Pharmacokinetic of florfenicol in pulmonary epithelial lining fluid of swine and effects of anesthetic agent on drug plasma disposition kinetics

Wang, Yanping; Zhang, Ling; Ahmed, Saeed; Liu, Yonghong; Li, Xianqiang

doi:10.1590/1678-4162-9770

ABSTRACT

The primary objective of the current study was to compare the pharmacokinetic (PK) of florfenicol (FFL) in pulmonary epithelial lining fluid and the plasma in swine. The second objectives were to evaluate the effect of anesthesia with ketamine and propofol on the PK of FFL in plasma. Bronchoaveolar lavage was utilized for quantification of PELF volume and the urea dilution method was used to determine the concentration of FFL in PELF. FFL was administered intramuscularly (IM) to swine in a single dose of 20mg/kg body weight. The main PK parameters of FFL in plasma and PELF were as follows: the area under the concentration-time curve, maximal drug concentration, elimination half-life and mean residence time were 69.45±4.36 vs 85.03±9.26μg·hr/ml, 4.65±0.34 vs 5.94±0.86μg/ml, 9.87±1.70 vs 10.69±1.60hr and 12.75±0.35 vs 14.46±1.26hr, respectively. There was no statistically significant difference between the PK profiles of FFL for the anesthetized and unanesthetized pigs. This study suggest that (i) FFL penetrated rapidly into the pulmonary and the drug concentration decay faster in plasma than in the pulmonary, (ii) the PK profile of FFL in swine was not interfered after administration of anesthetic agent.

Keywords:
anesthetic agent; bronchoaveolar lavage; florfenicol; pharmacokinetic; pulmonary

RESUMO

O objetivo primário desse estudo foi comparar a farmacocinética de florfenicol (FFL) em fluido epitelial pulmonar à farmacocinética (PK) de FFL em plasma suíno. O segundo objetivo foi avaliar o efeito de anestesia com ketamina e propofol no PK de FFL em plasma. Lavagem broncoalveolar foi utilizada para quantificar volume de fluido epitelial pulmonar (PELF) e método de diluição de uréia para determinar FFL em PELF. Injeção de FFL foi administrada intramuscular a suínos em dose única de 20mg/kg de peso corporal. Os principais parâmetros de PK em FFL em plasma e PELF foram os seguintes: a área sob a curva de concentração-tempo, concentração máxima da droga, eliminação de meia-vida e média de tempo de permanência foram 69,45±4,36 vs 85,03±9,26μg·hr/ml, 4,65±0,34 vs 5,94±0,86μg/ml, 9,87±1,70 vs 10,69±1,60hr e 12,75±0,35 vs 14,46±1,26hr, respectivamente. Não houve diferença estatisticamente significante entre os perfis de PK de FFL para os porcos anestesiados e não anestesiados. Esse estudo sugere que (i) FFL penetrou rapidamente no pulmão e concentração da droga sofre queda mais veloz em plasma que líquido pulmonar, (ii) o perfil de PK de FFL em suínos não modificou após administração de agente anestésico.

Palavras-chave:
agente anestésico; lavagem broncoalveolar; florfenicol; farmacocinética; pulmonar

INTRODUCTION

Bacterial pneumonia is common in modern pork production worldwide, which can cause great economic loss and increased mortality, morbidity (Li et al., 2016LI, X.; XIE, S.; PAN, Y. et al. Preparation, characterization and pharmacokinetics of doxycycline hydrochloride and florfenicol polyvinylpyrroliddone microparticle entrapped with hydroxypropyl-β-cyclodextrin inclusion complexes suspension. Colloid. Surf. B, v.141, p.634-642, 2016.). Some prevalence surveys showed that the morbidity of pig pneumonia ranges from 10% to 45% and mortality from 2% to 20% (Hansen et al., 2010HANSEN, M.S.; PORS, S.E.; JENSEN, H.E. et al. An investigation of the pathology and pathogens associated with porcine respiratory disease complex in Denmark. J. Comp. Pathol., v.143, p.120-131, 2010.). The research has also been shown that the average daily gain (ADG) of affected pigs was reduced by 12.7%~15.9%, while the feed efficiency was reduced by 13.8% (Pointon et al., 1985POINTON, A.M.; HEAP, P.; MCCLOUD, P. Enzootic pneumonia of pigs in South Australia-factors relating to incidence of disease. Aust. Vet. J., v.62, p.98-101, 1985.), a 10% increase in the volume of pneumonic lungs and it was associated with a decrease in daily weight gain by 41.1g (Hill et al., 1992HILL, M.A.; SCHEIDT, A.B.; TECLAW, R.F. et al. Association between growth indicators and volume of lesions in lungs from pigs at slaughter. Am. J. Vet. Res., v.53, p.2221-2223, 1992.). Florfenicol (FFL), a fluorinated derivative of thiamphenicol, has a broad antibacterial spectrum similar to chloramphenicol and has a stronger antibacterial activity than thiamphenicol (Cannon et al., 1990CANNON, M.; HARFORD, S.; DAVIES, J. A comparative study on the inhibitory actions of chloramphenicol, thiamphenicol and some fluorinated derivatives. J. Antimicrob. Chemother., v.26, p.307-317, 1990.). It is intensively used to control the porcine respiratory disease due to the excellent antibacterial activity against the main primary causative bacteria such as Pasteurella multocida, Actinobacillus Pleuropneumoniae, Streptococcus suis, Bordetella bronchiseptica, Haemophilus parasuis, etc (Priebe & Schwarz, 2003; Shin et al., 2005SHIN, S.J.; SANG, G.K.; NABIN, R. et al. Evaluation of the antimicrobial activity of florfenicol against bacteria isolated from bovine and porcine respiratory disease. Vet. Microbiol., v.106, p.73-77, 2005.; Li et al., 2016).

Although the pharmacokinetic (PK) of FFL has been extensively studied in veal calves (Varma et al., 1986VARMA, K.J.; ADAMS, P.E.; POWERS, T.E. et al. Pharmacokinetics of florfenicol in veal calves. J. Vet. Pharmacol. Ther., v.9, p.412-425, 1986.), cows (Soback et al., 1995SOBACK, S.; PAAPE, M.J.; FILEP, R. et al. Florfenicol pharmacokinetics in lactating cows after intravenous, intramuscular and intramammary administration. J. Vet. Pharmacol. Ther., v.18, p.413-417, 1995.), goats (Verma et al., 2009VERMA, S.; AHMAD, A.H.; RAHAL, A. et al. Pharmacokinetics of florfenicol following single dose intravenous and intramuscular administration in goats. J. Appl. Anim. Res., v.36, p.93-96, 2009.), sheep (Lane et al., 2004LANE, V.M.; WETZLICH, S.; CLIFFORD, A. et al. Intravenous and subcutaneous pharmacokinetics of florfenicol in sheep. J. Vet. Pharmacol. Ther., v.27, p.191-196, 2004.), pigs (Liu et al., 2003; Kim et al., 2008KIM, M.H.; GEBRU, E.; CHANG, Z.Q. et al. Comparative pharmacokinetics of tylosin or florfenicol after a single intramuscular administration at two different doses of tylosin-florfenicol combination in pigs. J. Vet. Med. Sci., v.70, p.99-102, 2008.; Li et al., 2016), dogs (Park et al., 2008PARK, B.K.; LIM, J.H.; KIM, M.S. et al. Pharmacokinetics of florfenicol and its metabolite, florfenicol amine, in dogs. Res. Vet. Sci., v.84, p.85-89, 2008.) and broiler chickens (Shen et al., 2003),, reports concerning the PK in the pulmonary tissue are quite few. As we know, the main primary causative bacteria of the pneumonia always could be isolated from the upper respiratory tract such as the tonsils of both infected and healthy animals (Vaillancourt et al., 2015VAILLANCOURT, K.; LEBEL, G.; FRENETTE, M. et al. Suicin 3908, a new lantibiotic produced by a strain of Streptococcus suis serotype 2 isolated from a healthy carrier pig. PLoS One, v.10, p.e0117245, 2015.). Furthermore, FFL may accumulate in a respiratory organs, with the result that the drug concentration at pulmonary tissue was always higher than that in plasma/serum (Afifi & Abo elSooud, 1997AFIFI, N.A.; ABO-ELSOOUD, K.A. Tissue concentrations and pharmacokinetics of florfenicol in broiler chickens. Br. Poult. Sci., v.38, p.425-428, 1997.). So, the prediction of drug concentrations in the lungs from simple extrapolation of the unbound drug fraction in plasma/serum is always not very precise. In addition, knowledge regarding the drug concentrations at a target sites is very important to increase the efficacy of therapeutic interventions and in selection of new drug candidates, several studies have shown that the drug concentrations in the target sites were directly correlated with the clinical efficacy (Barbour et al., 2010BARBOUR, A.; SCAGLIONE, F.; DERENDORF, H. Class-dependent relevance of tissue distribution in the interpretation of anti-infective pharmacokinetic/pharmacodynamic indices. Int. J. Antimicrob. Agents, v.35, p.431-438, 2010.). Therefore, it has practical significance to conduct the PK of FFL in pulmonary tissue.

The pulmonary epithelial lining fluid (PELF) the most important target site for lung infections, and bronchoaveolar lavage (BAL) is an interesting technique for detecting a variety of pulmonary disorders and studying the concentrations of various solutes in the epithelial fluid that lines the surface of the lung (Lee et al., 2015LEE, J.Y.; PARK, H.J.; KIM, Y.K. et al. Cellular profiles of bronchoalveolar lavage fluid and their prognostic significance for non-HIV-infected patients with Pneumocystis jirovecii pneumonia. J. Clin. Microbiol., v.53, p.1310-1316, 2015.), and it has been frequently used to establish an intrapulmonary PK model. In this study, the purpose was to describe the FFL kinetic disposition in both the plasma and pulmonary tissue at 20mg/kg dosage after intramuscular for comparing the PK parameters at the two different tissue and evaluate the effect of anesthesia with ketamine and propofol on the PK of FFL in plasma.

MATERIALS AND METHODS

FFL injection (0.3g/ml) was obtained from Zhejiang Guobang Pharmaceutical Factory Co., Ltd (Zhejiang, China). Atropine injection, ketamine injection and propofol solution were donated from Key Laboratory of Tarim Animal Husbandry Science and Technology of Xinjiang Production & Construction Corps. Ammonia, ethyl acetate and dimethylformamide (DFM) were purchased from Aladdin Biological Engineering Technology & Services Co., Ltd (Shanghai, China). Acetonitrile with liquid chromatography grade were provided by TEDIA (USA). The water for HPLC was prepared with a Milli-Q system. Other chemicals and reagents not specified in the text were of analytical grade or equivalent.

Eighteen healthy castrated crossbred (Duroc × Large White × Landrace) pigs (body weight 16±2kg) were obtained from experimental station of Tarim University (Alar, Xinjiang, China). The animals were housed in laboratory animal rooms of Tarim University’s Animal Teaching Hospital for 7 days to acclimatize. During acclimatization periods, the pigs were kept on basal feed twice daily and water available ad libitum around the clock without any drugs and contaminants. The breed environment temperature and relative humidity were kept at 15~20°C and 80~90%, respectively. After the final sampling, all pigs were immediately euthanized and all experiments protocols concerning the handling of pigs were in accordance with the requirements of the experimental animal ethics/Ethics Committee Animal Science Academy of Xinjiang Uygur Autonomous Region.

Atropine injection (0.05mg/kg) was intramuscular administration for reducing the airway mucus before anesthetic medication. After that the ketamine injection (5mg/kg) was given intramuscularly to get a shallow sedation anesthesia and then intravenous bolus injection administration of the propofol solution (3mg/kg) for general anesthesia. When the pig was completely unconscious, the fiberoptic bronchoscopy (KangmeiGU-180VET) with BAL was performed according to a standardized protocol described previously (Choi et al., 2012CHOI, S.H.; HONG, S.B.; KO, G.B. et al. Viral infection in patients with severe pneumonia requiring intensive care unit admission. Am. J. Resp. Crit. Care, v.186, p.325-332, 2012.; Villarino et al., 2013VILLARINO, N.; MARTÍN-JIMÉNEZ, T. Pharmacokinetics of macrolides in foals. J. Vet. Pharmacol. Ther., v.36, p.1-13, 2013.; Villarino and Martín-Jiménez, 2013). Briefly, three consecutive aliquots (10, 20, and 30mL) of sterile saline solution were instilled into the right middle lobe by the flexible fiber-optic endoscope and the probe following the bronchi until resistance was met. The probe was uncovered from the protective sheath and was visually placed in contact with the bronchus wall for approximately 20sec, and then the fluid retrieved was collected into a 50ml centrifugal tube, transported on wet ice (~0°C) and stored at -20°C for analysis by High Performance Liquid Chromatography (HPLC).

The urea dilution method was used to determine the volume of PELF as described previously (Choi et al., 2012CHOI, S.H.; HONG, S.B.; KO, G.B. et al. Viral infection in patients with severe pneumonia requiring intensive care unit admission. Am. J. Resp. Crit. Care, v.186, p.325-332, 2012.; Lee et al., 2015LEE, J.Y.; PARK, H.J.; KIM, Y.K. et al. Cellular profiles of bronchoalveolar lavage fluid and their prognostic significance for non-HIV-infected patients with Pneumocystis jirovecii pneumonia. J. Clin. Microbiol., v.53, p.1310-1316, 2015.; Zhang et al., 2016ZHANG, P.; HAO, H.; LI, J. et al. The epidemiologic and pharmacodynamic cutoff values of tilmicosin against Haemophilus parasuis. Front. Microbiol., v.7, p.385, 2016. ), which based on the concentration of urea in PELF is considered to be same as the serum urea concentration implying complete distribution. The concentration of urea in plasma and PELF were determined by the urease-glutamate dehydrogenase enzymatic method with an automatic biochemical analyzer (synchroncx4pro; Beckman) at the Tarim University’s Animal Teaching Hospital (Alar, Xinjiang, China). And the volume of PELF is adjusted for excess exogenous water using the following equation (Kiem & Schentag, 2008KIEM, S.; SCHENTAG, J. Interpretation of antibiotic concentration ratios measured in epithelial lining fluid. Antimicrob. Agents Chemother., v.52, p.24-36, 2008.): V_PELF=V_BAL×Urea_BAL/Urea_serum, where Urea_BAL and Urea_serum are the concentrations of urea in BAL fluid and serum, respectively.

Eighteen pigs were randomly divided into 3 groups with 6 animals in each group (first group for plasma PK study without anesthesia, second group for plasma PK study with anesthesia and another group for pulmonary PK study). The approved label dose (20mg/kg) of FFL injection was intramuscularly administrated to one side of the neck of the pigs. At different time points (0, 0.25, 0.5, 0.75, 1, 2, 4, 6, 9, 12, 24, 36 and 48hr for blood samples, 0.5, 2, 4, 6, 9, 12, 24, 36, 48, 72, and 96hr for PELF samples) post administration, blood samples (1ml) were taken from anterior vena cava and PELF samples were collected by BAL. Plasma was separated from blood by centrifugation at 3000 ×g for 10min and was kept at -70°C until assay, and the PELF was centrifuged at 400×g for 10min and stored at -70°C until analysis. The drug levels in plasma and PELF all were determined by HPLC. The data on plasma and pulmonary drug concentrations-time were analyzed by using the Winnonlin (Version 5.2.1, Pharsight Corporation, Mountain View, CA, USA) computer software.

FFL were quantified using a Waters 2695 series HPLC and a Waters 2587UV detector set at a wavelength of 254nm. The chromatographic separation was achieved with an analytical ZORBAX SB C18 column (250 × 4.6mm, i.d. 5μm; Agilent Technology, USA) at 25°C. The mobile phase of FFL was acetonitrile and 0.1% ammonia solution with the proportion of 25/75 (V/V). The flow rate and injection volume of the drug were 1ml/min and 20μl.

Plasma (0.2ml) was extracted with ethyl acetate (0.4ml) twice. After centrifugation, supernatant was evaporated and resuspended in the mobile phase (0.2ml). PELF (0.5ml) was extracted with DFM (2ml), and then centrifuged, evaporated and resuspended in a same manner. The limit of determination (LOD) was 0.02μg/ml and the limit of quantification (LOQ) was 0.03μg/ml both in plasma and PELF. Standard curves were linear from 0.03 to 10μg/ml both in plasma (R ²=0.9999) and PELF (R ²=0.9998). The inter-day variation for determination in plasma ranged from 0.68 to 1.03% and PELF 0.17 to 0.82%, respectively. The recovery of FFL in plasma ranged from 91.09±2.15% to 93.27±1.58% and in PELF from 97.49±1.26 to 98.33±0.94%, respectively.

Data are presented as mean ± S.D. (standard deviation). The Prism 5.0 software (GraphPad Software, San Diego, Calif.) was used to perform statistical analysis, data processing as well as the graph representation. In each case, a two-tailed t test was used to assess the significance of difference in the PK parameter values between the PELF, plasma with anesthesia and plasma without anesthesia. A P value of 0.05 was regarded as significant.

RESULTS

Blood samples at all time points were eligible for analysis. Both plasma and pulmonary drug concentration-time profiles of FFL were illustrated in Table 2 and Figure 1. After intramuscular administration, the FFL in plasma without anesthesia and with anesthesia were reached to the peak concentrations of 4.73±0.42μg/ml at 3.33±1.03hr and 4.65±0.34μg/ml at 3.67±0.82hr, and then maintained above the LOQ of 0.03μg/ml for 36hr and 48hr, respectively. The main PK parameters were depicted in Table 2. The area under the concentration-time curve (AUC_0-t), elimination half-life (T_½ke) and mean residence time (MRT) of FFL in plasma without anesthesia and with anesthesia were 61.31±4.14 vs 69.45±4.36μg·hr/ml, 7.89±0.95 vs 9.87±1.70hr and 10.36±0.42 vs 12.75±0.35hr, respectively. And there was no statistically significant difference between the PK profiles of FFL for the anesthetized and unanesthetized pigs.

Figure 1
Semi-logarithmic plots of florfenicol in plasma and pulmonary following intramuscular administration of a single dose of 20mg/kg body weight in pigs. Drugs concentrations were expressed means ± standard deviations (n=6).

The urease-glutamate dehydrogenase enzymatic in PELF samples at all time points was eligible for determination, and the concentration of urea in plasma and PELF at all time points was illustrated in Table 1. The urea concentration in plasma of pre-administration group was 5.38±0.49mmol/l, and the urea concentration in PELF of all time points was 0.49±0.07mmol/l, respectively. As shown in Table 1, the concentration of FFL in PELF was diluted about 10 times by sterile saline solution compare to the drug concentration in plasma through the urea dilution method.

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Table 1
Urea concentration in BALF and plasma (mmol/l)

Anesthesia scheme was qualified for PELF sampling in the pulmonary PK study and all PELF samples were eligible for analysis. After drug administration, FFL in PELF was reached to the peak concentrations of 5.94±0.86μg/ml at 4.33±0.82hr, then decreased slowly and sustained about 0.23μg/ml for 48hr. As shown in Table 1, the main PK parameters such as AUC_0-t, T_½ke and MRT of FFL in PELF were 85.03±9.26μg·hr/ml, 10.69±1.60hr and 14.46±1.26hr, respectively.

DISCUSSION

FFL was approved worldwide for the control of bacterial respiratory tract infections in pigs (Ali et al., 2003; Shin et al., 2005SHIN, S.J.; SANG, G.K.; NABIN, R. et al. Evaluation of the antimicrobial activity of florfenicol against bacteria isolated from bovine and porcine respiratory disease. Vet. Microbiol., v.106, p.73-77, 2005.; Li et al., 2016LI, X.; XIE, S.; PAN, Y. et al. Preparation, characterization and pharmacokinetics of doxycycline hydrochloride and florfenicol polyvinylpyrroliddone microparticle entrapped with hydroxypropyl-β-cyclodextrin inclusion complexes suspension. Colloid. Surf. B, v.141, p.634-642, 2016.. The PK of FFL has been extensively investigated in many species, including veal calves (Varma et al., 1986VARMA, K.J.; ADAMS, P.E.; POWERS, T.E. et al. Pharmacokinetics of florfenicol in veal calves. J. Vet. Pharmacol. Ther., v.9, p.412-425, 1986.), cows (Soback et al., 1995SOBACK, S.; PAAPE, M.J.; FILEP, R. et al. Florfenicol pharmacokinetics in lactating cows after intravenous, intramuscular and intramammary administration. J. Vet. Pharmacol. Ther., v.18, p.413-417, 1995.), goats (Verma et al., 2009VERMA, S.; AHMAD, A.H.; RAHAL, A. et al. Pharmacokinetics of florfenicol following single dose intravenous and intramuscular administration in goats. J. Appl. Anim. Res., v.36, p.93-96, 2009.), sheep (Lane et al., 2004LANE, V.M.; WETZLICH, S.; CLIFFORD, A. et al. Intravenous and subcutaneous pharmacokinetics of florfenicol in sheep. J. Vet. Pharmacol. Ther., v.27, p.191-196, 2004.), pigs (Liu et al., 2003; Kim et al., 2008KIM, M.H.; GEBRU, E.; CHANG, Z.Q. et al. Comparative pharmacokinetics of tylosin or florfenicol after a single intramuscular administration at two different doses of tylosin-florfenicol combination in pigs. J. Vet. Med. Sci., v.70, p.99-102, 2008.; Li et al., 2016), dogs (Park et al., 2008PARK, B.K.; LIM, J.H.; KIM, M.S. et al. Pharmacokinetics of florfenicol and its metabolite, florfenicol amine, in dogs. Res. Vet. Sci., v.84, p.85-89, 2008.) and broiler chickens (Shen et al., 2003), but most previous PK studies only focused on the plasma/serum concentration of the active substance but ignored the concentrations of antimicrobial agents in its target sites. Nevertheless, drug concentrations at the site of infection are clinically relevant (Drusano, 2005), as it is broadly accepted that biophase drug kinetics is the primary controller in the antimicrobial response (Müller et al., 2004MÜLLER, M.; PEÑA, A.D.; DERENDORF, H. Issues in Pharmacokinetics and pharmacodynamics of anti-infective agents: distribution in Tissue. Antimicrob. Agents Chemother., v.48, p.1441-1453, 2004.; Drusano, 2007).. Innovatively, the PKs parameters of FFL in both plasma and pulmonary tissue were analyzed in current study.

FFL deposition in plasma after the i.m. administration was well described by the one-compartment model with a first order absorption, exhibiting a markedly elongated the elimination half-life (T_½ke) and a high bioavailability, indicating that FFL underwent a slow elimination phase but a completely systematic utilization in both anesthetic and non-anaesthetic pigs. The T_½ke of FFL in plasma of unanaesthetic pigs calculated in the present study was 7.89±0.95hr, similar to previous study of 9.35±1.32hr 32hr (Li et al., 2016LI, X.; XIE, S.; PAN, Y. et al. Preparation, characterization and pharmacokinetics of doxycycline hydrochloride and florfenicol polyvinylpyrroliddone microparticle entrapped with hydroxypropyl-β-cyclodextrin inclusion complexes suspension. Colloid. Surf. B, v.141, p.634-642, 2016.) and 5.29±2.58hr (Kim et al., 2008KIM, M.H.; GEBRU, E.; CHANG, Z.Q. et al. Comparative pharmacokinetics of tylosin or florfenicol after a single intramuscular administration at two different doses of tylosin-florfenicol combination in pigs. J. Vet. Med. Sci., v.70, p.99-102, 2008.) in pigs by the same route and dosage. And the area under the concentration-time curve (AUC_0-t) was 61.31±4.14μg·hr/ml, in agreement with 60.70±6.04 (Li et al., 2016), 60.9±18.9 (Kim et al., 2008) and 68.61±10.36μg·hr/ml (Liu et al., 2003) in pigs. Maximal drug concentration (C_max), time to reach C_max (T_max) and the absorption half-life (T_½ka) value of 4.73±0.42μg/ml, 3.33±1.03hr and 0.62±0.09hr obtained for unanaesthetic pigs weren't appear to be much different from the previous researches. Other PK parameters such as mean residence time (MRT), apparent volume of distribution (Vd/F) and the clearance rate (Cl/F) were significantly difference with previously reported that maybe due to the biases introduced by individual animals or pharmaceutical factors in the special formula as well as the analytical methods.

In respiratory conditions, the target tissue is the lung, in particular the extracellular fluid such as the epithelial lining fluid that covers the route of entry and colonization of microorganisms that cause pneumonia (Villarino et al., 2013VILLARINO, N.; MARTÍN-JIMÉNEZ, T. Pharmacokinetics of macrolides in foals. J. Vet. Pharmacol. Ther., v.36, p.1-13, 2013.). Concentrations of antibiotics in PELF for extracellular pathogens such as Actinobacillus Pleuropneumoniae are thought to reflect the antibiotic activity in pneumonia. Therefore, predictions about antibacterial efficacy shouldn’t be performed by using plasma/serum drug concentrations as a surrogate for the drug concentration at the site of infection.

Moreover, it's important to note, the total antibiotic concentration measurements from tissue homogenate cannot be normally considered as valid, and results or interpretations based on them may be ambiguous. The main reason is that lung homogenate is a hybrid heterogeneous sample, as it encompasses multiple compartments. For most of the microorganisms, the actual target biophase is the interstitial space fluid; therefore, effective concentrations might be under or overestimated. BAL is an interesting technique for detecting a variety of pulmonary disorders and studying the concentrations of various solutes in the epithelial fluid that lines the surface of the lung (Lee et al., 2015LEE, J.Y.; PARK, H.J.; KIM, Y.K. et al. Cellular profiles of bronchoalveolar lavage fluid and their prognostic significance for non-HIV-infected patients with Pneumocystis jirovecii pneumonia. J. Clin. Microbiol., v.53, p.1310-1316, 2015.), and it has frequently been used to establish an intrapulmonary PK model.

In PELF sampling, anesthesia was maintained for 10~20min in a different time points with ketamine injection and intermittently intravenous propofol solution. Statistical results show that there was no statistically significant difference between the PK profiles of FFL in plasma for the anesthetized and unanesthetized pigs shown in Table 2. Mostly, it has been suggested that the PK profile of FFL in PELF was not interfered after the administration of anesthetic agent with ketamine and propofol. FFL in PELF was swiftly reached to the C_max of 5.94±0.86μg/ml at about 4.3hr, decreased slowly and continued for 48hr. In contrast, the drug in plasma of anaesthetic pigs was more quickly reached to the C_max of 4.65±0.34μg/ml at 3.67±0.82hr, and then declined rapidly below the LOD at 36hr post administration. This result suggested that the drug penetrated rapidly into the pulmonary, but concentration declined slowly. And the drug concentration decay faster in plasma than in the pulmonary. Furthermore, FFL concentration in the PELF exceeded that in plasma, this demonstrates that there is not a rapid drug equilibration between both compartments after T_max. And this result might indicate that different factors, other than/or in addition to simple drug diffusion, intervene in the process of movement of the FFL in and out between the plasma and the pulmonary compartments. Higher AUC_0-t, MRT, C_max and T_½ke could be obtained in PELF (85.03±9.26μg·hr/ml, 14.46±1.26hr, 5.94±0.86μg/ml and 10.69±1.60hr) when compared to plasma in anaesthetic pigs (69.45±4.36μg·hr/ml, 12.75±0.35hr, 4.65±0.34μg/ml and 9.87±1.70hr). In total, all these results suggest that FFL not only rapidly distributed in respiratory organs at high concentrations but also resided in epithelial lining fluid for a long time (>48hr). And this characteristic is exactly why the FFL could extensive used in worldwide for the prophylaxis and treatment of bacterial respiratory tract infections in pigs.

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Table 2
PK parameters of florfenicol in plasma and PELF following intramuscular administration of a single dose of 20mg/kg body weight in pigs. Values were means ± standard deviations (n=6)

It is of interest that, whilst FFL has been in widespread use in pig industry for 20 years and whilst resistance occurrence and mechanisms have been described (Kehrenberg et al., 2004KEHRENBERG, C.; MUMME, J.; WALLMANN, J. et al. Monitoring of florfenicol susceptibility among bovine and porcine respiratory tract pathogens collected in Germany during the years 2002 and 2003. J. Antimicrob. Chemother., v.54, p.572-574, 2004.; Schwarz et al., 2004SCHWARZ, S.; KEHRENBERG, C.; DOUBLET, B. et al. Molecular basis of bacterial resistance to chloramphenicol and florfenicol. FEMS. Microbiol. Rev., v.28, p.519-542, 2004.; it have been documented that FFL have a high level of activity against Actinobacillus Pleuropneumoniae, Haemophilus parasuis, Pasteurella multocida, etc with MIC ranging between 0.25 and 0.5μg/ml (Sidhu et al., 2009SIDHU, P.K.; ILLAMBAS, J.; POTTER, T. et al. Pharmacokinetics and pharmacodynamics of florfenicol in calves. J. Vet. Pharmacol. Ther., v.32, p.67-68, 2009.; Li et al., 2016LI, X.; XIE, S.; PAN, Y. et al. Preparation, characterization and pharmacokinetics of doxycycline hydrochloride and florfenicol polyvinylpyrroliddone microparticle entrapped with hydroxypropyl-β-cyclodextrin inclusion complexes suspension. Colloid. Surf. B, v.141, p.634-642, 2016.). Basically, present study demonstrated that average FFL concentrations in PELF exceeded about 4~10×MIC and 1~4×MIC for a periods between 0-12 and 24-48hr, respectively. In addition, FFL was classified as typical concentration-dependent drug (Sidhu et al., 2009), the initially reported AUC/MIC and C_max/MIC are a better predictors than T > MIC for the antibacterial effect, and on the basis of the FFL concentrations in PELF in present study and MIC report in literature, in vivo AUC₂₄/MIC was about 130~260hr (Sang et al., 2016SANG, K.; HAO, H.; HUANG, L. et al. Pharmacokinetic- pharmacodynamic modeling of enrofloxacin against escherichia coli in broilers. Front. Vet. Sci., v.2, p.80, 2016. ), which means that the dose of 20mg/kg/bw administered intramuscularly should be to ensure the success of therapy and preventing the emergence of resistance.

In conclusion, this study describes the disposition of FFL in PELF by use of the BAL technique and intrapulmonary model on the basis of our anesthesia method. PK of FFL in PELF in present study was demonstrated that FFL penetrated rapidly into the pulmonary and the drug concentration decay faster in plasma than in the pulmonary, and the PK profile of FFL in swine was not interfered after administration of anesthetic agent. This was considered to be acceptable, the risk of therapeutic failures and antimicrobial resistance to FFL could be reduced using the optimized dosage regimens based on these data. At the same time, this means of pulmonary PK studying and anesthesia protocols have leading meaning and practicality value to research and develop other antibiotics for respiratory infections.

ACKNOWLEDGEMENTS

This article was supported by the National Natural Science Foundation of China (31660729) and the Youth Program for Scholar and Innovative Research Teams in Tarim University (TDZKQN201603). Scientific and technical help from the staff in the laboratories of Key Laboratory of Tarim Animal Husbandry Science and Technology of Xinjiang Production & Construction Corps is gratefully acknowledged in this study.

REFERENCES

AFIFI, N.A.; ABO-ELSOOUD, K.A. Tissue concentrations and pharmacokinetics of florfenicol in broiler chickens. Br. Poult. Sci., v.38, p.425-428, 1997.
ALI, B.H.; AL-QARAWI. A.A.; HASHAAD, M. Comparative plasma pharmacokinetics and tolerance of florfenicol following intramuscular and intravenous administration to camels, sheep and goats. Vet. Res. Commun., v.27, p.475-483, 2013.
BARBOUR, A.; SCAGLIONE, F.; DERENDORF, H. Class-dependent relevance of tissue distribution in the interpretation of anti-infective pharmacokinetic/pharmacodynamic indices. Int. J. Antimicrob. Agents, v.35, p.431-438, 2010.
CANNON, M.; HARFORD, S.; DAVIES, J. A comparative study on the inhibitory actions of chloramphenicol, thiamphenicol and some fluorinated derivatives. J. Antimicrob. Chemother., v.26, p.307-317, 1990.
CHOI, S.H.; HONG, S.B.; KO, G.B. et al. Viral infection in patients with severe pneumonia requiring intensive care unit admission. Am. J. Resp. Crit. Care, v.186, p.325-332, 2012.
DRUSANO, G.L. Infection site concentrations: their therapeutic importance and the macrolide and macrolide-like class of antibiotics. Pharmacotherapy, v.25, p.150S-158S, 2015.
DRUSANO, G.L. Pharmacokinetics and pharmacodynamics of antimicrobials. Clin. Infect. Dis., v.45, Suppl.1, p.89-93, 2007.
HANSEN, M.S.; PORS, S.E.; JENSEN, H.E. et al. An investigation of the pathology and pathogens associated with porcine respiratory disease complex in Denmark. J. Comp. Pathol., v.143, p.120-131, 2010.
HILL, M.A.; SCHEIDT, A.B.; TECLAW, R.F. et al. Association between growth indicators and volume of lesions in lungs from pigs at slaughter. Am. J. Vet. Res., v.53, p.2221-2223, 1992.
KEHRENBERG, C.; MUMME, J.; WALLMANN, J. et al. Monitoring of florfenicol susceptibility among bovine and porcine respiratory tract pathogens collected in Germany during the years 2002 and 2003. J. Antimicrob. Chemother., v.54, p.572-574, 2004.
KEHRENBERG, C.; SCHWARZ, S. Plasmid-borne florfenicol resistance in Pasteurella multocida. J. Antimicrob. Chemother., v.55, p.773-775, 2005.
KIEM, S.; SCHENTAG, J. Interpretation of antibiotic concentration ratios measured in epithelial lining fluid. Antimicrob. Agents Chemother., v.52, p.24-36, 2008.
KIM, M.H.; GEBRU, E.; CHANG, Z.Q. et al. Comparative pharmacokinetics of tylosin or florfenicol after a single intramuscular administration at two different doses of tylosin-florfenicol combination in pigs. J. Vet. Med. Sci., v.70, p.99-102, 2008.
LANE, V.M.; WETZLICH, S.; CLIFFORD, A. et al. Intravenous and subcutaneous pharmacokinetics of florfenicol in sheep. J. Vet. Pharmacol. Ther., v.27, p.191-196, 2004.
LANE, V.M.; WETZLICH, S.; CLIFFORD, A. et al. Intravenous and subcutaneous pharmacokinetics of florfenicol in sheep. J. Vet. Pharmacol. Ther., v.27, p.191-196, 2004.
LEE, J.Y.; PARK, H.J.; KIM, Y.K. et al. Cellular profiles of bronchoalveolar lavage fluid and their prognostic significance for non-HIV-infected patients with Pneumocystis jirovecii pneumonia. J. Clin. Microbiol., v.53, p.1310-1316, 2015.
LI, X.; XIE, S.; PAN, Y. et al. Preparation, characterization and pharmacokinetics of doxycycline hydrochloride and florfenicol polyvinylpyrroliddone microparticle entrapped with hydroxypropyl-β-cyclodextrin inclusion complexes suspension. Colloid. Surf. B, v.141, p.634-642, 2016.
LIU, J.; FUNG, K.F.; CHEN, Z. et al. Pharmacokinetics of florfenicol in healthy pigs and in pigs experimentally infected with Actinobacillus pleuropneumoniae. Antimicrob. Agents Chemother., v.47, p.820-823, 2013.
MÜLLER, M.; PEÑA, A.D.; DERENDORF, H. Issues in Pharmacokinetics and pharmacodynamics of anti-infective agents: distribution in Tissue. Antimicrob. Agents Chemother., v.48, p.1441-1453, 2004.
PARK, B.K.; LIM, J.H.; KIM, M.S. et al. Pharmacokinetics of florfenicol and its metabolite, florfenicol amine, in dogs. Res. Vet. Sci., v.84, p.85-89, 2008.
POINTON, A.M.; HEAP, P.; MCCLOUD, P. Enzootic pneumonia of pigs in South Australia-factors relating to incidence of disease. Aust. Vet. J., v.62, p.98-101, 1985.
PRIEBE, S.; SCHWARZ, S. In vitro activities of florfenicol against bovine and porcine respiratory tract pathogens. Antimicrob. Agents Chemother., v.47, p.2703-2705, 2013.
SANG, K.; HAO, H.; HUANG, L. et al. Pharmacokinetic- pharmacodynamic modeling of enrofloxacin against escherichia coli in broilers. Front. Vet. Sci., v.2, p.80, 2016.
SCHWARZ, S.; KEHRENBERG, C.; DOUBLET, B. et al. Molecular basis of bacterial resistance to chloramphenicol and florfenicol. FEMS. Microbiol. Rev., v.28, p.519-542, 2004.
SHEN, J.; HU, D.; WU, X. et al. Bioavailability and pharmacokinetics of florfenicol in broiler chickens. J. Vet. Pharmacol. Ther., v.26, p.337-341, 2013.
SHIN, S.J.; SANG, G.K.; NABIN, R. et al. Evaluation of the antimicrobial activity of florfenicol against bacteria isolated from bovine and porcine respiratory disease. Vet. Microbiol., v.106, p.73-77, 2005.
SIDHU, P.K.; ILLAMBAS, J.; POTTER, T. et al. Pharmacokinetics and pharmacodynamics of florfenicol in calves. J. Vet. Pharmacol. Ther., v.32, p.67-68, 2009.
SOBACK, S.; PAAPE, M.J.; FILEP, R. et al. Florfenicol pharmacokinetics in lactating cows after intravenous, intramuscular and intramammary administration. J. Vet. Pharmacol. Ther., v.18, p.413-417, 1995.
VAILLANCOURT, K.; LEBEL, G.; FRENETTE, M. et al. Suicin 3908, a new lantibiotic produced by a strain of Streptococcus suis serotype 2 isolated from a healthy carrier pig. PLoS One, v.10, p.e0117245, 2015.
VARMA, K.J.; ADAMS, P.E.; POWERS, T.E. et al. Pharmacokinetics of florfenicol in veal calves. J. Vet. Pharmacol. Ther., v.9, p.412-425, 1986.
VERMA, S.; AHMAD, A.H.; RAHAL, A. et al. Pharmacokinetics of florfenicol following single dose intravenous and intramuscular administration in goats. J. Appl. Anim. Res., v.36, p.93-96, 2009.
VILLARINO, N.; LESMAN, S.; FIELDER, A. et al. Pulmonary pharmacokinetics of tulathromycin in swine. Part 2: Intra-airways compartments. J. Vet. Pharmacol. Ther., v.36, p.340-349, 2013.
VILLARINO, N.; MARTÍN-JIMÉNEZ, T. Pharmacokinetics of macrolides in foals. J. Vet. Pharmacol. Ther., v.36, p.1-13, 2013.
ZHANG, P.; HAO, H.; LI, J. et al. The epidemiologic and pharmacodynamic cutoff values of tilmicosin against Haemophilus parasuis. Front. Microbiol., v.7, p.385, 2016.

Publication Dates

Publication in this collection
Sep-Oct 2018

History

Received
28 Jan 2017
Accepted
30 Jan 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] AFIFI, N.A.; ABO-ELSOOUD, K.A. Tissue concentrations and pharmacokinetics of florfenicol in broiler chickens. Br. Poult. Sci., v.38, p.425-428, 1997.

[2] ALI, B.H.; AL-QARAWI. A.A.; HASHAAD, M. Comparative plasma pharmacokinetics and tolerance of florfenicol following intramuscular and intravenous administration to camels, sheep and goats. Vet. Res. Commun., v.27, p.475-483, 2013.

[3] BARBOUR, A.; SCAGLIONE, F.; DERENDORF, H. Class-dependent relevance of tissue distribution in the interpretation of anti-infective pharmacokinetic/pharmacodynamic indices. Int. J. Antimicrob. Agents, v.35, p.431-438, 2010.

[4] CANNON, M.; HARFORD, S.; DAVIES, J. A comparative study on the inhibitory actions of chloramphenicol, thiamphenicol and some fluorinated derivatives. J. Antimicrob. Chemother., v.26, p.307-317, 1990.

[5] CHOI, S.H.; HONG, S.B.; KO, G.B. et al. Viral infection in patients with severe pneumonia requiring intensive care unit admission. Am. J. Resp. Crit. Care, v.186, p.325-332, 2012.

[6] DRUSANO, G.L. Infection site concentrations: their therapeutic importance and the macrolide and macrolide-like class of antibiotics. Pharmacotherapy, v.25, p.150S-158S, 2015.

[7] DRUSANO, G.L. Pharmacokinetics and pharmacodynamics of antimicrobials. Clin. Infect. Dis., v.45, Suppl.1, p.89-93, 2007.

[8] HANSEN, M.S.; PORS, S.E.; JENSEN, H.E. et al. An investigation of the pathology and pathogens associated with porcine respiratory disease complex in Denmark. J. Comp. Pathol., v.143, p.120-131, 2010.

[9] HILL, M.A.; SCHEIDT, A.B.; TECLAW, R.F. et al. Association between growth indicators and volume of lesions in lungs from pigs at slaughter. Am. J. Vet. Res., v.53, p.2221-2223, 1992.

[10] KEHRENBERG, C.; MUMME, J.; WALLMANN, J. et al. Monitoring of florfenicol susceptibility among bovine and porcine respiratory tract pathogens collected in Germany during the years 2002 and 2003. J. Antimicrob. Chemother., v.54, p.572-574, 2004.

[11] KEHRENBERG, C.; SCHWARZ, S. Plasmid-borne florfenicol resistance in Pasteurella multocida. J. Antimicrob. Chemother., v.55, p.773-775, 2005.

[12] KIEM, S.; SCHENTAG, J. Interpretation of antibiotic concentration ratios measured in epithelial lining fluid. Antimicrob. Agents Chemother., v.52, p.24-36, 2008.

[13] KIM, M.H.; GEBRU, E.; CHANG, Z.Q. et al. Comparative pharmacokinetics of tylosin or florfenicol after a single intramuscular administration at two different doses of tylosin-florfenicol combination in pigs. J. Vet. Med. Sci., v.70, p.99-102, 2008.

[14] LANE, V.M.; WETZLICH, S.; CLIFFORD, A. et al. Intravenous and subcutaneous pharmacokinetics of florfenicol in sheep. J. Vet. Pharmacol. Ther., v.27, p.191-196, 2004.

[15] LANE, V.M.; WETZLICH, S.; CLIFFORD, A. et al. Intravenous and subcutaneous pharmacokinetics of florfenicol in sheep. J. Vet. Pharmacol. Ther., v.27, p.191-196, 2004.

[16] LEE, J.Y.; PARK, H.J.; KIM, Y.K. et al. Cellular profiles of bronchoalveolar lavage fluid and their prognostic significance for non-HIV-infected patients with Pneumocystis jirovecii pneumonia. J. Clin. Microbiol., v.53, p.1310-1316, 2015.

[17] LI, X.; XIE, S.; PAN, Y. et al. Preparation, characterization and pharmacokinetics of doxycycline hydrochloride and florfenicol polyvinylpyrroliddone microparticle entrapped with hydroxypropyl-β-cyclodextrin inclusion complexes suspension. Colloid. Surf. B, v.141, p.634-642, 2016.

[18] LIU, J.; FUNG, K.F.; CHEN, Z. et al. Pharmacokinetics of florfenicol in healthy pigs and in pigs experimentally infected with Actinobacillus pleuropneumoniae. Antimicrob. Agents Chemother., v.47, p.820-823, 2013.

[19] MÜLLER, M.; PEÑA, A.D.; DERENDORF, H. Issues in Pharmacokinetics and pharmacodynamics of anti-infective agents: distribution in Tissue. Antimicrob. Agents Chemother., v.48, p.1441-1453, 2004.

[20] PARK, B.K.; LIM, J.H.; KIM, M.S. et al. Pharmacokinetics of florfenicol and its metabolite, florfenicol amine, in dogs. Res. Vet. Sci., v.84, p.85-89, 2008.

[21] POINTON, A.M.; HEAP, P.; MCCLOUD, P. Enzootic pneumonia of pigs in South Australia-factors relating to incidence of disease. Aust. Vet. J., v.62, p.98-101, 1985.

[22] PRIEBE, S.; SCHWARZ, S. In vitro activities of florfenicol against bovine and porcine respiratory tract pathogens. Antimicrob. Agents Chemother., v.47, p.2703-2705, 2013.

[23] SANG, K.; HAO, H.; HUANG, L. et al. Pharmacokinetic- pharmacodynamic modeling of enrofloxacin against escherichia coli in broilers. Front. Vet. Sci., v.2, p.80, 2016.

[24] SCHWARZ, S.; KEHRENBERG, C.; DOUBLET, B. et al. Molecular basis of bacterial resistance to chloramphenicol and florfenicol. FEMS. Microbiol. Rev., v.28, p.519-542, 2004.

[25] SHEN, J.; HU, D.; WU, X. et al. Bioavailability and pharmacokinetics of florfenicol in broiler chickens. J. Vet. Pharmacol. Ther., v.26, p.337-341, 2013.

[26] SHIN, S.J.; SANG, G.K.; NABIN, R. et al. Evaluation of the antimicrobial activity of florfenicol against bacteria isolated from bovine and porcine respiratory disease. Vet. Microbiol., v.106, p.73-77, 2005.

[27] SIDHU, P.K.; ILLAMBAS, J.; POTTER, T. et al. Pharmacokinetics and pharmacodynamics of florfenicol in calves. J. Vet. Pharmacol. Ther., v.32, p.67-68, 2009.

[28] SOBACK, S.; PAAPE, M.J.; FILEP, R. et al. Florfenicol pharmacokinetics in lactating cows after intravenous, intramuscular and intramammary administration. J. Vet. Pharmacol. Ther., v.18, p.413-417, 1995.

[29] VAILLANCOURT, K.; LEBEL, G.; FRENETTE, M. et al. Suicin 3908, a new lantibiotic produced by a strain of Streptococcus suis serotype 2 isolated from a healthy carrier pig. PLoS One, v.10, p.e0117245, 2015.

[30] VARMA, K.J.; ADAMS, P.E.; POWERS, T.E. et al. Pharmacokinetics of florfenicol in veal calves. J. Vet. Pharmacol. Ther., v.9, p.412-425, 1986.

[31] VERMA, S.; AHMAD, A.H.; RAHAL, A. et al. Pharmacokinetics of florfenicol following single dose intravenous and intramuscular administration in goats. J. Appl. Anim. Res., v.36, p.93-96, 2009.

[32] VILLARINO, N.; LESMAN, S.; FIELDER, A. et al. Pulmonary pharmacokinetics of tulathromycin in swine. Part 2: Intra-airways compartments. J. Vet. Pharmacol. Ther., v.36, p.340-349, 2013.

[33] VILLARINO, N.; MARTÍN-JIMÉNEZ, T. Pharmacokinetics of macrolides in foals. J. Vet. Pharmacol. Ther., v.36, p.1-13, 2013.

[34] ZHANG, P.; HAO, H.; LI, J. et al. The epidemiologic and pharmacodynamic cutoff values of tilmicosin against Haemophilus parasuis. Front. Microbiol., v.7, p.385, 2016.

Time	1#	2#	3#	4#	5#	6#
Urea concentration in BALF (mmol/l)
0.5 hr	0.48	0.42	0.49	0.41	0.39	0.41
2 hr	0.51	0.37	0.41	0.35	0.45	0.46
4 hr	0.46	0.52	0.48	0.52	0.51	0.53
6 hr	0.56	0.52	0.53	0.51	0.45	0.48
9 hr	0.53	0.49	0.62	0.47	0.41	0.39
12 hr	0.62	0.57	0.52	0.55	0.48	0.47
24 hr	0.53	0.55	0.48	0.49	0.64	0.61
36 hr	0.48	0.47	0.39	0.62	0.45	0.55
48 hr	0.51	0.49	0.47	0.48	0.44	0.62
Urea concentration in plasma (mmol/l)
	4.72	5.97	5.59	5.66	4.83	5.49

PK parameters	Plasma without anesthesia	Plasma with anesthesia	PELF with anesthesia
MRT (hr)	10.36±0.42	12.75±0.35	14.46±1.26*
AUC_0-24 (μg·hr/ml)	54.66±3.42	57.27±3.11	64.53±5.83
AUC_0-t (μg·hr/ml)	61.31±4.14	69.45±4.36	85.03±9.26*
C_max (μg/ml)	4.73±0.42	4.65±0.34	5.94±0.86*
T_max (hr)	3.33±1.03	3.67±0.82	4.33±0.82*
T_½ka (hr)	0.62±0.09	0.56±0.10	0.76±0.12*
T_½ke (hr)	7.89±0.95	9.87±1.70﹟	10.69±1.60*
Vd/F (l/kg)	3.55±0.39	3.47±0.49	3.49±0.53
Cl/F (l/hr/kg)	0.31±0.02	0.26±0.02	0.23±0.02

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