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.     

Clinical pharmacokinetics of nimesulide

Nimesulide is a selective COX-2 inhibitor used in a variety of inflammatory, pain and fever states. After healthy volunteers received oral nimesulide 100 mg in tablet, granule or suspension form the drug was rapidly and extensively absorbed. Mean peak concentrations (Cmax) of 2.86 to 6.50 mg/L were achieved within 1.22 to 2.75 hours of administration. The presence of food did not reduce either the rate or extent of nimesulide absorption. When nimesulide was administered in the suppository form, the Cmax was lower and occurred later than after oral administration; the bioavailability of nimesulide via suppository ranged from 54 to 64%, relative to that of orally administered formulations. Nimesulide is rapidly distributed and has an apparent volume of distribution ranging between 0.18 and 0.39 L/kg. It is extensively bound to albumin; the unbound fraction in plasma was 1%. The unbound fraction increased to 2 and 4% in patients with renal or hepatic insufficiency. With oral administration, the concentrations of nimesulide declined monoexponentially following Cmax. The estimated mean terminal elimination half-life varied from 1.80 to 4.73 hours. Excretion of the unchanged drug in urine and faeces is negligible. Nimesulide is largely eliminated via metabolic transformation and the principal metabolite is the 4'-hydroxy derivative (M1). Minor metabolites have been detected in urine and faeces, mainly in a conjugated form. Pharmacological tests in vivo have shown that the metabolites are endowed with anti-inflammatory and analgesic properties, although their activity is lower than that of nimesulide. Excretion in the urine and faeces accounted for 50.5 to 62.5% and 17.9 to 36.2% of an orally administered dose, respectively. The total plasma clearance of nimesulide, was 31.02 to 106.16 ml/h/kg, reflecting almost exclusive metabolic clearance. The drug has a low extraction ratio, close to 0.1. With twice daily oral or rectal administration of nimesulide, steady-state was achieved within 24 to 48 hours (2 to 4 administrations); only modest accumulation of nimesulide and M1 occurred. Gender has only a limited influence on the pharmacokinetic profiles of nimesulide and M1. The pharmacokinetic profiles of nimesulide and M1 in children and the elderly did not differ from that of healthy young individuals. Hepatic insufficiency affected the pharmacokinetics of nimesulide and M1 to a significant extent: the rate of elimination of nimesulide and M1 was remarkably reduced in comparison to the rate of elimination in healthy individuals. Therefore, a dose reduction (4 to 5 times) is required in patients with hepatic impairment. The pharmacokinetic profile of nimesulide and M1 was not altered in patients with moderate renal failure and no dose adjustment in patients with creatinine clearances higher than 1.8 L/h is envisaged. Pharmacokinetic interactions between nimesulide and other drugs given in combination [i.e. glibenclamide, cimetidine, antacids, furosemide (frusemide), theophylline, warfarin and digoxin] were absent, or of no apparent clinical relevance.     

Clinical pharmacokinetics of irinotecan

Nitric oxide (NO) and cyclic guanosine 3',5'-monophosphate (cGMP) have been reported to prevent vascular smooth muscle cell (VSMC) proliferation and have beneficial effects to reduce intimal thickening in response to arterial injury. The purpose of this study was to determine whether the downstream effector molecule of NO-cGMP signaling, cyclic GMP-dependent protein kinase (PKG), regulates phenotypic modulation and proliferation in cultured rat aortic VSMC. PKG-expressing VSMC lines were created by transfection of PKG-deficient cell lines and characterized. All forms of PKG, i.e. PKG-I alpha and PKG-I beta, as well as the constitutively active catalytic domain of PKG-I, transformed dedifferentiated 'synthetic' VSMC to a more contractile-like morphology. PKG expression resulted in an increased production of the contractile phenotype marker proteins, smooth muscle myosin heavy chain-2, calponin and alpha-actin and restored the capacity of cAMP and cGMP analogues to inhibit platelet-derived growth factor (PDGF)-induced cell migration. On the other hand, PKG expression had no significant effects on PDGF-induced cell proliferation. These results suggest that PKG expression contributes to the regulation of a contractile-like phenotypic expression in cultured VSMC, and the suppression of PKG expression during cultured growth in vitro may permit the modulation of cells to a more synthetic, dedifferentiated phenotype.     

Clinical pharmacokinetics of acamprosate

Acamprosate is a new psychotropic drug used in the treatment of alcohol (ethanol)-dependence. Recent studies suggest that acamprosate inhibits neuronal hyperexcitability by antagonising excitatory amino acids. It is available as a 333 mg enteric-coated tablet, with a recommended dosage of 1.3 g/day for patients with a bodyweight < 60 kg and 2 g/day for patients with a bodyweight > or = 60 kg. Treatment with higher dose strength tablets 2 x 500 mg twice daily is bioequivalent to treatment with the 2 x 333 mg 3 times daily dosage regimen. Acamprosate is absorbed via the paracellular route in the gastrointestinal tract. Absorption is rapid but limited after oral administration. At steady-state, acamprosate has a moderate distribution volume of about 20L. Acamprosate is not protein bound or metabolised. Half of the elimination of acamprosate occurs as unchanged acetyl-homotaurine in urine, the other half might be eliminated by biliary excretion. The administration of the enteric-coated tablets showed a flip-flop mechanism with a terminal elimination half-life 10-fold higher than the 3-hour half-life reported after intravenous infusion. During repeated oral administration of 666 mg 3 times daily, steady-state is reached after 5 to 7 days and leads to plasma concentrations ranging from 370 to 650 micrograms/L. The pharmacokinetics of acamprosate administered as an enteric-coated tablets are time- and dose-independent, and its accumulation ratio is about 2.4 at steady-state. Acamprosate disposition does not differ between males and females. The pharmacokinetics of acamprosate are not modified in patients with hepatic insufficiency or chronic alcoholism. In contrast, renal insufficiency influences the elimination of acamprosate and it is, therefore, contraindicated under such circumstances. Interaction studies have confirmed that when acamprosate is concomitantly administered with food, the amount absorbed is decreased. When combined with diazepam, disulfiram or alcohol, the pharmacokinetic disposition of acamprosate is not modified. Acamprosate does not influence the kinetics of diazepam, alcohol or imipramine and its metabolite desipramine.     

Levonorgestrel. Clinical pharmacokinetics

Published values for the serum concentrations and pharmacokinetic parameters of levonorgestrel after administration of various doses of levonorgestrel alone or with ethinylestradiol are reviewed. Most data apply to oral administration of the gestagen, with the smaller amount of data for other modes of administration, e.g. subcutaneous, intravaginal and intra-uterine administration, also included. There is a large variability among the different studies for both serum concentration and pharmacokinetic parameters and not all of this is due to the large interindividual variability demonstrated in all of the studies. The factors responsible for the inter- and intraindividual variability have not been discovered. Sex hormone binding globulin (SHBG) plays an important role in levonorgestrel pharmacokinetics since: (i) levonorgestrel binds strongly to this protein; and (ii) serum SHBG levels are influenced by a large number of different factors including the administration of levonorgestrel and ethinylestradiol. However, not all of the anomalies in the metabolism of levonorgestrel can be ascribed to its interaction with SHBG.     

Clinical pharmacokinetics of mycophenolate mofetil

The pharmacokinetics of the immunosuppressant mycophenolate mofetil have been investigated in healthy volunteers and mainly in recipients of renal allografts. Following oral administration, mycophenolate mofetil was rapidly and completely absorbed, and underwent extensive presystemic de-esterification. Systemic plasma clearance of intravenous mycophenolate mofetil was around 10 L/min in healthy individuals, and plasma mycophenolate mofetil concentrations fell below the quantitation limit (0.4 mg/L) within 10 minutes of the cessation of infusion. Similar plasma mycophenolate mofetil concentrations were seen after intravenous administration in patients with severe renal or hepatic impairment, implying that the de-esterification process had not been substantially affected. Mycophenolic acid, the active immunosuppressant species, is glucuronidated to a stable phenolic glucuronide (MPAG) which is not pharmacologically active. Over 90% of the administered dose is eventually excreted in the urine, mostly as MPAG. The magnitude of the MPAG renal clearance indicates that active tubular secretion of MPAG must occur. At clinically relevant concentrations, mycophenolic acid and MPAG are about 97% and 82% bound to albumin, respectively. MPAG at high (but clinically realisable) concentrations reduced the plasma binding of mycophenolic acid. The mean maximum plasma mycophenolic acid concentration (Cmax) after a mycophenolate mofetil 1 g dose in healthy individuals was around 25 mg/L, occurred at 0.8 hours postdose, decayed with a mean apparent half-life (t1/2) of around 16 hours, and generated a mean total area under the plasma concentration-time curve (AUC infinity) of around 64 mg.h/L. Intra- and interindividual coefficients of variation for the AUC infinity of the drug were estimated to be 25% and 10%, respectively. Intravenous and oral administration of mycophenolate mofetil showed statistically equivalent MPA AUC infinity values in healthy individuals. Compared with mycophenolic acid, MPAG showed a roughly similar Cmax about 1 hour after mycophenolic acid Cmax, with a similar t1/2 and an AUC infinity about 5-fold larger than that for mycophenolic acid. Secondary mycophenolic acid peaks represent a significant enterohepatic cycling process. Since MPAG was the sole material excreted in bile, entrohepatic cycling must involve colonic bacterial deconjugation of MPAG. An oral cholestyramine interaction study showed that the mean contribution of entrohepatic cycling to the AUC infinity of mycophenolic acid was around 40% with a range of 10 to 60%. The pharmacokinetics of patients with renal transplants (after 3 months or more) compared with those of healthy individuals were similar after oral mycophenolate mofetil. Immediately post-transplant, the mean Cmax and AUC infinity of mycophenolic acid were 30 to 50% of those in the 3-month post-transplant patients. These parameters rose slowly over the 3-month interval. Slow metabolic changes, rather than poor absorption, seem responsible for this nonstationarity, since intravenous and oral administration of mycophenolate mofetil in the immediate post-transplant period generated comparable MPA AUC infinity values. Renal impairment had no major effect on the pharmacokinetic of mycophenolic acid after single doses of mycophenolate mofetil, but there was a progressive decrease in MPAG clearance as glomerular filtration rate (GFR) declined. Compared to individuals with a normal GFR, patients with severe renal impairment (GFR 1.5 L/h/1.73m2) showed 3-to 6-fold higher MPAG AUC values. In rental transplant recipients during acute renal impairment in the early post-transplant period, the plasma MPA concentrations were comparable to those in patients without renal failure, whereas plasma MPAG concentrations were 2- to 3-fold higher. Haemodialysis had no major effect on plasma mycophenolic acid or MPAG. Dosage adjustments appear to not be necessary either in renal impairment or during dialysis. (ABSTRACT TRUN     

Clinical pharmacokinetics of nisoldipine coat-core

Nisoldipine, a calcium antagonist of the dihydropyridine type, is the active ingredient of the controlled release nisoldipine coat-core (CC) formulation. In humans, the absorption from nisoldipine CC occurs across the entire gastrointestinal tract with an increase in bioavailability in the colon because of the lower concentrations of metabolising enzymes in the distal gut wall. Although nisoldipine is almost completely absorbed, its absolute bioavailability from the CC tablet is only 5.5%, as a result of significant first-pass metabolism in the gut and liver. Nisoldipine is a high-clearance drug with substantial interindividual and relatively lower intraindividual variability in pharmacokinetics, dependent on liver blood flow. Nisoldipine is highly (> 99%) protein bound. Its elimination is almost exclusively via the metabolic route and renal excretion of metabolites dominates over excretion in the faeces. Although nisoldipine is administered as a racemic mixture, its plasma concentrations are almost entirely caused by the eutomer as a result of highly stereoselective intrinsic clearance. Nisoldipine CC demonstrates linear pharmacokinetics in the therapeutic dose range and its steady-state pharmacokinetics are predictable from single dose data. Steady-state is reached with the second dose when the drug is given once daily and the peak-trough fluctuations in plasma concentration is minimal. Plasma-concentrations of nisoldipine increase with age. Careful dose titration according to individual clinical response is recommended in the elderly. Nisoldipine CC should not be used in patients with liver cirrhosis, though dosage adjustments in patients with renal impairment are not necessary. Inter-ethnic differences in its pharmacokinetics are not evident. Owing to inhibition of metabolising enzymes, a small dosage adjustment decrement for nisoldipine CC may be required when it is given in combination with cimetidine. Concomitant ingestion of nisoldipine with grapefruit juice should be avoided. Inducers of cytochrome P450 (CYP) 3A4, e.g. rifampicin (rifampin) and phenytoin should not be combined with nisoldipine CC, as they may reduce its bioavailability and result in a loss of efficacy. The concomitant use of other drugs which may produce marked induction or inhibition of CYP3A4 is contraindicated. Concomitant intake of the CC tablet with high fat, high calorie foods resulted in an increase in the maximum plasma concentrations of nisoldipine. The 'food-effect' can be avoided by administration of the CC tablet up to 30 minutes before the intake of food [corrected]. Plasma concentrations of nisoldipine are related to its antihypertensive effect via a maximum effect model. Nisoldipine CC once daily produce reductions in blood pressure which are maintained over 24 hours in the absence of relevant effects on heart rate.     

Clinical pharmacokinetics of carboplatin in children

The present study was undertaken to evaluate in children the plasma pharmacokinetics of free carboplatin given at different doses and schedules and to evaluate the inter- and intrapatient variability and the possible influence of schedule on drug exposure. A total of 35 children (age range, 1-17 years) with malignant tumors were studied. All patients had normal renal function (creatinine clearance corrected for surface body area, above 70 ml min-1 m-2; range, 71-151 ml min-1 m-2) and none had renal involvement by malignancy. Carboplatin was given at the following doses and schedules: 175, 400, 500, and 600 mg/m2 given as as a 1-h infusion; 1,200 mg/m2 divided into equal doses and infused over 1 h on 2 consecutive days; and 875 and 1,200 mg/m2 given as a 5-day continuous infusion. A total of 57 courses were studied. Carboplatin levels in plasma ultrafiltrate (UF) samples were measured both by high-performance liquid chromatography and by atomic absorption spectrophotometry. Following a 1-h infusion, carboplatin free plasma levels decayed biphasically; the disappearance half-lives, total body clearance, and apparent volume of distribution were similar for different doses. In children with normal renal function as defined by creatinemia and blood urea nitrogen (BUN) and creatinine clearance, we found at each dose studied a limited interpatient variability of the peak plasma concentration (Cmax) and the area under the concentration-time curve (AUC) and a linear correlation between the dose and both Cmax (r = 0.95) and AUC (r = 0.97). The mean value +/- SD for the dose-normalized AUC was 13 +/- 2 min m2 l-1 (n = 57).2+ The administration schedule does not seem to influence drug exposure, since prolonged i.v. infusion or bolus administration of 1,200 mg/m2 achieved a similar AUC (13.78 +/- 2.90 and 15.05 +/- 1.44 mg ml-1 min, respectively). In the nine children studied during subsequent courses a limited interpatient variability was observed and no correlation (r = 0.035) was found between AUC and subsequent courses by a multivariate analysis of dose, AUC, and course number. The pharmacokinetic parameters were similar to those previously reported in adults; however, a weak correlation (r = 0.52, P = 0.03) between carboplatin total body clearance and creatinine clearance varying within the normal range was observed.(ABSTRACT TRUNCATED AT 400 WORDS)     

Clinical pharmacokinetics of vasodilators. Part II

The legume lectins are a large family of homologous carbohydrate binding proteins that are found mainly in the seeds of most legume plants. Despite their strong similarity on the level of their amino acid sequences and tertiary structures, their carbohydrate specificities and quaternary structures vary widely. In this review we will focus on the structural features of legume lectins and their complexes with carbohydrates. These will be discussed in the light of recent mutagenesis results when appropriate. Monosaccharide specificity seems to be achieved by the use of a conserved core of residues that hydrogen bond to the sugar, and a variable loop that determines the exact shape of the monosaccharide binding site. The higher affinity for particular oligosaccharides and monosaccharides containing a hydrophobic aglycon results mainly from a few distinct subsites next to the monosaccharide binding site. These subsites consist of a small number of variable residues and are found in both the mannose and galactose specificity groups. The quaternary structures of these proteins form the basis of a higher level of specificity, where the spacing between individual epitopes of multivalent carbohydrates becomes important. This results in homogeneous cross-linked lattices even in mixed precipitation systems, and is of relevance for their effects on the biological activities of cells such as mitogenic responses. Quaternary structure is also thought to play an important role in the high affinity interaction between some legume lectins and adenine and a series of adenine-derived plant hormones. The molecular basis of the variation in quaternary structure in this group of proteins is poorly understood.     

Clinical pharmacokinetics of camptothecin topoisomerase I inhibitors

In this review the clinical pharmacokinetics of camptothecin topoisomerase I inhibitors, an important new class of anticancer drugs, is discussed. Two prototypes, topotecan and irinotecan, are currently marketed in many European countries and the USA for the treatment of patients with ovarian and colorectal cancer, respectively. Other camptothecin derivatives, including lurtotecan, 9-aminocamptothecin (9-AC) and 9-nitrocamptothecin (9-NC), are at different stages of clinical development. The common property of camptothecin analogues is their action against DNA topoisomerase I, but beyond this similarity the compounds differ widely in terms of antitumour efficacy, pharmacology, pharmacokinetics and metabolism. We review chemistry, mechanism of action, stability and bioanalysis of the camptothecins. Dosage and administration, status of clinical application, pharmacokinetics, pharmacodynamics and drug interactions are discussed.     

Clinical pharmacokinetics of tiaprofenic acid and its enantiomers

Tiaprofenic acid is a chiral nonsteroidal anti-inflammatory drug (NSAID) of the 2-arylpropionic acid (2-APA) class. A common structural feature of 2-APA NSAIDs is a sp3-hybridised tetrahedral chiral carbon heteroatom within the propionic acid side chain moiety, with the S-enantiomer possessing most of the beneficial anti-inflammatory activity. However, all tiaprofenic acid preparations to date are marketed as the racemate. Tiaprofenic acid has been suggested to exhibit limited pharmacokinetic stereoselectivity. The synovium is the proposed site of action of NSAIDs when used for musculoskeletal disorders, and substantial concentrations of tiaprofenic acid are attained in synovial fluid. Recent data suggested that possibility of stereoselective distribution of tiaprofenic acid into synovium and cartilage. Hence, data generated using non-stereospecific assays may not always be extrapolated to explain the disposition of the individual enantiomers. Tiaprofenic acid is rapidly and almost completely absorbed when given orally. The area under the plasma concentration-time curve (AUC) of tiaprofenic acid is proportional to the oral dose administered. A sustained release dosage form is available, which may be beneficial due to the short terminal phase half-life of tiaprofenic acid (3 to 6 hours). The bioavailability is the same as that with conventional rapid release preparations, although the peak plasma drug concentration is reduced and time peak is prolonged. Tiaprofenic acid binds extensively to plasma albumin. These is negligible R to S inversion upon oral administration. Tiaprofenic acid is eliminated following extensive biotransformation to glucuronide-conjugated metabolites. Approximately 60% is eliminated as conjugates excreted in urine, and little drug is eliminated unchanged. The rate of excretion of tiaprofenic acid and its conjugates may be related to renal function; accumulation of conjugates occurs in end-stage renal disease, but not in young individuals or elderly patients. Potentially clinically important drug interactions with tiaprofenic acid have been demonstrated for some anticoagulants and probenecid. Relationships between tiaprofenic acid concentrations in biological matrices and therapeutic or toxic effects have not yet been elucidated for this drug.     

Clinical pharmacokinetics of various topical ophthalmic delivery systems

The eye provides an interesting study in contrasts: it is a delicate structure with a transparent anterior wall as thin as 0.5mm; yet this structure in combination with the ocular adnexa provides a resilient physicochemical barrier. The lids, tears and lacrimal apparatus work in concert to continuously protect the cornea and conjunctiva with a stable tear film, which also serves as the primary refracting surface. This elaborate defence system simultaneously prevents ready intraocular access of pharmaceutical agents. Additionally, the trilaminate structure of the cornea has variable permeability to chemical agents, thereby further limiting the passage of highly hydrophobic and hydrophilic moieties. Presenting topical pharmaceutical agents to the eye via different delivery systems allows clinicians to directly affect the profile of drug bioavailability and, ultimately, bioactivity. While achieving optimum bioavailability is therapeutically important, one must simultaneously limit the occurrence of drug-induced adverse effects, both systemic and local. Utilising the different pharmacokinetic properties of drug delivery systems permits clinicians to maximise their therapeutic plans for addressing specific clinical situations while minimising the potential for adverse drug effects.     

Clinical pharmacokinetics of antimicrobial drugs in cystic fibrosis

The disposition of many drugs in cystic fibrosis is abnormal compared with healthy individuals. In general, changes include an increased volume of distribution expressed in liters per kg bodyweight for highly hydrophilic drugs such as aminoglycosides, and, to a lesser extent, for penicillins and cephalosporins, together with an increased total body clearance. The main reason for the increased volume of distribution is the increased amount of lean tissue per kg bodyweight, since patients with CF are generally undernourished and have a paucity of adipose tissue. The reason for the increased renal clearance is less clear. Increased glomerular filtration and tubular secretion have been observed. Protein binding generally is unaltered in CF. The fluorquinolones and vancomycin show no altered pharmacokinetics in CF although gastro-intestinal absorption may be delayed for fluorquinolones. Sulphamethoxazole shows increased clearance due to an increased acetylation and, in the case of trimethoprim, renal clearance is increased compared with healthy individuals. As a consequence, drugs that show increased clearance, will lead to reduced serum concentrations and smaller AUCs and therefore CF patients require larger doses per kg bodyweight.     

Clinical pharmacokinetics and pharmacodynamics of selegiline. An update

Schistosomes are eliminated from laboratory rats around 28 days post-infection, whilst they are still resident within the hepatic portal distributaries of the liver. We have previously shown that their presence in this location is accompanied by an intense mastocytosis. We have investigated the potential relationships between IgE responses, the allergenicity of schistosome antigens, mast cell responsiveness, and worm elimination. Total and specific IgE were measured using an ELISA and a functional assay based on 3H serotonin release from activated rat basophilic leukemia cells (RBL-SRA), respectively. Both assays revealed that infected rats produced elevated IgE titres relative to naive animals. At days 28 and 35, mixed-sex infections stimulated a higher total IgE than male-only infections. IgE was affinity purified from rat infection serum and used to probe a fractionated soluble worm antigen preparation (SWAP) by Western blotting. Two allergenic products were detected of M(r) 67 and 36-38 kDa, the former having the same molecular weight as a previously identified secretory protein. IgE from mixed-sex schistosome infections bound strongly to the 36-38 kDa molecule, compared to the relatively weak binding exhibited by IgE from male-only infection serum. Since eggs were not recovered from the infected rats, this reactivity was attributed to the greater release of allergens from female worms. Results from the RBL-SRA showed that female SWAP was a more effective trigger of mast cell degranulation in vitro, for equal amounts of protein. This enhanced allergenicity was ascribed to the relative abundance of carbohydrate moieties. Our results support a role for IgE, and mast cell degranulation in the elimination of a primary schistosome burden from rats.     

Clinical pharmacokinetics of diclofenac. Therapeutic insights and pitfalls

Diclofenac is a nonsteroidal anti-inflammatory drug (NSAID) of the phenylacetic acid class. When given orally the absorption of diclofenac is rapid and complete. Diclofenac binds extensively to plasma albumin. The area under the plasma concentration-time curve (AUC) of diclofenac is proportional to the dose for oral doses between 25 to 150 mg. Substantial concentrations of drug are attained in synovial fluid, which is the proposed site of action for NSAIDs. Concentration-effect relationships have been established for total bound, unbound and synovial fluid diclofenac concentrations. Diclofenac is eliminated following biotransformation to glucoroconjugated and sulphate metabolites which are excreted in urine, very little drug is eliminated unchanged. The excretion of conjugates may be related to renal function. Conjugate accumulation occurs in end-stage renal disease; however, no accumulation is apparent upon comparison of young and elderly individuals. Dosage adjustments for the elderly, children or for patients with various disease states (such as hepatic disease or rheumatoid arthritis) may not be required. Significant drug interactions have been demonstrated for aspirin (acetylsalicylic acid), lithium, digoxin, methotrexate, cyclosporin, cholestyramine and colestipol.     

Clinical pharmacokinetics of ibuprofen. The first 30 years

Ibuprofen is a chiral nonsteroidal anti-inflammatory drug (NSAID) of the 2 arylpropionic acid (2-APA) class. A common structural feature of 2-APANSAIDs is a sp3-hybridised tetrahedral chiral carbon atom within the propionic acid side chain moiety with the S-(+)-enantiomer possessing most of the beneficial anti-inflammatory activity. Ibuprofen demonstrates marked stereoselectivity in its pharmacokinetics. Substantial unidirectional inversion of the R-(-) to the S-(+) enantiomer occurs and thus, data generated using nonstereospecific assays may not be extrapolated to explain the disposition of the individual enantiomers. The absorption of ibuprofen is rapid and complete when given orally. The area under the plasma concentration-time curve (AUC) of ibuprofen is dose-dependent. Ibuprofen binds extensively, in a concentration-dependent manner, to plasma albumin. At doses greater than 600mg there is an increase in the unbound fraction of the drug, leading to an increased clearance of ibuprofen and a reduced AUC of the total drug. Substantial concentrations of ibuprofen are attained in synovial fluid, which is a proposed site of action for nonsteroidal anti-inflammatory drugs. Ibuprofen is eliminated following biotransformation to glucuronide conjugate metabolites that are excreted in urine, with little of the drug being eliminated unchanged. The excretion of conjugates may be tied to renal function and the accumulation of conjugates occurs in end-stage renal disease. Hepatic disease and cystic fibrosis can alter the disposition kinetics of ibuprofen. Ibuprofen is not excreted in substantial concentrations into breast milk. Significant drug interactions have been demonstrated for aspirin (acetylsalicylic acid), cholestyramine and methotrexate. A relationship between ibuprofen plasma concentrations and analgesic and antipyretic effects has been elucidated.     

Clinical effects and pharmacokinetics of different dosage schedules of adriamycin

Adriamycin was administered to 60 adults and 21 children by 3 different dosage schedules: 22.5 mg/sq m (0.6 mg/kg) daily for 4 days, 15 mg/sq m (0.4 mg/kg) every 8 hr for a total of 6 doses, and 50 to 120 mg/sq m as a single dose every 3 to 4 weeks. Objective responses lasting more than 1 month occurred in 5 subjects with acute leukemias or lymphoma, 3 with transitional cell carcinomas, 2 with sarcomas, 2 with Ewing's sarcoma and 1 each with bronchogenic carcinoma, orchidoblastoma, and thymoma. Toxic reactions included nausea, vomiting, stomatitis, alopecia, and hematopoietic depression, but significant cardiac toxicity occurred in only 1 patient. Pharmacokinetic data, collected in 25 patients by fluorometric and chromatographic assay, suggested a biphasic plasma clearance of drug with initial and secondary half-lives of about 1.5 and 14 to 21 hr, respectively. When drug was given every 8 hr there was evidence of loss of an initial very rapid phase of distribution of adriamycin and its metabolites. Urinary excretion accounted for 3.4 to 38.1% of administered fluorescence over a 72-hr period; in the first 24 hr, between 48.2 and 100% of this urinary material was in the form of adriamycin; leter, this fraction declined. No adriamycin or its fluorescent metabolites could be extracted from the stools.