved for use in people. The goal of this study was to describe the pharmacokinetics of intravenous and oral doses of BRV in healthy cats. A cross-over study involving eight healthy cats, that were administered 10 mg of BRV intravenously as a bolus and orally in the fasted state. Blood samples were collected over 24 h. Analysis was performed using liquid chromatography-mass spectrometry. Data were subjected to non-compartmental analysis. Median (min-max) of maximal concentration, time to maximal concentration, area under the curve, elimination half-life and oral absolute bioavailability were 902 (682-1036) ng/mL, 0.6 (0.5-2.0) h, 6.4 (5.2-7.2) h, 8145 (6669-9351) ng × h/mL and 100% (85-110) respectively. BRV appeared to be well tolerated by all cats. A single dose of BRV is well tolerated both orally and intravenously. Maximal concentrations are produced rapidly and within the human reference interval considered to be therapeutic.

Levetiracetam (LEV) is an anti-epileptic drug used extra-label in dogs. Commercially available extended-release formulations (LEV-ER), administered twice daily, cannot be crushed or split, limiting their use in small dogs. A compounded LEV-ER formulation (PO-COMP) can purportedly be partitioned without loss of extended-release properties. The aims of this study were to establish the pharmacokinetic parameters of PO-COMP, divided at the tablet score, and determine the bioequivalence of partitioned PO-COMP to an intact commercially available Food and Drug Administration-approved human oral generic formulation of LEV-ER (PO-COMM). In a randomized crossover design, 12 healthy dogs received a single IV dose (30 mg/kg) of IV-COMM, a single oral dose (500 mg) of intact PO-COMM, or a single oral dose (500 mg) of partitioned PO-COMP and underwent serial measurement of plasma LEV concentrations over 24 h. PO-COMP was bioequivalent to PO-COMM using the 90% confidence interval method for maximum concentration (-3.2% difference [CI -7.4% to -1.1%]) and area under the curve (-14.4% difference [CI -17.8% to 10.8%]). PO-COMP may improve medication adherence and seizure control relative to immediate-release LEV, which requires three times daily dosing. Efficacy studies of PO-COMP are warranted.

Canine urinary excretion of chloramphenicol was evaluated to optimize a dosing protocol for treating urinary tract infections. Seven healthy male intact purpose-bred Beagles and six healthy client-owned dogs of various breeds each received a single oral 50 mg/kg dose of chloramphenicol. Urine was collected at baseline, and 6, 8, 12, and 24 h after chloramphenicol. Chloramphenicol urine concentrations were measured and compared to the epidemiological cutoff value for E. coli (16 mcg/mL). At 8 h, mean chloramphenicol concentration from all dogs was 266.9 mcg/mL (90% CI 136.2-397.7 mcg/mL) but was lower in Beagles than client-owned dogs. At 12 h, mean chloramphenicol concentration from all dogs was 111.0 mcg/mL (90% CI 36.9-185.0 mcg/mL) and was lower in Beagles (10.6 mcg/mL, 90% CI 1.4-19.8 mcg/mL) than client-owned dogs (228.0 mcg/mL, 90% CI 103.0-353.1 mcg/mL). Urine half-life was similar for all dogs (1.8-3.8 h). This justifies dosing chloramphenicol 50 mg/kg PO q 8 h. All client-owned dogs additionally maintained concentrations well above 16 mcg/mL, for 12 h, suggesting that q 12-h dosing might be appropriate for non-Beagle dogs with susceptible lower urinary tract infections. A clinical trial in dogs with urinary tract infections is needed as well as further investigation into potential breed differences.

Sea turtles face various threats to survival, primarily due to human activities, such as bycatch, vessel strikes, pollution, and climate change. Many of these activities can lead to illness or injuries, increasing the risk of infection. Treating infections appropriately and effectively requires knowledge of antimicrobial properties and their ability to eradicate microbes without harm to the sea turtle. Robust pharmacokinetic studies, therefore, are important for appropriate dosing. Herein, we review the studies detailing the pharmacokinetic properties of antimicrobials in sea turtles conducted to date.

Plasma chlortetracycline (CTC) concentration data were subjected to Monte Carlo simulation of area under the concentration curve (AUC) values related to bovine respiratory disease pathogen MIC distributions to evaluate target attainment rates. Crossbred Hereford heifers were randomly assigned into two treatment groups. Treatment group (A) received chlortetracycline (CTC) at a target dose of 22 mg/kg of bodyweight daily for 5 consecutive days (n = 8) and group (B) received CTC at 350 mg/head per day (1.5 ± 0.2 mg/kg based on actual bodyweights) for seven consecutive days (n = 8). Non-compartmental analysis was used to calculate plasma-free drug CTC area under the concentration curves. The mean observed (±SD) free drug AUC values were 4.18 (±1.72) μg × h/mL and 0.30 (±0.06) μg × h/mL for treatment groups A and B, respectively. The probability of target attainment for AUC/MIC values of 25 and 12.5 was modeled using Monte Carlo simulations. Treatment group A achieved >90% target attainment (AUC/MIC of 25) at an MIC of 0.06 μg/mL, whereas treatment group B displayed only 12.6% target attainment (AUC/MIC of 12.5) at the lowest MIC evaluated (0.015 μg/mL). Both in-feed CTC regimens failed to obtain a reasonable target attainment rate in light of expected MIC distributions of potential pathogens.

Mycoplasma synoviae (MS) infection is a serious threat to poultry industry in China. Tilmicosin is a semisynthetic macrolide antibiotic used only in animals and has shown potential efficacy against MS, but there were no reported articles concerning the pharmacokinetics/pharmacodynamics (PK/PD) interactions of tilmicosin against MS in vitro and vivo. This study aimed to assess the antibacterial activity of tilmicosin against MS in vitro and in vivo using PK/PD model to provide maximal efficacy. The minimum inhibitory concentration (MIC) and killing rates of different drug concentrations were measured using the microdilution method in vitro. Then, tilmicosin was administered orally to the MS-infected chickens at doses of 7.5 and 60 mg/kg, and the PK parameters of tilmicosin in joint dialysates were determined using high-pressure liquid chromatography/tandem mass spectrometry (HPLC-MS/MS) combined with the microdialysis technique. The antibacterial effect (△E) was calculated when the infected chickens were administered a single oral dose of tilmicosin at 4, 7.5, 15, 30, and 60 mg/kg b.w. The PK and PD data were fitted using the Sigmoid E model to evaluate the PK/PD interactions of tilmicosin against MS. The bactericidal activity of tilmicosin against MS was concentration dependent. Furthermore, the PK/PD index of AUC/MIC exhibited the most optimal fitting results (R = .98). The MS load decreased by 1, 2, and 3 Log CFU/mL, then AUC/MIC was determined as 13.99, 20.53, and 28.23 h, respectively, and the bactericidal effect can be achieved when the dose of MS-infected chickens is at 31.64 mg/kg b.w. The findings of this study hold significant implications for optimizing the treatment regimen for MS infection.

Parasitic infections in dairy cattle reduce herd immunity, milk production, and conception rates. This leads to higher production costs, compromised animal welfare, and increased interest in extralabel drug use. The extralabel use of anthelmintics poses food safety risks for consumers since appropriate withdrawal intervals in milk have yet to be established. Although topical eprinomectin has no milk withdrawal time, more research is needed to determine the residues present in milk after subcutaneous administration. This study aimed to characterize the pharmacokinetics of injectable eprinomectin in dry dairy cows. We hypothesized that, when given at the labeled dose, eprinomectin residues in dry dairy cattle would be below the FDA milk tolerance at the onset of lactation. Plasma was collected daily from 13 mature dairy cattle for 7 days postadministration, followed by periodic samples for 90 days. After calving, milk was collected daily until 90 days. Eprinomectin concentrations were measured using HPLC-fluorescence detection. The maximum eprinomectin concentration in plasma and milk was approximately 36 ng/mL 43 h after administration and 3 ng/mL at the onset of lactation, respectively. The low eprinomectin levels in milk collected from these lactating dairy cattle suggest that administering eprinomectin at dry-off is unlikely to result in violative residues. However, subcutaneous eprinomectin in lactating dairy cattle would be hard to justify unless there is evidence that the approved topical formulation is clinically ineffective.

Abomasal ulcers are a challenge in animal farming, affecting health, welfare, and productivity. Omeprazole's (OPZ) efficacy in treating these ulcers is known, but data on its pharmacokinetics (PK) in adult goats and sheep are lacking. The purpose of this research was to investigate and contrast OPZ's PK in these animals following a single intravenous (IV, 1 mg/kg) and subcutaneous (SC, 2 mg/kg) doses. Sheep and goats had similar exposure levels for all administration routes, with no significant AUCD variations. Half-life was short in both species (sheep: 0.20 h; goats: 0.31 h). Goats had a higher volume of distribution after IV administration. Clearance was rapid, and extraction ratio values were high for both goats and sheep (43% and 30%, respectively). SC administration showed similarities in C and T values between species. Both goats and sheep had high bioavailability (about 80%) levels and comparable mean absorption times (MAT). Despite some PK parameters' variances, systemic exposure to OPZ is similar in sheep and goats. SC administration's high bioavailability suggests it as a convenient field application route. Further investigations are needed to understand OPZ's effectiveness in small ruminants with abomasal ulcers and improve dosing regimens for clinical use.

Flunixin's pharmacokinetics, bioavailability, and plasma protein binding were examined in rainbow trout. The experiment involved 252 rainbow trout (Oncorhynchus mykiss) maintained at 12 ± 0.6°C. Flunixin was administered to rainbow trout via intravascular (IV), intramuscular (IM), and oral routes at a dosage of 2.2 mg/kg. Plasma samples were collected at times 0 (control), 0.25, 0.5, 1, 2, 4, 6, 8, 10, 12, 24, 48, 72, and 96 h. High-pressure liquid chromatography-ultraviolet was employed to quantify flunixin concentrations. The elimination half-life (t) for flunixin was 8.37 h for IV, 8.68 h for IM, and 8.76 h for oral. The t was similar between administration groups. The volume of distribution at a steady state and total body clearance were 55.81 mL/kg and 6.83 mL/h/kg, respectively, after IV administration. The mean peak plasma concentration was 6.24 ± 0.41 μg/mL at 4 h for oral administration and 13.98 ± 0.86 μg/mL at 2 h for IM administration. The in vitro protein binding ratio of flunixin in rainbow trout plasma was 96.34 ± 2.29%. The bioavailability of flunixin after oral (25.74%) administration was lower than that after IM (66.70%) administration. Thus, developing an oral pharmaceutical formulation that can be administered with feed and has high bioavailability could enhance the therapeutic effect.

Uterine vascular alterations take place in pyometra bitches speculatively influenced by prostaglandin and nitric oxide pathways. However, no causative effect of nitric oxide on endometrial vascularization was proved elsewhere for medically treated pyometra bitches. This study aimed to identify the main in situ uterine artery vasodilation pathway in pyometra bitches medically treated with antigestagen solely or coupled with prostaglandin. Pyometra bitches were enrolled into groups: Ovariohysterectomy at diagnosis (Control-OHE; n = 7), Antigestagen (10 mg/kg aglepristone on Days 1, 2, and 8 after diagnosis; n = 5), and Antigestagen + luteolytic (aglepristone plus 1 μg/kg of cloprostenol from Days 1-7; n = 5). Treated bitches were ovariohysterectomized after 8 days of treatment. Uterine artery fragments from all bitches were collected for tissue nitric oxide and prostaglandin E assays. Control-OHE group had lower uterine artery concentration of nitric oxide compared to treated bitches (Antigestagen and Antigestagen + luteolytic groups). No significant difference was verified between the medical treated groups. Uterine artery concentration of prostaglandin E was not different between control and treated bitches, as well as between both treated groups. In conclusion, nitric oxide and prostaglandin E are not directly involved in vascular modulation of the uterine artery, albeit pyometra medical treatment influences nitric oxide concentration in the uterine artery.

The aim of this study was to determine pharmacokinetics of florfenicol and its metabolite florfenicol amine after a single (30 mg/kg) intravenous (IV) and oral administration of florfenicol in chukar partridges. It also aimed to investigate tissue residue and withdrawal time of florfenicol after multiple-dose (30 mg/kg, every 24 h for 5 days) oral administration. The research was carried out in two stages: pharmacokinetics and residue. Plasma and tissue concentrations of florfenicol and florfenicol amine were determined by HPLC. The elimination half-life of florfenicol was 5.25 h for IV and 5.44 h for oral. The volume of distribution at a steady state and total body clearance of florfenicol were 0.38 L/kg and 0.07 L/h/kg, respectively, after IV administration. The peak plasma concentration and bioavailability for oral administration were 45.26 ± 4.06 and 51.55%, respectively. After multiple-dose oral administration, the highest concentration was detected in the liver (9.21 μg/g) for florfenicol and in the kidney (0.67 μg/g) for florfeniol amine. The calculated withdrawal period of florfenicol was determined as 6, 3, 4, and 5 days for muscle, liver, kidney, and skin + fat, respectively. These data indicate that a 6-day WT after multiple-dose administration of florfenicol in chukar partridges can be considered safe for human consumption.

Water temperature is a critical environmental parameter that significantly influences fish metabolism. This study assessed the metabolism of florfenicol (FF) in tilapia (Oreochromis niloticus) at water temperatures typical of tropical and subtropical regions. Fish were treated with FF by oral administration of a dose of 10 mg kg bw for 10 consecutive days. Fish fillet, liver, and kidney were sampled during the treatment phase (1, 5, and 10 days) and posttreatment (1, 2, 3, and 5 days after the last FF administration). FF, florfenicol amine (FFA), monochloro florfenicol (FFCl), and florfenicol alcohol (FFOH) were determined in the sampled tissues using a validated LC-LC-MS/MS method. The highest FF, FFA, and FFOH concentrations were determined on day 5 during the treatment phase. For FF, the concentration order is kidney > liver > fillet, while for the metabolites FFOH and FFA, the order is liver > kidney > fillet. In fillet and liver, the concentrations of FFOH were higher than the FFA concentrations, indicating that FFOH was the primary metabolite in these tissues. FFCl was only quantified at concentrations lower than 90 μg kg in all tissues. The results indicated that FF can be readily absorbed and rapidly eliminated in tilapia cultivated in warm water environments. This study revealed FFOH as the primary and most persistent metabolite in tilapia farmed in warm water, followed by FFA.

The aim of this study was to compare the pharmacokinetics of marbofloxacin after intravenous (IV) administration of a single dose of 10 mg/kg to calves of different ages. The study was carried on 1- (n = 6), 2- (n = 6), and 4-month-old (n = 6) Montofon calves. Plasma concentrations of marbofloxacin were measured using HPLC, and pharmacokinetic data were calculated by non-compartmental analysis. The elimination half-life (t), volume of distribution at steady state (V), total clearance (Cl), and area under the concentration-versus time curve (AUC) values of marbofloxacin in 1-month-old calves were 10.62 h, 1.03 L/kg, 0.08 L/h/kg, and 127.90 h*μg/mL, respectively. While the t (from 10.62 to 3.36 h) and AUC (from 127.90 to 47.35 h*μg/mL) decreased in parallel with the age of the calves, Cl (from 0.08 to 0.21 L/h/kg) increased. The V of marbofloxacin was higher in 1- and 2-month-old calves compared to 4-month-old calves. After IV administration of marbofloxacin at a dose of 10 mg/kg, an ƒAUC/MIC ratio of ≥ 125 was obtained for bacteria with MIC values of ≤ 0.60, ≤ 0.39 and ≤ 0.27 μg/mL in 1-, 2-, and 4-month-old calves, respectively. These results show that the antibacterial effect of marbofloxacin, which has concentration-dependent activity, decreases due to age-related pharmacokinetic changes and that the 10 mg/kg dose should be reviewed according to the MIC value of the bacteria.

The objective of this study was to assess the impact of the vehicle of administration and the prandial state of post weaning piglets on the indices of therapeutic efficacy for different broad-spectrum antibiotic/pathogen combinations. Pharmacokinetic data were retrieved from previous studies, in which we orally administered oxytetracycline (OTC), fosfomycin (FOS), or amoxicillin (AMX) according to the following treatments: dissolved in soft water to fasted or non-fasted piglets, dissolved in hard water to fasted or non-fasted piglets, and mixed with feed. Minimum inhibitory concentration (MIC) values for susceptible strains of bacteria causing swine diseases were obtained from the database of European Committee on Antimicrobial Susceptibility Testing (EUCAST) for each antibiotic. Pharmacokinetic/pharmacodynamic (PK/PD) indices of therapeutic efficacy-drug exposure over the dosing interval (fAUC/MIC) for OTC and FOS; time that free drug concentration remains above MIC (%fT>MIC) for AMX-were calculated for each antibiotic/pathogen combination under each treatment. After all OTC and in-feed FOS and AMX treatments, the indices of therapeutic efficacy were below the target value for all the study microorganisms. When FOS or AMX were delivered dissolved in soft or hard water, the indices were above the target value over which therapeutic efficacy would be expected for Escherichia coli treated with FOS and, Glaesserella parasuis, Pasteurella multocida, and Actinobacillus pleuropneumoniae treated with AMX. The prandial state of piglets showed no influence on the indices of therapeutic efficacy. Pharmacokinetic profiles of broad-spectrum antibiotics, specifically the ability to achieve target concentrations, may be largely reduced due to drug interactions with components present in feed or water resulting in a discrepancy with PK/PD principles of prudent and responsible use of antibiotics.

Oral artemisinin has antiparasitic activity and may help improve treatment success rates in dogs infected with Babesia gibsoni. However, these artemisinin products are unapproved and unregulated botanical supplements. They have not been evaluated for safety and efficacy or for strength, purity, or quality compared with a reference standard. Before considering these products for a clinical study, we evaluated the strength of four suppliers of artemisinin capsules using an high-performance liquid chromatography method validated in our laboratory. We found that the four artemisinin-labeled products that were tested had high within product and between product variability in capsule strength compared with the stated capsule strength on the product label. No products met the acceptance criteria of the United States Pharmacopeia and International Council for Harmonisation (ICH) as well as the criteria adapted by the authors. One product had no detectable artemisinin, and the other three products were much higher than the stated label strength. The results of this study reinforce the importance of testing unapproved and unregulated supplements before recommending a supplement for clinical use in dogs.

In response to the heightened risk of bacterial diseases in fish farms caused by increased demand for fish consumption and subsequent overcrowding, researchers are currently investigating the efficacy and residue management of oxolinic acid (OA) as a treatment for bacterial infections in fish. This research is crucial for gaining a comprehensive understanding of the pharmacokinetics of OA. The present study investigates pharmacokinetics of OA in juvenile rainbow trout. The fish were given a 12 mg kg dose of OA through their feed, and tissue samples were collected of the liver, kidney, gill, intestine, muscle, and plasma for analysis using LC-MS/MS. The highest concentrations of the drug were found in the gill (4096.55 μg kg) and intestine (11592.98 μg kg), with significant absorption also seen in the liver (0.36 L/h) and gill (0.07 L/h) (p < 0.05). The liver (0.21 L/h) and kidney (0.03 L/h) were found to be the most efficient (p < 0.05) at eliminating the drug. The study also confirmed the drug antimicrobial effectiveness against several bacterial pathogens, including Shewanella xiamenensis (0.25 μg mL), Lactococcus garvieae (1 μg mL), and Chryseobacterium aquaticum (4 μg mL). The study concludes significant variations among different fish tissues, with higher concentrations and longer half-lives observed in the kidney and intestine. The lowest MIC value recorded against major bacterial pathogens demonstrated its therapeutic potential in aquaculture. It also emphasizes the importance of understanding OA pharmacokinetics to optimize antimicrobial therapy in aquaculture.

Canagliflozin (CFZ) is a sodium-glucose cotransporter-2 inhibitor that has shown promising results as a drug for the treatment of insulin dysregulation in horses. Even though CFZ is used clinically, no pharmacokinetic data has previously been published. In this study, the pharmacokinetics of CFZ after administration of a single oral dose of 1.8 mg/kg in eight healthy Icelandic horses was examined. Additionally, the effect of treatment on glucose and insulin levels in response to a graded glucose infusion was investigated. Plasma samples for CFZ quantification were taken at 0, 0.33, 0.66, 1, 1.33, 1.66, 2, 2.33, 2.66, 3, 3.5, 4, 5, 6, 8, 12, 24, 32, and 48 h post administration. CFZ was quantified using UHPLC coupled to tandem quadrupole mass spectrometry (UHPLC-MS/MS). A non-compartmental analysis revealed key pharmacokinetic parameters, including a median T of 7 h, a C of 2350 ng/mL, and a t of 28.5 h. CFZ treatment reduced glucose (AUC, p = 0.001) and insulin (AUC, p = 0.04) response to a graded glucose infusion administered 5 h after treatment. This indicates a rapid onset of action following a single dose in healthy Icelandic horses. No obvious adverse effects related to the treatment were observed.

The objective of this study was to determine the pharmacokinetics of enrofloxacin and its metabolite, ciprofloxacin, in Nanyang cattle after a single intravenous (IV), and intramuscular (IM) administration of enrofloxacin at 2.5 mg/kg body weight (BW). Blood samples were collected at predetermined time points. Enrofloxacin and ciprofloxacin concentrations in plasma were simultaneously determined using a high-performance liquid chromatography (HPLC) assay method and subjected to a non-compartmental analysis. After IV administration, enrofloxacin had a mean (±SD) volume of distribution at steady state (V) of 1.394 ± 0.349 L/kg, a terminal half-life (t) of 3.592 ± 1.205 h, and a total body clearance (Cl) of 0.675 ± 0.16 L/h/kg. After IM administration, enrofloxacin was absorbed relatively slowly but completely, with a mean absorption time (MAT) of 6.051 ± 1.107 h and a bioavailability of 99.225 ± 7.389%. Both compounds were detected simultaneously in most plasma samples following both routes of administration, indicating efficient biotransformation of enrofloxacin to ciprofloxacin. After IV injection, the peak concentration (C) of ciprofloxacin was 0.315 ± 0.017 μg/mL, observed at 0.958 ± 0.102 h. Following IM injection, the corresponding values were 0.071 ± 0.006 μg/mL and 3 ± 1.095 h, respectively. Following IV and IM administration, the conversion ratio of enrofloxacin to ciprofloxacin was calculated as 59.2 ± 9.6% and 31.2 ± 7.7%, respectively. The present results demonstrated favorable pharmacokinetic profiles for enrofloxacin, characterized by complete absorption with relatively slow kinetics, extensive distribution, efficient biotransformation to ciprofloxacin, and prolonged elimination in Nanyang cattle.