Concepts basic to pharmacokinetics

Reduced oxycodone brain delivery in rats due to lipopolysaccharide-induced inflammation: microdialysis insights into brain disposition and sex-specific pharmacokinetics

BACKGROUND

Oxycodone, a widely used opioid analgesic, has an unbound brain-to-plasma concentration ratio (Kp,uu) greater than unity, indicating active uptake across brain barriers associated with the putative proton-coupled organic cation (H+/OC) antiporter system. With this study, we aimed to elucidate oxycodone's CNS disposition during lipopolysaccharide (LPS)-induced systemic inflammation in Sprague-Dawley rats.

METHODS

Using brain microdialysis, we dynamically and simultaneously monitored unbound oxycodone concentrations in blood, striatum, lateral ventricle, and cisterna magna following intravenous administration of oxycodone post-LPS challenge.

RESULTS

Our results indicated a reduced, sex-independent brain net uptake of oxycodone across the blood-brain barrier (BBB) measured in the striatum. Notably, the LPS challenge has significantly altered the systemic pharmacokinetics (PK) of oxycodone, in a sex-specific manner, leading to lower clearance and higher blood concentrations in females compared to LPS-treated males and healthy rats of both sexes. Proteomic analysis using Olink Target 96 Mouse Exploratory assay confirmed the induction of systemic inflammation and neuroinflammation. The inflammation led to an increased paracellular transport, measured using 4 kDa dextran, while preserving net active uptake of oxycodone across both BBB and the blood-cerebrospinal fluid barrier (BCSFB), with Kp,uu values of 2.7 and 2.5, respectively. The extent of uptake was 1.6-fold lower (p < 0.0001) at the BBB and unchanged at the BCSFB after the LPS challenge compared to that in healthy rats. However, the mean exposure of unbound oxycodone in the brain following LPS was similar to that in healthy rats, primarily due to the LPS-induced changes in systemic exposure.

CONCLUSIONS

These findings highlight the dissimilar responses at blood-brain interfaces during LPS-induced inflammation. Advancing the knowledge of neuropharmacokinetic mechanisms, specifically those involving the H+/OC antiporter system, will enable the development of more effective therapeutic strategies during inflammation conditions.

Active Uptake of Oxycodone at Both the Blood-Cerebrospinal Fluid Barrier and The Blood-Brain Barrier without Sex Differences: A Rat Microdialysis Study

BACKGROUND

Oxycodone active uptake across the blood-brain barrier (BBB) is associated with the putative proton-coupled organic cation (H+/OC) antiporter system. Yet, the activity of this system at the blood-cerebrospinal fluid barrier (BCSFB) is not fully understood. Additionally, sex differences in systemic pharmacokinetics and pharmacodynamics of oxycodone has been reported, but whether the previous observations involve sex differences in the function of the H+/OC antiporter system remain unknown. The objective of this study was, therefore, to investigate the extent of oxycodone transport across the BBB and the BCSFB in female and male Sprague-Dawley rats using microdialysis.

METHODS

Microdialysis probes were implanted in the blood and two of the following brain locations: striatum and lateral ventricle or cisterna magna. Oxycodone was administered as an intravenous infusion, and dialysate, blood and brain were collected. Unbound partition coefficients (Kp,uu) were calculated to understand the extent of oxycodone transport across the blood-brain barriers. Non-compartmental analysis was conducted using Phoenix 64 WinNonlin. GraphPad Prism version 9.0.0 was used to perform t-tests, one-way and two-way analysis of variance followed by Tukey's or Šídák's multiple comparison tests. Differences were considered significant at p < 0.05.

RESULTS

The extent of transport at the BBB measured in striatum was 4.44 ± 1.02 (Kp,uu,STR), in the lateral ventricle 3.41 ± 0.74 (Kp,uu,LV) and in cisterna magna 2.68 ± 1.01 (Kp,uu,CM). These Kp,uu values indicate that the extent of oxycodone transport is significantly lower at the BCSFB compared with that at the BBB, but still confirm the presence of active uptake at both blood-brain interfaces. No significant sex differences were observed in neither the extent of oxycodone delivery to the brain, nor in the systemic pharmacokinetics of oxycodone.

CONCLUSIONS

The findings clearly show that active uptake is present at both the BCSFB and the BBB. Despite some underestimation of the extent of oxycodone delivery to the brain, CSF may be an acceptable surrogate of brain ISF for oxycodone, and potentially also other drugs actively transported into the brain via the H+/OC antiporter system.

Polyphenolic promiscuity, inflammation-coupled selectivity: Whether PAINs filters mask an antiviral asset

The Covid-19 pandemic has elicited much laboratory and clinical research attention on vaccines, mAbs, and certain small-molecule antivirals against SARS-CoV-2 infection. By contrast, there has been comparatively little attention on plant-derived compounds, especially those that are understood to be safely ingested at common doses and are frequently consumed in the diet in herbs, spices, fruits and vegetables. Examining plant secondary metabolites, we review recent elucidations into the pharmacological activity of flavonoids and other polyphenolic compounds and also survey their putative frequent-hitter behavior. Polyphenols, like many drugs, are glucuronidated post-ingestion. In an inflammatory milieu such as infection, a reversion back to the active aglycone by the release of β-glucuronidase from neutrophils and macrophages allows cellular entry of the aglycone. In the context of viral infection, virions and intracellular virus particles may be exposed to promiscuous binding by the polyphenol aglycones resulting in viral inhibition. As the mechanism's scope would apply to the diverse range of virus species that elicit inflammation in infected hosts, we highlight pre-clinical studies of polyphenol aglycones, such as luteolin, isoginkgetin, quercetin, quercetagetin, baicalein, curcumin, fisetin and hesperetin that reduce virion replication spanning multiple distinct virus genera. It is hoped that greater awareness of the potential spatial selectivity of polyphenolic activation to sites of pathogenic infection will spur renewed research and clinical attention for natural products antiviral assaying and trialing over a wide array of infectious viral diseases.

Transcriptome analysis of extended-spectrum β-lactamase-producing Escherichia coli and methicillin-resistant Staphylococcus aureus exposed to cefotaxime

Previous studies on bacterial response to antibiotics mainly focused on susceptible strains. Here we characterized the transcriptional responses of distinct cephalosporin-resistant bacteria of public health relevance to cefotaxime (CTX), a cephalosporin widely used in clinical practice. Adaptation to therapeutic concentrations of CTX (30 µg/ml) was investigated by RNA sequencing in mid-exponential phase cultures of a methicillin-resistant Staphylococcus aureus (MRSA) and two genetically diverse E. coli producing CTX-M-15 or CMY-2 β-lactamase following genome sequencing and annotation for each strain. MRSA showed the most notable adaptive changes in the transcriptome after exposure to CTX, mainly associated with cell envelope functions. This reprogramming coincided with a transient reduction in cell growth, which also occurred in the CMY-2-producing E. coli but not in the CTX-M-15-producing strain. Re-establishment of growth in the CMY-2 producer proceeded without any notable adaptive transcriptional response, while limited reprogramming of gene transcription was observed in the CTX-M-15 producer. Our data show that the transcriptional response of CTX-resistant bacteria to CTX depends on the bacterial species, level of resistance and resistance determinant involved. Gene products induced in the presence of CTX may play an essential role for bacterial survival during therapy and merit further investigation as possible targets for potentiating CTX.

Identifiability Results for Several Classes of Linear Compartment Models

Identifiability concerns finding which unknown parameters of a model can be estimated, uniquely or otherwise, from given input-output data. If some subset of the parameters of a model cannot be determined given input-output data, then we say the model is unidentifiable. In this work, we study linear compartment models, which are a class of biological models commonly used in pharmacokinetics, physiology, and ecology. In past work, we used commutative algebra and graph theory to identify a class of linear compartment models that we call identifiable cycle models, which are unidentifiable but have the simplest possible identifiable functions (so-called monomial cycles). Here we show how to modify identifiable cycle models by adding inputs, adding outputs, or removing leaks, in such a way that we obtain an identifiable model. We also prove a constructive result on how to combine identifiable models, each corresponding to strongly connected graphs, into a larger identifiable model. We apply these theoretical results to several real-world biological models from physiology, cell biology, and ecology.

Relevance of Liver Failure for Anti-Infective Agents: From Pharmacokinetic Alterations to Dosage Adjustments

The liver is a complex organ with great ability to influence drug pharmacokinetics. Due to its wide array of function, its impairment has the potential to affect bioavailability, enterohepatic circulation, drug distribution, metabolism, clearance, and biliary elimination. These alterations differ widely depending on the cause of the liver failure, if it is acute or chronic in nature, the extent of impairment, and comorbid conditions. In addition, effects on liver functions do not occur in a proportional or predictable manner for escalating degrees of liver impairment. The ability of hepatic alterations to influence PK is also dependent on drug characteristics, such as administration route, chemical properties, protein binding, and extraction ratio, among others. This complexity makes it difficult to predict what these effects have on drugs. Unlike certain classes of agents, efficacy of anti-infectives is most often dependent on fulfilling pharmacokinetic/pharmacodynamic targets, such as C_max/MIC, AUC/MIC, T_>MIC, IC₅₀/EC₅₀, or T>EC₉₅. Loss of efficacy, or conversely, increased risk of toxicity may occur in certain circumstances of liver injury. Although important to consider these potential alterations and their effects on specific anti-infectives, many lack data to constitute specific dosing adjustments, making it important to monitor patients for effectiveness and toxicities of therapy.

Irreversible enzyme inhibition kinetics and drug-drug interactions

This chapter describes the types of irreversible inhibition of drug-metabolizing enzymes and the methods commonly employed to quantify the irreversible inhibition and subsequently predict the extent and time course of clinically important drug-drug interactions.

Viral dose, radioiodide uptake, and delayed efflux in adenovirus-mediated NIS radiovirotherapy correlates with treatment efficacy

We have constructed a prostate tumor-specific conditionally replicating adenovirus (CRAd), named Ad5PB_RSV-NIS, which expresses the human sodium iodine symporter (NIS) gene. LNCaP tumors were established in nude mice and infected with this CRAd to study tumor viral spread, NIS expression, and efficacy. Using quantitative PCR, we found a linear correlation between the viral dose and viral genome copy numbers recovered after tumor infection. Confocal microscopy showed a linear correlation between adenovirus density and NIS expression. Radioiodide uptake vs virus dose-response curves revealed that the dose response curve was not linear and displayed a lower threshold of detection at 10(7) vp (virus particles) and an upper plateau of uptake at 10(11) vp. The outcome of radiovirotherapy was highly dependent upon viral dose. At 10(10) vp, no significant differences were observed between virotherapy alone or radiovirotherapy. However, when radioiodide therapy was combined with virotherapy at a dose of 10(11) vp, significant improvement in survival was observed, indicating a relationship between viral dose-response uptake and the efficacy of radiovirotherapy. The reasons behind the differences in radioiodide therapy efficacy can be ascribed to more efficient viral tumor spread and a decrease in the rate of radioisotope efflux. Our results have important implications regarding the desirable and undesirable characteristics of vectors for clinical translation of virus-mediated NIS transfer therapy.

QT interval prolongation and torsade de pointes induced by propofol and hypoalbuminemia

We report the case of a 70-year-old man presenting with the development of torsade de pointes (TDP) during infusion of propofol in the setting of severe hypoalbuminemia. TDP developed 15 hours after the beginning of a standard infusion of propofol, following the development of a prominent U wave and prolongation of the QTc interval. While the serum concentrations of electrolytes were within normal ranges, serum albumin as low as 1.4 mg/dL was observed. TDP disappeared during the infusion of isoproterenol, and QTc normalized after the discontinuation of propofol. We hypothesize that hypoalbuminemia increased the free fraction of propofol, causing marked QTc prolongation and TDP.

Significance of protein binding in pharmacokinetics and pharmacodynamics

The significance of plasma protein binding on drug efficacy and, subsequently, the clinical relevance of changes in protein binding has been controversially discussed for decades. The uncertainty concerning the impact of plasma protein binding on a drug's pharmacological activity is, in part, related to the approach used when investigating and interpreting protein binding effects in vitro and in vivo. Frequently, a generalized one-size-fits-all approach, such as "protein binding does matter/does not matter," may not be applicable. An appropriate analysis requires careful consideration of both pharmacokinetic and pharmacodynamic processes, as they both contribute to the safety and efficacy of drugs. Therefore, the aim of this article is to provide a concise review of the theoretical concepts of protein binding, and to discuss relevant examples where applicable.

Drug-drug interaction pattern recognition

BACKGROUND AND OBJECTIVE

Drug-drug interaction (DDI) is an important aspect of drug development, especially for safety. When a drug is used concomitantly with other drug(s), one of the major concerns is the change of exposures, including the rate and extent of drug absorption, distribution, metabolism and elimination. To address the concerns, a common practice is to measure and report the differences between the exposure in the presence and in the absence of concomitant medication (COMED). The area under the plasma concentration versus time curve (AUC), maximum plasma concentration (C(max)) and time to reach the C(max) (t(max)) changes are usually measured in DDI studies. A usual observation is the different extents of changes among AUC, C(max) and t(max), which may raise concerns in certain therapeutic areas or some special agents. The objective of this study was to investigate the variation among changes of AUC, C(max) and t(max) in DDI studies, and its pharmacokinetic manifestation.

DATA SOURCES

Based on a list of DDI results from the literature, with the assumptions that the primary parameters of a drug of interest were altered during a DDI, two sets of simulated data were generated according to a single oral dose, one-compartment model. The first set including 24 cases with different half-lives and absorption constants (k(a)) considered the exposure changes upon independent variation of bioavailability (F), clearance (CL), volume of distribution (V(d)) and k(a) up to 50-fold increases or decreases. The second set considered the exposure changes with simultaneous variation of F, CL, V(d), and k(a) within 5-fold range (increase or decrease) for a case selected from the first set.

STUDY SELECTION, DATA EXTRACTION AND SYNTHESIS

Parameter fold changes (defined in a fashion showing fold increase or fold decreases, including CL fold change, F fold change, V(d) fold change and k(a) fold change) and exposure changes (AUC fold change, C(max) fold change, t(max) fold change and fold change difference [AUC fold change - C(max) fold change]) were used to generate plots demonstrating various relationships between parameter fold changes and exposure changes. Based on the observations that AUC was influenced by CL and F, C(max) was affected by all four parameters, t(max) was mainly determined by CL and k(a), F did little for t(max) and k(a) was unrelated to AUC, a chart was created for DDI pattern recognition.

CONCLUSION

An approach, named DDI pattern recognition, is proposed for didactical purposes. It provides a quick initial estimate for interpreting the DDI results based on the exposure changes. This approach entails the following stages: (i) performing a drug interaction study; (ii) calculating the exposure changes in the presence of COMED compared to those in the absence of COMED, and the fold change difference; (iii) selecting the parameter fold changes that may play important roles in a specific DDI, by estimating their possible ranges; and (iv) interpreting the DDI by integrating all the information available, such as the possible mechanism involved. A quicker and better understanding about the processes, which dominate a DDI, has been achieved using this approach by focusing on integration of all information available and mechanistic interpretation.

In vivo blood-brain barrier transport of oxycodone in the rat: indications for active influx and implications for pharmacokinetics/pharmacodynamics

The blood-brain barrier (BBB) transport of oxycodone was studied in rats. Microdialysis probes were inserted into the striatum and vena jugularis. Ten animals were given a bolus dose followed by a 120-min constant rate infusion to study the steady-state concepts of oxycodone BBB equilibration. Another 10 animals were given a 60-min constant rate infusion to study the rate of equilibration across the BBB. Oxycodone-D3 was used as a calibrator for the microdialysis experiments. The samples were analyzed with a liquid chromatography-tandem mass spectrometry method and a population pharmacokinetic model was used to simultaneously fit all the data using NONMEM. A two-compartment model which allowed for a delay between the venous and arterial compartments best described the pharmacokinetics for oxycodone in blood and plasma, whereas a one-compartment model was sufficient to describe the pharmacokinetics in the brain. The BBB transport of oxycodone was parameterized as CL(in) and K(p,uu). CL(in) describes the clearance of oxycodone across the BBB into the brain, whereas K(p,uu) describes the extent of drug equilibration across the BBB. CL(in) across the BBB was estimated to 1910 microl/min x g brain. K(p,uu) was estimated to 3.0, meaning that the unbound concentration of oxycodone in brain was 3 times higher than in blood, which is an indication of active influx of oxycodone at the BBB. This is the first evidence of an opioid having an unbound steady-state concentration in brain that is higher than unity, which can explain potency discrepancies between oxycodone and other opioids.

Pharmacokinetics, Urinary and Mammary Excretion of Ceftriaxone in Lactating Goats

The pharmacokinetic properties of ceftriaxone were investigated in 10 goats following a single intravenous (i.v.) and intramuscular (i.m.) administration of 20 mg kg(-1) body weight. After i.v. injection, ceftriaxone serum concentration-time curves were characteristic of a two-compartment open model. The distribution and elimination half-lives (t(1/2alpha), t(1/2beta)) were 0.12 and 1.44 h respectively. Following i.m. injection, peak serum concentration (C(max)) of 23.6 microg ml(-1) was attained at 0.70 h. The absorption and elimination half-lives (t(1/2ab), t(1/2el)) were 0.138 and 1.65 h respectively. The systemic bioavailability of the i.m. administration (F %) was 85%. Following i.v. and i.m. administration, the drug was excreted in high concentrations in urine for 24 h post-administration. The drug was detected at low concentrations in milk of lactating goats. A recommended dosage of 20 mg kg(-1) injected i.m. every 12 h could be expected to provide a therapeutic serum concentration exceeding the minimal inhibitory concentrations for different susceptible pathogens.

Evaluation of the protein binding ratio of drugs by a micro-scale ultracentrifugation method

Ultracentrifugation methods have been widely used for the determination of the free fraction of compounds in plasma, especially for lipophilic compounds. To estimate the effect of contaminated proteins in the "protein-free phase" fraction, 200 microL of human plasma was separated into three layers by ultracentrifugation at 436,000g for 140 min with a table-top ultracentrifuge. Twenty microliters of the middle layer was taken as the protein-free fraction. Major contaminated proteins were analyzed by liquid chromatography/electrospray ionization/tandem mass spectrometry (LC/ESI/MS/MS) and identified as albumin, alpha-1-antitrypsin, alpha-2-HS-glycoprotein, apolipoprotein E, and apolipoprotein A-1. alpha-1-acid glycoprotein was not detected. Contamination of albumin was 0.13% of that in plasma. Simulation analysis demonstrated that at an actual free fraction of 1% (protein binding ratio of 99%), the extent of overestimation of free fraction was just 13% and the apparent free fraction was 1.13%. Human plasma protein binding ratios of 10 drugs estimated by this method correlated well with reported values determined by other methods, such as ultrafiltration and equilibrium dialysis, with a correlation factor of 0.98 and a slope of 0.99. Collectively, our results indicate the reliability of this micro-scale ultracentrifugation technique for the evaluation of the protein binding of drugs despite a little contamination of albumin.

In vivo cerebral pharmacokinetics and pharmacodynamics of diazepam and midazolam after short intravenous infusion administration in sheep

The cerebral pharmacokinetics and pharmacodynamics of midazolam and diazepam were examined in chronically instrumented sheep via measurements of their arterio-venous concentration difference across the brain during and after 2-min i.v. infusions. Diazepam (30 mg) or midazolam (10 mg) were administered on 5 separate occasions to 4 sheep. For both drugs, rapid cerebral uptake occurred during the infusion, which quickly turned to elution in the postinfusion period. However, this process was more rapid for midazolam than diazepam. The cerebral pharmacokinetics of both was better described by a kinetic model with slight membrane limitation rather than flow limitation. For diazepam, the estimated brain:plasma partition coefficient was 2.67, and the first and second compartments filled with half-lives of 2.2 and 0.5 min, respectively. For midazolam, these values were 0.27, 0.26 and 1.34 min, respectively. In a subset of sheep, pulmonary arterial-arterial gradients were too small to measure suggesting limited metabolism and small distribution volumes for both drugs in the lungs. Simultaneous dynamic measurements of cerebral blood flow and algesimetry lagged behind both the arterial and sagittal sinus blood concentrations. The changes in cerebral blood flow were best described by a previously published a dynamic model that incorporated long half-lives for drug dissociation from the benzodiazepine receptor (13.3 and 5.5 min for midazolam and diazepam, respectively). Effect compartment modeling of the cerebral blood flow data showed apparent effect compartment half-lives (t1/2,keo) that were longer than the half-lives of cerebral equilibration.

Distribution and elimination of the solute and water components of urological irrigating fluids

OBJECTIVE

Irrigating fluids are used to dilate mucosal spaces and to remove blood and cut tissue from the operating field during endoscopic procedures. We have studied their disposition, since irrigating solutions are sometimes absorbed and may therefore be regarded as intravenous drugs.

MATERIAL AND METHODS

The distribution and the rate of elimination of four irrigating fluids containing glycine, mannitol and sorbitol were studied after infusing 0.75 ml/kg/min of them over a period of 20 min in 10 male volunteers. Kinetic calculations were based on 12 blood samples collected over 120 min using traditional pharmacokinetics for the solutes and volume kinetics for the water component.

RESULTS

The solutes had distribution half-lives of between 3 and 7 min; the elimination half-lives were 39 min (glycine), 97 min (mannitol) and 33 min (sorbitol). The volume of distribution during steady state was between 20 and 36 litres, while the volume of the body fluid space expanded by the water component of the irrigating fluids varied between 6 and 9 litres. Although the solutes became distributed over a much larger space than the infused fluid volume, the intersubject variation was smaller for the solute concentrations than for the dilution of the plasma fraction of the blood.

CONCLUSIONS

The kinetics of the solute and water components of urological irrigating fluids can be analysed and compared using computer-based mathematical models.

Binding of propofol to blood components: implications for pharmacokinetics and for pharmacodynamics

AIMS

Propofol is a widely used i.v. anaesthetic agent. However, its binding properties to blood components have not been fully studied.

METHODS

We studied the binding of propofol to erythrocytes, to human serum and to isolated serum proteins. Because propofol bound to ultrafiltration and equilibrium dialysis membranes, we used a co-binding technique with dextran coated charcoal and with erythrocytes.

RESULTS

Propofol free fraction in blood was 1.2-1.7% at total concentrations ranging from 2.80 to 179 microM (0.5 to 32 microg ml(-1)). Fifty percent was bound to erythrocytes and 48% to serum proteins, almost exclusively to human serum albumin. In the clinical range of concentrations (0.5-16 microg ml(-1)) 40% of the molecules bound to erythrocytes are on the red blood cells membranes. No binding to lipoproteins occurred and binding to alpha1-acid glycoprotein was less than 1.5%

CONCLUSIONS

We conclude that hypoalbuminaemia may increase propofol free fraction particularly during prolonged administration. Since propofol is non-restrictively cleared, no change in clearance is expected to occur, and the increase in free fraction will not be compensated by a parallel increase in clearance. It is also noted that many in vitro studies used concentrations 50 to 500 times the concentration expected to be encountered in the immediate cellular environment.

Arterio-venous ethanol levels in blood and plasma after intravenous injection in rabbits

Arterio-venous ethanol concentrations in both whole blood and plasma were determined as a function of time in the rabbit. Following i.v. injection of 1.0 g/kg, both arterial and venous ethanol concentrations showed an abrupt decline occurring immediately after the end of the administration, followed by a pseudolinear phase that persisted for the length of the experiment. This work substantiates the arterio-venous ethanol concentration differences reported in the literature. It illustrates that equal arterial and venous ethanol concentrations may not be achieved readily after rapid i.v. injection. Moreover, it demonstrates a faster decay of ethanol concentrations in arterial than in venous plasma.

Oxaprozin and piroxicam, nonsteroidal antiinflammatory drugs with long half-lives: effect of protein-binding differences on steady-state pharmacokinetics

The nonsteroidal antiinflammatory drugs (NSAIDs) oxaprozin and piroxicam have long elimination half-lives (t 1/2 approximately 55 hours), permitting once-daily dose regimens. The protein-binding characteristics of these drugs, however, vary widely. This study examines the effect of these binding differences on the drugs' disposition kinetics at steady state. A total of 52 participants (26 young healthy volunteers, and 26 elderly osteoarthritic patients, 15 men and 37 women (2 of them poor metabolizers of debrisoquine [CYP2D6]) completed the two-period, two-treatment, randomized, single-dose and 21-day, once-daily multiple-dose, cross-over study. Doses of oxaprozin and piroxicam were 1,200 mg once daily and 20 mg once daily, respectively. Mean single-dose kinetic parameters of oxaprozin versus piroxicam did not differ more than +/-14% (t1/2, 53.0 versus 57.4 hours; apparent oral clearance adjusted for 70-kg body weight [Clpo], 0.139 versus 0.121 L/hr; apparent volume of distribution adjusted for 70-kg body weight [Vd/F]; 10.2 L versus 9.13 L). Protein binding was plasma-concentration dependent with oxaprozin (range, 10-400 mg/L) but not with piroxicam (range, 1-30 mg/ L). Steady-state conditions were established within 3 days with oxaprozin but took almost 12 days with piroxicam. Compared with the single-dose values, steady-state Clpo (Clpo,ss) and Vd/F of total drug increased with oxaprozin by almost 127% but remained within +/-10% with piroxicam. Post-steady-state apparent t 1/2 of the total and unbound drugs of approximately 62 hours were similarly prolonged with piroxicam but differed substantially with oxaprozin (50.6 hours [total drug] versus 23.8 hours [unbound drug]). Single dose Clpo (Clpo,sd) values of both NSAIDs were significantly correlated in the study populations. With both NSAIDs, Clpo in the two poor metabolizers of debrisoquine was within +/-20% of mean values for the population. Clinically important age- and gender-dependent decreases were not observed in the weight-adjusted, Clpo,sd or Vd/F values of the total drug for either NSAID. Clearances of the two NSAIDs were significantly correlated, suggesting that a common P450 isozyme (most likely CYP2C9, in that piroxicam is a known substrate of this isozyme) may be at least partly involved in the oxidative metabolism of these NSAIDs.

Inverse nonlinear pharmacokinetics of total and protein unbound drug (oxaprozin): clinical and pharmacokinetic implications

The nonsteroidal antiinflammatory drug oxaprozin is extensively bound to plasma proteins in a concentration-dependent manner. This study demonstrates for the first time the inverse nonlinear pharmacokinetics of total and unbound oxaprozin and presents clinical implications of this phenomenon. A total of 71 healthy volunteers participated in single- and multiple-dose studies. In study I, 0.6-, 1.2-, and 1.8-gm doses of oxaprozin were given on an empty stomach in a randomized, crossover trial (n = 35). In studies II and III, 1.2- and 1.8-gm doses, respectively, were given once a day for 8 days (n = 12 and 24, respectively). Serial blood samples for total and unbound drug assays were taken over a 240-hour period in study I and for a 24-hour period on days 1, 5, and 8 in studies II and III. After administration of 1.2 gm once daily, steady-state conditions were established by day 5. Actual average steady-state plasma concentrations (Cavg) were lower than those predicted from the single-dose study based on linear kinetics for the total drug, but higher for the unbound drug. Nonlinear changes in Vd/F were also noted with multiple-dose administration. Vd/F increased by 47% for total drug but decreased by 61% for unbound drug relative to single-dose values. Half-lives after single-dose administration for total and unbound drug determined from 24 to 240 hours and from 24 to 72 hours, respectively, were dose independent for total drug, but dose dependent for unbound drug. Half-lives after multiple-dose administration measured from 24 to 48 hours in study II decreased further. In conclusion, oxaprozin clearance for the total drug was increased while that of the unbound drug was decreased after repetitive dosing. This inverse pharmacokinetic behavior has been attributed to the two noncompensatory kinetic effects: concentration-dependent protein binding and saturable metabolism of oxaprozin.

Antiepileptic drug therapy: clinical laboratory significance

When evaluating a patient who is taking an antiepileptic medication, it is important for the emergency physician to correlate the clinical presentation with the antiepileptic drug level. Therapeutic ranges have been suggested for most antiepileptic medications, but these must be interpreted in light of clinical efficacy and patient tolerance. When considering the efficacy of anti-epileptic medications, it is necessary to consider the patient's unique metabolism, side-effect tolerance, and overall response to therapy. Suggested therapeutic ranges should be the first reference for the emergency physician. The purpose of this report is to discuss the laboratory values of commonly prescribed antiepileptic medications. Therapeutic ranges, side-effects, and common medication interactions are discussed concerning phenytoin, phenobarbital, carbamezapine, and valproic acid.

Pharmacokinetics of pipecuronium in infants, children and adults

In order to explain the reported shorter clinical duration of action of cumulative ED95 of pipecuronium in infants as compared to children or adults, the pharmacokinetic profiles of pipecuronium were compared in infants (n = 6; mean age 6.8 months; mean weight 7.3 kg) in children (n = 6; mean age 4.6 years; mean weight 19.2 kg) and in adults (n = 7; mean age 42 years; mean weight 58.2 kg). Equipotent doses (2 x ED95) of pipecuronium were injected i.v. as single bolus and arterial blood was sampled for 4-5 h. Pipecuronium was quantified by complex formation with [125I]-labelled rose bengal. Pharmacokinetic parameters were calculated using a two-compartment open model. The median for the distribution half-life of pipecuronium was 2.54 min (interquartile range: 1.0-2.5 min) in infants and 2.04 min (0.26-2.04 min) in children; both were significantly shorter than in adults (5.75 [3.7-9.7] min). The plasma clearance of pipecuronium was significantly decreased in infants (1.50 [0.6-1.5] ml.min-1.kg-1; P < 0.05) as compared to children and adults (2.27 [0.88-2.27] and 2.45 [1.7-3.2] ml.min-1.kg-1, respectively). The total volume of distribution was similar in all three groups. We conclude that the pharmacokinetic features of pipecuronium are age-dependent: differences as compared to adults consisted of a faster distribution in both infants and children and a slower elimination in infants. The pharmacokinetic profile of pipecuronium does not explain the faster recovery from neuromuscular blockade in infants as compared to children. Because of the low total plasma clearance in infants, pipecuronium dosage should be carefully monitored to avoid accumulation and prolonged paralysis.

Dose-dependent inhibition in plasma protein binding of valproic acid during continued treatment in guinea-pigs

Plasma protein binding of valproic acid over a wide range of steady-state plasma concentration (11.3 +/- 2.6-1303.0 +/- 122.9 micrograms mL-1: s.e.m., n = 5) in guinea-pigs has been studied. Valproic acid was given by intravenous constant infusion. At steady-state the plasma protein binding of valproic acid was analysed. Nonlinear binding was observed. Unbound fraction (fu) of valproic acid increased from 25 to 95% with the increase of steady-state plasma concentration (Css). The plasma protein-bound drug concentration (Cb) of valproic acid increased initially with Css but decreased after the Css exceeded 345.0 micrograms mL-1, where the Cb was 152.5 +/- 26.8 micrograms mL-1. At a Css of 1303.3 +/- 122.9 micrograms mL-1 the Cb was significantly (P less than 0.05) decreased to 72.8 +/- 20.2 micrograms mL-1. Binding characteristics of valproic acid in-vitro were studied using drug-free guinea-pig plasma with added valproic acid (10-1000 micrograms mL-1). The binding behaviour was also nonlinear in-vitro. The fu increased from 14 to 79% with the increase of valproate concentrations. No decrease in Cb was observed throughout the range. The study demonstrated that binding characteristics of valproic acid in-vivo and in-vitro are not parallel. The results suggest that valproic acid may produce or induce plasma protein binding competitors; metabolites of valproic acid may be implicated.

Stereoselective disposition of flurbiprofen in normal volunteers

1. The concentrations of the R- and S-enantiomers of flurbiprofen and its metabolites were measured in plasma and urine following the oral administration of 50 mg racemic flurbiprofen to six normal volunteers. 2. The AUC and half-life of the R-enantiomer were significantly lower than the corresponding S-enantiomer values reflecting the greater clearance of R-flurbiprofen (20.42 +/- 4.71 vs 16.12 +/- 3.60 ml min-1). 3. Ex vivo protein binding studies indicated that the percent unbound of R-flurbiprofen was (not significantly) greater than that of the S-enantiomer (0.055 +/- 0.008 vs 0.049 +/- 0.009) and the corresponding unbound clearances did not show enantioselectivity. 4. Both enantiomers were cleared primarily by metabolism to an acylglucuronide and 4'-hydroxyflurbiprofen. There was significant enantioselectivity (R greater than S) in the formation clearances of these metabolites which remained when unbound metabolite formation clearances were considered. 5. In conclusion, the disposition of the enantiomers of flurbiprofen exhibits enantioselectivity at the level of protein binding and metabolite formation.

Myocardial uptake of lignocaine: pharmacokinetics and pharmacodynamics in the isolated perfused heart of the rabbit

1. The uptake kinetics and pharmacodynamics of lignocaine were studied in isolated perfused heart of the rabbit. 2. Six hearts were perfused with increasing concentrations of lignocaine in a modified Krebs-Henseleit buffer. The effluent concentration together with the increase in QRS duration were measured during lignocaine infusion and during 20 min after cessation of lignocaine infusion. 3. Lignocaine disposition and elimination were best described by a two-compartment open model. Terminal half-life was 11.0 +/- 2.9 min. The unidirectional transfer was slower from central to peripheral compartment than from peripheral to central compartment (T1/2.12 = 42.6 +/- 10.5 min whereas T1/2.21 = 10.7 +/- 2.8 min). The myocardium/perfusate concentration-ratio was 4.7 +/- 0.4. 4. The pharmacodynamic effect was best described in the central compartment by using the Hill equation. Calculated maximum QRS duration (Emax) was 77 +/- 8 ms. Emax was also directly measured in four additional rabbits by infusing ten times the dose of lignocaine used in the main experiment: the value of Emax measured in these conditions was 92.5 +/- 9.6 ms, i.e. a QRS widening of 150%. The steady-state perfusate concentration producing half the effect (C50) was 15.7 +/- 7.6 micrograms ml-1. 6. In conclusion, the specific lignocaine binding leading to increase in QRS duration appeared to be more closely related to the vascular stream than non specific binding leading to a deeper accumulation process.

Physiological pharmacokinetic modelling

1. The different types of models are described, with emphasis on the clearance-based one-compartment model, and on full physiological models which distinguish between a number of anatomical compartments interconnected through the body fluid system. 2. The clearance-based, one-compartment model incorporates physiological concepts, such as apparent volume of distribution, systemic availability, hepatic and renal clearance. As opposed to the classical rate constant-based model, it allows a study of the influence of plasma protein binding, hepatic intrinsic clearance and blood flow. The advantages of such an approach are illustrated in two typical situations, namely renal insufficiency and saturable protein binding. 3. In full physiological models each compartment represents a particular organ or tissue, further divided into vascular, interstitial and cellular spaces. Mass balance equations are written for each of these subcompartments. Shortcomings of such comprehensive models include difficulty in collecting tissue data, especially human, and sophisticated numerical techniques needed for parameter estimation. The main advantages are specific organ metabolism and transport, and the possibility of scaling up from animal to human. 4. The pharmacokinetic parameters important for new drug registration are also listed.

[Pharmacokinetics of drugs in single and multiple organ failure]

Organ failure modifies the pharmacokinetics of drugs and usually requires a decrease in their dosage. A decrease in cardiac output, in protein binding and extraction ratio, hepatic and renal insufficiency, a modification in acid-base balance are the main factors regulating pharmacokinetics of drugs used in anaesthesia and intensive therapy.

Pharmacokinetics of intravenous cefetamet and oral cefetamet pivoxil in patients with renal insufficiency

The pharmacokinetics of cefetamet after a short intravenous infusion of cefetamet (515 mg) and oral administration of 1,000 mg of cefetamet pivoxil were studied in 9 healthy subjects and in 38 patients with various degrees of renal impairment. The results showed that cefetamet elimination was dependent on renal function. After intravenous dosing, total body (CLS), renal (CLR), and nonrenal (CLNR) clearances were linearly related to creatinine clearance (CLCR; r = 0.95, 0.92, and 0.59, respectively). Elimination half-life (t1/2 beta) was prolonged from 2.46 +/- 0.33 h in normal subjects to 29.1 +/- 13.9 h in patients with CLCR of less than 10 ml/min per 1.73 m2. Correspondingly, CLS and CLR decreased from 1.77 +/- 0.27 and 1.42 +/- 0.25 ml/min per kg to 0.14 +/- 0.04 and 0.04 +/- 0.03 ml/min per kg, respectively. The volume of distribution at steady state (0.298 +/- 0.049 liter/kg) for cefetamet was not altered by renal insufficiency (P greater than 0.05). After oral administration, the elimination parameters, t1/2 beta and CLR, were insignificantly different from the intravenous data (P greater than 0.05). Furthermore, the bioavailability (F) of cefetamet pivoxil (45 +/- 13%) was not altered by renal failure (P greater than 0.05). However, maximum concentration in plasma and the time to achieve this value were significantly increased (5.86 +/- 0.74 versus 14.8 +/- 6.14 micrograms/ml and 3.9 +/- 1.1 versus 8.4 +/- 1.7 h, respectively; P less than 0.05). Based on these observations, it is recommended that patients with CLcr of <10 ml/min per 1.73 m2 and between 10 and 39 ml/min per 1.73 m2 be given one-quarter of the normal daily dose either once or twice daily. Patients with CLcr between 40 and 80 ml/min per 1.73 m2 should receive one-half of the normal dose twice daily. For patients with CLcr of <10 ml/min per 1.73 m2, it would be recommended that they receive a normal standard dose as a loading dose on day 1 of treatment.

Pharmacokinetics and dromotropic activity of ajmaline in rats with hyperthyroidism

1. The pharmacokinetics and the dromotropic action (increased PQ interval) of intravenously administered ajmaline (2 mg kg-1) were studied in hyperthyroid rats with sinus tachycardia. The hyperthyroidism was induced by intraperitoneal injection of 3,5,3'-triiodo-L-thyronine (0.5 mg kg-1) for 4 days. 2. The change in the ajmaline concentration in whole blood could be described by a biexponential equation. The steady state distribution volume of ajmaline decreased from 4.81 l kg-1 in control rats to 3.80 l kg-1 in hyperthyroid rats and the total body blood clearance was slightly higher in hyperthyroid rats than in control rats. 3. Ajmaline exhibited a saturable binding to rat plasma proteins, and one kind of binding site was found in the observed range of concentrations. The binding capacity was 2 fold higher in hyperthyroid rats than in control rats. 4. On the basis of the plasma unbound concentration, ajmaline exhibited an increased negative dromotropic activity in hyperthyroid rats compared with control rats. 5. A positive correlation was found between the pacing rate and the dromotropic action of ajmaline on atrioventricular conduction in isolated perfused hearts. There was no significant difference in the rate-dependence of the effect of ajmaline on the heart between control and hyperthyroid rats. 6. Our findings suggest that the increased dromotropic activity of ajmaline is mainly due to the increased heart rate in hyperthyroid rats.

The use of mass balance principles to describe regional drug distribution and elimination

Mass balance principles were used to derive a number of terms that are helpful in describing the rate and extent of regional drug uptake. Regional drug uptake was defined as the net movement of drug from the blood perfusing a region into the extravascular space of the region due to the distribution and/or elimination of the drug. By analogy with the traditional physiological definition of flux, net drug flux was defined as the difference in mass per unit time of drug respectively entering and leaving a region via the arterial and venous blood vessels. The time-integral of net drug flux, net drug mass, was defined as the mass of drug that has entered a region via the arterial blood vessels but has not left the region via the venous blood vessels. For regions in which no drug elimination occurs, the mean regional drug concentration was defined as the net drug mass divided by the mass of the region. When a number of criteria are satisfied, the net drug flux is approximately the rate of drug uptake and the net drug mass is approximately the extent of drug uptake. Several examples are given to demonstrate the broad range of applications of mass balance principles. First, the method was used to characterize the differences between drug distribution and elimination in a hypothetical region using drug concentrations simulated from compartmental models of either distribution alone or distribution with elimination. Second, the whole body distribution net flux was described during a constant rate infusion of iodohippurate (IOH) into a sheep from the difference between the whole body net flux and renal net flux of IOH. Third, the time course of the mean myocardial lignocaine (lidocaine) concentrations in a sheep after an intravenous bolus of lignocaine were described. The time course of the lignocaine-induced depression of myocardial contractility followed more closely the mean myocardial lignocaine concentrations than that of either the arterial or coronary sinus blood concentrations. It is concluded that the use of mass balance principles provides a simple, empirical, and physiologically based method for the determination of the rate and extent of both drug distribution and elimination in regions as simple as single organs or as complex as the whole body.

The pharmacokinetics of bendazac-lysine and 5-hydroxybendazac, its main metabolite, in patients with hepatic cirrhosis

We have studied the pharmacokinetics of bendazac and its major metabolite, 5-hydroxybendazac, in 11 patients with hepatic cirrhosis after the oral administration of a single 500 mg tablet of bendazac-lysine, and compared them with those obtained from 10 healthy adults. The rate of absorption of bendazac, as assessed by tmax and Cmax, is similar in patients and in healthy subjects. The drug is eliminated mostly by metabolism in healthy adults, more than 60% of the dose being excreted in the urine as 5-hydroxybendazac and its glucuronide. Hepatic insufficiency impairs this metabolism, a two-fold decrease in apparent plasma clearance (CL/f) being observed in the patients. Although the plasma unbound fraction of bendazac is increased in patients (the drug is highly bound to plasma albumin), the apparent volume of distribution (V/f) is unchanged. In consequence, the half-life of bendazac is increased two-fold in the patients. Impairment of metabolism decreases the formation of 5-hydroxybendazac, but metabolism remains the main route of its elimination. Renal excretion of bendazac accounts for about 10% of the dose in both patients with cirrhosis and healthy subjects. We conclude that in patients with severe hepatic insufficiency the daily dose of bendazac-lysine should be halved.

Dose-dependent pharmacokinetics of valproate in guinea pigs of different ages

The dose-dependence of sodium valproate (VPA) pharmacokinetics in relation to age was studied using guinea pigs. Sodium valproate in doses of 20, 200, and 600 mg/kg was administered by rapid intravenous infusion to male guinea pigs 3, 21, and 42 days old. Serum levels of VPA were determined by gas chromatography. Pharmacokinetic parameters were calculated based upon a two-compartment model. The area under the plasma concentration-time curve (AUC) increased out of proportion at the 600 mg/kg dose level in all groups. Other pharmacokinetic changes were as follows: in 3-day-old guinea pigs, the slow disposition rate constant (beta), the elimination rate constant from central compartment (K10), and the total clearance (Clt) were significantly decreased and the beta phase half-life (t 1/2) and the volume of central compartment (V1) were significantly increased at the 600 mg/kg dose level. In 21-day-old guinea pigs, beta and K10 were significantly decreased and t1/2 and V1 were significantly increased at doses of both 200 mg/kg and 600 mg/kg. In 42-day-old guinea pigs, however, only V1 and the volume of distribution at steady-state (Vss) showed significant increase after increasing doses. The extraction ratio (E) and the clearance of unbound drug (Clu), which were calculated based on unbound plasma levels, indicate that the dose-dependent kinetics of VPA are probably due to saturation of metabolism and that the metabolic capacity for VPA in the newborn group is the smallest among all groups.

Pharmacokinetics of bendazac-lysine and 5-hydroxybendazac in patients with renal insufficiency

The pharmacokinetics of bendazac and its major metabolite, 5-hydroxybendazac, have been investigated in 15 patients with moderate to severe renal insufficiency and renal failure following a single oral dose of 500 mg bendazac-lysine. The pharmacokinetic parameters were compared to those obtained in 10 healthy adult volunteers. The rate and the extent of absorption of bendazac was not modified in the patients with moderate and severe renal insufficiency, nor was there any change in plasma tmax, Cmax, apparent elimination t1/2 and AUC. There was a significant increase in the unbound fraction of bendazac in renal failure patients undergoing haemodialysis, with a consequent increase in the apparent volume of distribution (V/F) and apparent plasma clearance (CL/F), and a decrease in plasma Cmax and AUC. Simultaneous changes of V/F and CL/F lead to an unchanged plasma t1/2 in these patients. Renal clearance (CLR) was decreased, but CL/F was not affected, since renal excretion is a minor route of elimination of bendazac. Bendazac is mostly eliminated by metabolism to 5-hydroxybendazac, in healthy subjects greater than 60% of a dose being excreted in urine as 5-hydroxybendazac and its glucuronide. In patients with renal insufficiency urinary excretion of 5-hydroxybendazac was decreased and the systemic availability of the metabolite (AUC), was increased about three-fold, irrespective of the degree of renal failure. Plasma 5-hydroxybendazac glucuronide accumulated according to the degree of renal insufficiency. Overall it can be assumed that the pharmacological effect of the drug will not be enhanced in renal failure and that the dosage regimen of bendazac-lysine in such patients need not be modified.

Pharmacokinetics of intravenous bepridil in patients with coronary disease

The pharmacokinetics of intravenous bepridil (1-[2-(N-benzylanilino)-1-(isobutoxymethyl)ethyl]pyrrolidine ) were studied in 16 patients undergoing cardiac catheterization for evaluation of coronary disease, all with normal base-line hemodynamic and renal functions. Ten patients received 3 mg/kg and six patients received 4 mg/kg of bepridil infused over a period of 30 min. Plasma bepridil concentrations were measured by HPLC and analyzed by model-dependent and model-independent methods. The mean (+/- SD) maximum plasma bepridil concentrations at the end of the infusion were 2047 +/- 820 ng/mL (3 mg/kg) and 2478 +/- 1426 ng/mL (4 mg/kg). Postinfusion bepridil concentrations were best described by a two-compartment open model. The model-dependent harmonic mean distribution and elimination half-lives were 1.7 h (range: 1.1-2.2 h) and 19.7 h (range: 8.0-61.9 h), respectively. The harmonic mean elimination half-life from model-independent analysis was 14.9 h (range: 7.4-64.0 h). The arithmetic means of other model-independent kinetic parameters were systemic clearance, 0.524 +/- 0.215 L X kg-1 X h-1; Vd, 15.3 +/- 10.9 L/kg; and Vdss, 10.1 +/- 6.0 L/kg. Model-dependent and model-independent estimates of half-life and clearance agreed reasonably well. Bepridil was well tolerated, effecting little or no change in central hemodynamics or EKG intervals. The extensive distribution and relatively slow clearance of bepridil account for its long elimination half-life. Intravenous bepridil appears to be a safe calcium (II) antagonist that is suitable for once-a-day dosing.

Pharmacokinetics of carumonam in patients with renal insufficiency

The pharmacokinetics of carumonam after a single 1,000-mg intravenous infusion (20 min) were evaluated in four groups of subjects who had various degrees of renal impairment: group 1, CLCR greater than 60 ml/min; group 2, CLCR = 30 to 60 ml/min; group 3, CLCR = 10 to 30 ml/min; and group 4, CLCR less than 10 ml/min). The elimination half-life of carumonam increased with decreasing creatinine clearance (CLCR) from 1.7 h in group 1 to 11.3 h in group 4. Peak carumonam concentration (103 micrograms/ml) and steady-state volume of distribution (12.8 liters) did not change with decreasing CLCR. Total body clearance (r = 0.98), renal clearance (r = 0.98), and nonrenal clearance (r = 0.67) of carumonam correlated with decreasing CLCR. Mean nonrenal clearance was 21 ml/min in group 1 and 12 ml/min in group 4. With regard to dosage, patients with a CLCR above 60 ml/min should receive their standard maintenance dose of carumonam without any changes; patients with a CLCR between 30 and 60 ml/min should receive the dose every 12 h; and individuals with a CLCR between 10 and 30 ml/min should be given the dose once a day. Patients with a CLCR of less than 10 ml/min should receive one-half of the dose once a day. Our recommended dosage regimens should produce within the CLCR borderlines of each group average plasma concentrations that are between one and two times that achieved in normal subjects with a t.i.d. dosage regimen.

Absolute bioavailability of mianserin tablets and solution in healthy humans

A pharmacokinetic study with mianserin . HCl was performed in six healthy male subjects. The subjects were treated on different occasions intravenously with a constant-rate infusion of 5 mg mianserin. HCl in 1 h, orally with a single dose of 60 mg as two tablets of 30 mg each and with 60 mg as an oral solution. The wash-out period between treatments was 1 month. Blood samples were taken at predetermined times over a period of 120 h following dosing. The mianserin concentration in the plasma samples was determined and the results were pharmacokinetically analyzed. The intravenous data could be adequately described by a 3-compartment model and the oral data by a 2-compartment model, both with first-order transfer and elimination rate constants. The mean plasma clearance of mianserin was found to be 19 +/- 2 l h-1 (mean +/- SEM), the kinetic volume of distribution 444 +/- 250 l, the steady-state volume of distribution 242 +/- 171 l and the elimination half-life 33 +/- 5 h. The absolute bioavailability in terms of extent of absorption was 22 +/- 3% for the solution and 20 +/- 3% for the tablets. The mean peak level for the solution was 79 +/- 11 ng X ml-1 and for the tablets 54 +/- 5 ng X ml-1; mean peak time for the solution was 1.1 +/- 0.2 h and for the tablets 1.4 +/- 0.2 h. The mean absorption half-life for the solution was 0.43 +/- 0.13 h and for the tablets 0.39 +/- 0.11 h.(ABSTRACT TRUNCATED AT 250 WORDS)

Clinical pharmacokinetics of the third generation cephalosporins

At the present time, the third generation cephalosporins that are already on the market or close to this point include cefsulodin, cefotaxime, cefoperazone, latamoxef, ceftriaxone, ceftazidime, ceftizoxime and cefotetan. Other newer compounds are also under development but have not been included in this review. None of the third generation compounds is suitable for oral administration and, accordingly, their pharmacokinetics have been studied only after intravenous and intramuscular administration. Microbiological assays and HPLC methods have been used for the measurement of plasma/serum, urine, bile and cerebrospinal fluid (CSF) concentrations. As found with cefotaxime, microbiological assays should only be used when the full metabolite spectrum of a particular drug is known, as otherwise, the presence of microbiologically active metabolites may lead to erroneous conclusions. Under normal conditions, the major route of elimination is via the kidneys for cefsulodin, latamoxef, ceftazidime, ceftizoxime and cefotetan. In contrast, cefoperazone is mainly eliminated in the bile, whereas cefotaxime and ceftriaxone depend both on the liver and the kidneys for their elimination. With the exception of ceftriaxone, which has a longer elimination half-life (i.e. around 8 hours), all the other third generation cephalosporins have a t1/2 ranging between 1.5 and 2.5 hours. Plasma protein binding is variable from one compound to another. However, the clinical relevance of this parameter is not clearly established since tissue penetration also depends on the relative affinity of the drug for tissue components. Third generation cephalosporins seem to penetrate adequately into the CSF and, thus pharmacokinetically appear to be appropriate agents for the treatment of meningitis. The degree of modification of pharmacokinetic parameters by renal insufficiency or hepatic diseases depends, as for other drugs, on the extent to which the compound is excreted via the kidneys or the liver. The third generation cephalosporins have been extensively studied under these conditions and recommendations for dosage modification in special circumstances are available for most of them. The pharmacokinetics of some third generation cephalosporins may be modified in neonates and elderly patients. Accordingly, their use at the extremes of age must be accompanied by a closer than usual clinical monitoring of the patient. From a clinical point of view, the third generation cephalosporins possess reliable pharmacokinetic properties.(ABSTRACT TRUNCATED AT 400 WORDS)

Lack of effect of tenoxicam on glibornuride kinetics and response

The pharmacokinetics of glibornuride (25 mg i.v.) and the accompanying insulin and glucose responses were characterized in eight human subjects in the presence and absence of steady-state tenoxicam (20 mg p.o./day for 2 weeks). Tenoxicam affected neither the pharmacokinetic parameters of glibornuride (systemic clearance, volume of distribution and biological half-life) nor the responses of plasma insulin and blood glucose to glibornuride. The single i.v. dose of glibornuride had no detectable effect on the kinetics of tenoxicam.

Pharmacokinetic effects of altered plasma protein binding of drugs in renal disease

The measurement of plasma drug concentrations provides no insight into the relationship between the free and the plasma-protein-bound fractions of drugs. Plasma protein binding may decrease in renal disease due to uremia, hypoalbuminemia, or due to drug interactions. Decreased plasma protein binding leads to an increase in free plasma fraction causing an increase in volume of distribution and a shorter elimination half life. The increase in the apparent volume of distribution and the shorter elimination half life cause a decrease in total plasma concentration. Therefore, the free drug concentration is more reliable than the total plasma concentration for therapeutic drug monitoring. However, the free amount in plasma and in tissue and the tissue-bound amount remain unchanged under steady state conditions. Thus, a decrease in plasma protein binding in renal disease usually does not lead to increased drug toxicity, and alteration of drug dosage is not required, although the total plasma concentration may be found to be considerably lower than normal. In addition to plasma protein binding, alteration of tissue binding must also be considered for the determination of the appropriate dosage of some drugs in renal disease.