Antibiotics and efflux: combined spectrofluorimetry and mass spectrometry to evaluate the involvement of concentration and efflux activity in antibiotic intracellular accumulation.

Background: In Gram-negative bacteria, passing through the double membrane barrier to reach the inhibitory concentration inside the bacterium is a pivotal step for antibiotic activity. Spectrofluorimetry has been developed to follow fluoroquinolone accumulation inside bacteria using intrinsic bacterial fluorescence as an internal standard. However, adaptation for non-fluorescent antibiotics is needed; quantitative methods based on MS offer the possibility of expanding the detection range obtained by spectrofluorimetry. Objectives: To validate, with spectrofluorimetry, the use of MS to measure antibiotic accumulation in cells and to determine the relationship between antibiotic concentrations and the amount of intrabacterial accumulation in different efflux backgrounds on the same batch of molecules. Methods: Spectrofluorimetry was performed in parallel with MS on the same samples to measure the ciprofloxacin and fleroxacin accumulation in cells expressing various efflux pump levels. A microplate protocol was set up to determine the antibiotic accumulation as a function of external antibiotic concentrations. Results: A correlation existed between the data obtained with spectrofluorimetry and MS, whatever the efflux pump or tested antibiotic. The results highlighted different dynamics of uptake between ciprofloxacin and fleroxacin as well as the relationship between the level of efflux activity and antibiotic accumulation. Conclusions: We have developed a microplate protocol and cross-validated two complementary methods: spectrofluorimetry, which contains a reliable internal standard; and MS, which allows detection of low antibiotic amounts. These assays allow study of the dose effect and the efflux impact on the intrabacterial accumulation of antibiotics.

First population pharmacokinetic analysis showing increased quinolone metabolite formation and clearance in patients with cystic fibrosis compared to healthy volunteers.

Understanding the pharmacokinetics in patients with cystic fibrosis (CF) is important for dosing. For antibiotics with extensive metabolism, however, a comparison of metabolite formation and elimination between patients with CF and healthy volunteers has never been performed via population modeling. We aimed to compare the population pharmacokinetics of fleroxacin and its N­oxide and demethyl metabolites between patients with CF and healthy volunteers. Our analysis included eleven adult patients with CF and twelve healthy volunteers who received 800 mg fleroxacin as a single oral dose followed by five doses every 24 h from a previously published study. All plasma concentrations and amounts in urine for fleroxacin and its metabolites were simultaneously modelled. The estimates below accounted for differences in body size and body composition via allometric scaling by lean body mass. Oral absorption was slower in patients with CF than in healthy volunteers. For fleroxacin, the population mean in patients with CF divided by that in healthy volunteers was 1.12 for renal clearance, 1.01 for linear nonrenal clearance, 0.83 for saturable exsorption clearance into intestine, and 0.81 for volume of distribution. The formation clearances of N­oxide fleroxacin and N­demethylfleroxacin were 0.520 L/h and 0.496 L/h in patients with CF; these formation clearances were 0.378 L/h and 0.353 L/h in healthy volunteers. Renal clearance in patients with CF divided by that in healthy volunteers was 1.53 for N­oxide fleroxacin and 1.70 for N­demethyl fleroxacin. Allometric scaling by lean body mass best explained the variability. While fleroxacin pharmacokinetics was comparable, both formation and elimination clearances of its two metabolites were substantially larger in patients with CF compared to those in healthy volunteers.

Overview of the pharmacokinetics of fleroxacin.

The pharmacokinetic properties of fleroxacin in relation to other quinolones are presented. Fleroxacin, like all quinolones, is well absorbed, reaching peak concentrations within 2 hours. Interactions with Ca2+ and Al3+ are minimal and possibly of little clinical importance. The drug is eliminated via filtration in the kidney. It is therefore sensitive to changes in renal function. Accumulation of drug in the body is minimal, and change from intravenous to oral dosing results in nearly identical serum concentrations. Aside from the modest effect of metals on its absorption, fleroxacin does not interact/compete with substances oxidized in the liver, such as theophylline, and drug interactions are minimal. Its long serum half-life (8-12 hours) allows once-a-day dosing. This feature, along with its modest drug interactions, makes fleroxacin an attractive quinolone, at least with respect to its pharmacokinetics.

Pharmacokinetics of fleroxacin in renal impairment.

Fleroxacin is excreted primarily via the kidneys in its unchanged form, and therefore renal impairment has a major influence on the pharmacokinetics of this drug. This study examined the pharmacokinetics of oral and intravenous fleroxacin in patients with renal impairment. Patients with renal disease (mean glomerular filtration rate [GFR], 22 mL/min) and healthy subjects (mean GFR, 100 mL/min) received 400 mg of fleroxacin orally and 100 mg of fleroxacin intravenously in a crossover design. Serial blood samples and a complete urine collection were obtained for > or = 72 hours after dosing. Unchanged drug in plasma and urine was determined by reverse-phase high-performance liquid chromatography. Fleroxacin was well tolerated by all study participants. Renal impairment had no influence on the complete absorption of fleroxacin from the gastrointestinal tract, the maximal plasma concentration, and the steady-state volume of distribution (Vd-ss > 1 L/kg). However, systemic clearance in patients was significantly decreased (p < 0.05) to 44.4 mL/min compared with 87.1 mL/min in healthy subjects. This decrease could be ascribed to a reduction in renal clearance from 59.1 mL/min in healthy subjects to 8.8 mL/min in patients. Metabolic clearance was not reduced significantly. As a consequence of reduced clearance, the mean elimination half-life in patients increased from 13.6 hours to 21.4 hours and the area under the concentration-time curve from 87.0 mg.h/L to 170.5 mg.h/L. To avoid an unacceptable accumulation of fleroxacin in the body during multiple dosing, the following dose adjustment was recommended: patients with renal disease whose GFR is < 40 mL/min should receive the normal loading dose, i.e., 400 mg, but should receive maintenance doses that are reduced by 50%, i.e., to 200 mg.

Penetration of fleroxacin into body tissues and fluids.

Concentrations of fleroxacin in human body fluids and tissues were studied to obtain information about the efficacy of the drug at the site of infection and the ratio of fleroxacin concentrations in tissue or fluid versus those in plasma as a measure of the extent of penetration. Samples of body fluids and tissues were obtained at various intervals after oral administration, and fleroxacin concentrations were determined by high-performance liquid chromatography. After administration of the standard dose of 400 mg once daily, the maximal plasma concentrations were 5-7 mg/L at steady-state and the minimal concentrations were approximately 1 mg/L at the end of the dosing interval. In most biologic specimens, such as myometrium, fallopian tube, bile bladder wall, bone, tonsils, maxillary sinus mucosa, prostatic adenoma, sputum, inflammatory fluid, synovia, lymph, saliva, and tears, the levels of fleroxacin were similar to those in plasma. In bile, nasal secretions, seminal fluid, lung, bronchial mucosa, and ovaries, the drug concentrations were 2-3 times higher than those in plasma. Penetration of fleroxacin into fat, lens, bronchial secretions, sweat, and aqueous humor was limited, with drug levels reaching only 10-40% of the concomitant levels in plasma. The measured concentration ratios did not vary markedly with time, and the decline in drug concentrations in tissues and fluids was generally parallel to that in plasma. The breakpoint for susceptibility is 1 micrograms/mL. The susceptibility breakpoint was exceeded by the drug concentration in plasma for the entire dosing interval and was also reached or exceeded in most body tissues and fluids.

Pharmacokinetics of fleroxacin as studied by positron emission tomography and [18F]fleroxacin.

A new method of tracing the disposition of fleroxacin was tested in infected and noninfected animals in an effort to develop a technique that might be applicable in humans. [18F]fleroxacin was synthesized and shown to be identical physically, chemically, and in its antimicrobial activity to the commercially produced product. Tracer amounts of [18F]fleroxacin were coinjected with a pharmacologic dose of unlabeled drug (10 mg/kg) into normal mice, rats with focal thigh infection due to Escherichia coli, and normal and infected rabbits. The rats and mice were killed at fixed time intervals after injection, and the concentration of drug was determined by radioactive counting in a well-type counter; the rabbits were studied both by this method and by positron emission tomographic (PET) imaging. These studies validated the reliability of the new approach and suggested that it could be applied safely to humans. In all three animal species studied, delivery of [18F]fleroxacin to most tissues was rapid, with the notable exception of the brain. Accumulation of drug in infected thigh muscle was similar to that in normal muscle. The concentrations of drug reached in various tissues suggest that fleroxacin will be particularly useful in the treatment of gastrointestinal, urinary tract, hepatobiliary, and skeletal infections and that it shows promise for the treatment of lung and soft tissue infection. The minimal concentrations of drug delivered to the brain should decrease the occurrence of central nervous system toxicity with this particular fluoroquinolone.

Drug disposition in cystic fibrosis.

There are many pathological changes in patients with cystic fibrosis (CF) which can lead to alterations in drug disposition. Although, in patients with CF, the extent of drug absorption varies widely and the rate of absorption is slower, bioavailability is not altered. Plasma protein binding for the majority of drugs studied did not differ in patients with CF compared with control groups. The difference in volume of distribution of most drugs between patients with CF and healthy individuals vanished when corrected for lean body mass. Despite hepatic dysfunction, patients with CF have enhanced clearance of many, but not all, drugs. Phase I mixed-function oxidases are selectively affected: cytochrome P450 (CYP) 1A2 and CYP2C8 have enhanced activity, while other CYP isoforms such as CYP2C9 and CYP3A4 are unaffected. Increased phase II activities are also demonstrated: glucuronyl transferase, acetyl transferase (NAT1) and sulfotransferase. The increased hepatic clearance of drugs in the presence of CF may be the consequence of disease-specific changes in both enzyme activity and/or drug transport within the liver. The renal clearance (CLR) of many drugs in patients with CF is enhanced although there has been no pathological abnormality identified which could explain this finding: glomerular filtration rate and tubular secretion appear normal in patients with CF. The precise mechanisms for enhanced drug clearance in patients with CF remain to be elucidated. The optimisation of antibiotic therapy in patients with CF includes increasing the dose of beta-lactams by 20 to 30% and monitoring plasma concentrations of aminoglycosides. The appropriate dosage of quinolones has not been definitively established.

Fleroxacin clinical pharmacokinetics.

Fleroxacin is a new member of the class of fluoroquinolones. The drug has good activity (i.e. minimum inhibitory concentrations at less than 2 mg/L against 90% of strains) against a wide range of Gram-positive and Gram-negative bacteria. High performance liquid chromatography is used to determine concentrations of fleroxacin and its metabolites in biological fluids. Absorption of orally ingested drug is rapid as the peak plasma concentration of approximately 5 mg/L is reached in 1 to 2h after a single dose of 400mg. The systemic availability is close to 100%. Fleroxacin is poorly bound to plasma proteins (23%) and exhibits excellent tissue distribution. Renal clearance accounts for 60 to 70% of elimination. The drug is metabolised to form antimicrobially active N-demethyl-fleroxacin and inactive N-oxide-fleroxacin. In multiple dose studies the accumulation ratio of a once-daily dosage regimen is about 1.3, as predicted from the elimination half-life of 10 to 12h. Compared with ciprofloxacin, fleroxacin has a greater systemic availability and a longer half-life. Fleroxacin concentrations are higher in elderly patients, but further studies are needed to establish whether a dosage reduction should be recommended for this age group. In patients with renal disease dosage adjustment is recommended since a decreased renal clearance of fleroxacin leads to a significant prolongation of the elimination half-life. Fleroxacin is only poorly eliminated by peritoneal dialysis or haemodialysis. The most important drug-drug interaction is a decrease in systemic availability of fleroxacin after ingestion of aluminium- or magnesium-containing antacids. There is no evidence of a significant interaction between fleroxacin and theophylline. Only limited data are available on adverse reactions of fleroxacin. The most important adverse effects appear to be photosensitivity and a dose-dependent incidence of central nervous system reactions including sleep disorders.

Influence of sex on the pharmacokinetic interaction of fleroxacin and ciprofloxacin with caffeine.

BACKGROUND: Previous pharmacokinetic studies have shown that a number of the quinolones inhibit the metabolism of caffeine. OBJECTIVE: To evaluate the effect of sex on the interaction between two quinolones and caffeine. DESIGN: Multiple-dose, double-blind, randomised, three-period crossover study. PARTICIPANTS: Twelve male and twelve female healthy volunteers. METHODS: Subjects received by mouth either fleroxacin 400 mg once daily and caffeine 100 mg three times daily, ciprofloxacin 500 mg twice daily and caffeine 100 mg three times daily, or caffeine alone, for 3 days. Subjects received each of the other regimens after 12-day washout periods. Plasma and urine concentrations were determined by validated high-performance liquid chromatography procedures and the data were analysed by noncompartmental linear pharmacokinetic methods. RESULTS: Analysis of the interaction by sex revealed that females showed a significant difference in caffeine pharmacokinetics in the presence of ciprofloxacin (area under the concentration-time curve [AUC], peak plasma concentration [C(max)], time to C(max) [t(max)] and apparent total body clearance [CL/F]) and fleroxacin (AUC and CL/F) when compared with males. Significant differences between sexes were also observed in the pharmacokinetics of ciprofloxacin (AUC, elimination rate constant [beta] and CL/F) and fleroxacin (C(max) and beta) in the presence of caffeine. However, these significant differences disappeared when AUC and C(max) were normalised to 70 kg bodyweight and CL/F was expressed as per kg bodyweight. CONCLUSION: The effect of quinolones on the pharmacokinetics of caffeine, and the reciprocal effect, are different between the sexes, due in part to different bodyweights.

Fleroxacin. A review of its pharmacology and therapeutic efficacy in various infections.

The fluoroquinolone antibacterial agent fleroxacin has a broad spectrum of in vitro activity which encompasses most Gram-negative species (particularly Enterobacteriaceae) and a number of Gram-positive organisms, including methicillin-sensitive staphylococci. It is available as oral and intravenous formulations. In clinical trials, fleroxacin has been evaluated in the treatment of uncomplicated urinary tract infections (single or multiple once-daily oral doses of 200 or 400mg), gonorrhoea and chancroid (single oral doses of 200 or 400mg), complicated urinary tract, nonpneumococcal lower respiratory tract and skin and soft tissue infections and typhoid fever (multiple once-daily oral or intravenous regimens, usually 400 mg/day), bacterial enteritis, and traveller's diarrhoea (single or multiple once-daily oral doses of 400mg). Bacteriological cure rates were generally around 90% or higher in complicated and uncomplicated urinary tract infections, uncomplicated gonorrhoea (approximately 100%), pyelonephritis, bacterial enteritis and typhoid fever, and exceeded 80% in lower respiratory tract, and skin and soft tissue infections and chancroid. These cure rates were similar to, or better than, those achieved with standard comparator antibacterial agents such as penicillins, cephalosporins, cotrimoxazole, or other quinolones. Fleroxacin 400mg once daily also achieved bacteriological cure in approximately 80% of patients with bone and joint infections in preliminary studies. In Japanese studies using a lower dosage of 200 or 300 mg/day, fleroxacin was reported to be bacteriologically effective in a range of infections, including urinary tract and upper and lower respiratory tract infections. Fleroxacin has a relatively long elimination half-life, which allows once-daily administration, and it appears to have less propensity for interactions with other medications in comparison to many other fluoroquinolones. Its tolerability profile is typical of this class of compound, with adverse events mostly relating to the gastrointestinal tract, CNS, and skin and appendages (including phototoxicity). Recent pooled tolerability data from worldwide clinical trials indicate that adverse events are reported by approximately 27% of patients receiving 200 mg/day orally or 400 mg/day orally or intravenously, and 17% of those receiving a single oral dose of 400mg. These exceed incidences reported for established fluoroquinolones, possibly indicating recent trends towards increased rates of reported adverse effects with these agents. However, in direct comparative studies with twice-daily fluoroquinolones, fleroxacin 400mg once daily produced a similar incidence of adverse effects to ofloxacin 800 mg/day and a slightly higher incidence than ciprofloxacin 1000 mg/day, while fleroxacin 200mg once daily produced a similar incidence to norfloxacin 800 mg/day.(ABSTRACT TRUNCATED AT 400 WORDS)

Synthesis and biodistribution of 18F-labeled fleroxacin.

[18F]Fleroxacin (6,8-difluoro-1,4-dihydro-1-(2-[18F]fluoroethyl)-4- oxo-7-(4-methyl-1-piperazinyl)-3-quinolinecarboxylic acid) was synthesized from its methylsulfonyl ester precursor. 6,7,8-Trifluoro-4-hydroxyquinoline-3-carboxylic acid ethyl ester (Ro 19-7423) was alkylated with 2-bromoethanol to produce 6,7,8-trifluoro-1,4-dihydro-1-(2-hydroxyethyl)-4-oxo-3-quinolinecarboxyl ic acid ethyl ester in 76% yield which was then condensed with 1-methyl-piperazine to produce 6,8-difluoro-1,4-dihydro-1-(2-hydroxyethyl)-7-(4-methyl-1-piperazinyl)4- oxo-3- quinolinecarboxylic acid ethyl ester in 67% yield. This product was reacted with methanesulfonyl chloride to produce the mesylate precursor of fleroxacin in 66% yield. Nucleophilic substitution of the mesylate with 18F- in the presence of Kryptofix 2.2.2 followed by basic hydrolysis produced [18F]fleroxacin with a radiochemical yield of 5-8% [EOS] within 90 min. The pattern of biodistribution of [18F]fleroxacin was similar to the 14C-labeled drug.

In vitro and in vivo investigations on fluoroquinolones; effects of the P-glycoprotein efflux transporter on brain distribution of sparfloxacin.

The role of mdr1a-encoded P-glycoprotein on transport of several fluoroquinolones across the blood-brain barrier was investigated. In vitro, P-glycoprotein substrates were selected by using a confluent monolayer of MDR1-LLC-PK1 cells. The inhibition of fluoroquinolones (100 microM) on transport of rhodamine-123 (1 microM) was compared with P-glycoprotein inhibitors verapamil (20 microM) and SDZ PSC 833 (2 microM). Subsequently, transport polarity of fluoroquinolones was studied. Sparfloxacin showed the strongest inhibition (26%) and a large polarity in transport, by P-glycoprotein activity. In vivo, using mdr1a (-/-) and wild-type mice, brain distribution of pefloxacin, norfloxacin, ciprofloxacin, fleroxacin and sparfloxacin was determined at 2, 4, and 6 h following intra-arterial infusion (50 nmol/min). Brain distribution of sparfloxacin was clearly higher in mdr1a (-/-) mice compared with wild-type mice. Sparfloxacin was infused (50 nmol/min) for 1, 2, 3 and 4 h in which intracerebral microdialysis was performed. At 4 h, in vivo recovery (dynamic-no-net-flux method) was 6.5+/-2.2 and 1.5+/-0.5%; brain(ECF) concentrations were 5.1+/-0.2 and 26+/-21 microM; and total brain concentrations were 7.2+/-0.3 and 23+/-0.3 microM in wild-type and mdr1a (-/-) mice, respectively. Plasma concentrations were similar (18.4+/-0.7 and 17.9+/-0.5 microM, respectively). In conclusion, sparfloxacin enters the brain poorly mainly because of P-glycoprotein activity at the blood-brain barrier.

Penetration of fleroxacin into human lung, muscle, and fat tissue.

Fleroxacin is a new fluoroquinolone with established potent antimicrobial and pharmacokinetic properties, and the aim of this study was to determine its rate of penetration into human lung, muscle, and fat tissues. In a total of eight patients undergoing lung surgery, plasma and tissue concentrations of unmetabolized fleroxacin were determined. This was done in subgroups of two patients each, receiving either 6, 8, 12 or 24 hours prior to surgery one single oral dose of 400 mg fleroxacin. It was found that fleroxacin penetrates well into muscle and lung tissues, but not into fat tissue. The levels in muscle and lung were 1.1 to 4.7 times higher than the according plasma concentrations.

Sustained release of fleroxacin in vitro from lactic acid polymer.

The time-delayed release of fleroxacin, a newer fluoroquinolone, from a mixture of racemic D-L-Lactic acid is reviewed. Ten in vitro experiments for each fleroxacin concentration of 1% and 10%, were performed. Pre-formed D-L-Lactic acid, plus fleroxacin clots were preserved in sterile 1 cm diameter tubes with one ml of nutrient broth at 37 degrees C until they were fully disintegrated. Every 24 hours the tubes were sampled and replaced by standard broth volumes. Fleroxacin levels were measured by a microbiological method. The release of fleroxacin impregnated in D-L-Lactic acid clots in these two concentrations (1% and 10%) is very promising; the levels obtained over a two month period were much higher than the minimum bacterial concentration of the expected pathogens implicated in bone infections.

Effect of sucralfate on pharmacokinetics of fleroxacin in healthy volunteers.

The effect of sucralfate on the pharmacokinetics of fleroxacin was assessed in 20 healthy male volunteers. The study was of a two-way crossover design in which subjects were randomized to one of the following two regimens at the time of entry: (i) a single 400-mg dose of fleroxacin alone or (ii) a 400-mg dose of fleroxacin given once and 1 g of sucralfate given every 6 h starting 24 h before fleroxacin treatment and continuing for 48 h after fleroxacin treatment. Blood samples were collected immediately before fleroxacin administration and at 0.5, 1, 1.5, 2, 2.5, 3, 4, 6, 8, 10, 12, 16, 24, 36, and 48 h postdosing. Fleroxacin concentrations in plasma and urine were determined by high-performance liquid chromatography. While concurrent of fleroxacin and sucralfate resulted in a decrease in the area under the plasma concentration-time curve, a decrease in the maximum concentration, and an increase in the time to the maximum concentration (P < 0.05), these changes were modest compared with the interaction of other quinolones with sucralfate. The relative bioavailability of fleroxacin given with sucralfate, calculated from the area under the concentration-time curve, was 76% compared with that of fleroxacin alone. This is significantly better than the bioavailabilities of other quinolones (1.8 to 12.3%) when they are administered with sucralfate.

Fleroxacin pharmacokinetics in aqueous and vitreous humors determined by using complete concentration-time data from individual rabbits.

Although composite data from separate subjects can be used to generate single-subject estimates, intersubject variation precludes rigorous ocular pharmacokinetic analysis. Therefore, a rabbit model in which sequential aqueous and vitreous humor samples were obtained following the administration of the quinolone fleroxacin was developed. Mean data from individual animals were used for pharmacokinetic analysis. Following direct intravitreal or systemic drug administration, sequential paracenteses did not alter pharmacokinetic constants or ocular penetration and were not associated with an increase in ocular protein; contamination of vitreous humor with blood was minimal (less than 0.1%). Following direct injection or intravenous administration, vitreous humor concentration-time data were best described by one- and two-compartment models, respectively. The maximum concentration and the penetration into the aqueous and vitreous humors were 1.54 and 0.5 micrograms/ml and 27 and 10%, respectively. Elimination rates from aqueous and vitreous humors and serum were similar following parenteral drug administration. Drug elimination following direct injection was rapid, and the elimination rate from the vitreous humor was not prolonged by the coadministration of probenecid. Our animal model provides a new approach to the rigorous examination of the ocular pharmacokinetics of quinolone antimicrobial agents in the eye.