Evidence of NI-0101 pharmacological activity, an anti-TLR4 antibody, in a randomized phase I dose escalation study in healthy volunteers receiving LPS.

Toll-like receptor-4 (TLR4) pathways are major contributors to pathological inflammatory responses induced by tissue damage. NI-0101 is the first monoclonal antibody (mAb) blocking TLR4 signaling. This activity is independent of the ligand type and concentration, therefore, potentially blocking any TLR4 ligands. A phase I single ascending dose study was conducted in 73 healthy volunteers to evaluate NI-0101 tolerability, preliminary safety, pharmacokinetics (PKs), and pharmacodynamics (PDs), in absence and in presence of a systemic challenge with lipopolysaccharide (LPS), a TLR4 ligand. NI-0101 was well tolerated without safety concern. The PK profile was characterized by a half-life of ∼10 days at high concentrations and by a rapid elimination at low concentrations due to expected target-mediated drug disposition. NI-0101 prevented cytokine release following ex vivo and in vivo LPS administration and prevented the C-reactive protein (CRP) increase and the occurrence of flu-like symptoms expected following the in vivo administration of LPS.

Modeling Alzheimer's Disease Progression Using Disease Onset Time and Disease Trajectory Concepts Applied to CDR-SOB Scores From ADNI.

Disease-onset time (DOT) and disease trajectory concepts were applied to derive an Alzheimer's disease (AD) progression population model using the clinical dementia rating scale-sum of boxes (CDR-SOB) from the AD neuroimaging initiative (ADNI) database. The model enabled the estimation of a DOT and a disease trajectory for each patient. The model also allowed distinguishing fast and slow-progressing subpopulations according to the functional assessment questionnaire, normalized hippocampal volume, and CDR-SOB score at study entry. On the basis of these prognostic factors, 81% of the mild cognitive impairment (MCI) subjects could correctly be assigned to slow or fast progressers, and 77% of MCI to AD conversions could be predicted whereas the model described correctly 84% of the conversions. Finally, synchronization of the biomarker-time profiles on estimated individual DOT virtually expanded the population observation period from 3 to 8 years. DOT-disease trajectory model is a powerful approach that could be applied to many progressive diseases.CPT: Pharmacometrics & Systems Pharmacology (2013) 2, e78; doi:10.1038/psp.2013.54; advance online publication 2 October 2013.

Assessment of Maraviroc Exposure-Response Relationship at 48 Weeks in Treatment-Experienced HIV-1-Infected Patients in the MOTIVATE Studies.

Efficacy exposure-response relationships of the CCR5 antagonist maraviroc were evaluated across two phase III clinical trials. This post-hoc analysis used 48-week efficacy data from 841 treatment-experienced patients infected with CCR5-tropic human immunodeficiency virus type 1 (HIV-1), identified by the enhanced sensitivity Trofile assay. Probability of treatment success (viral RNA <50 copies/ml) was modeled using generalized additive logistic regression, testing exposure, clinical, and virologic variables. Prognostic factors for treatment success (in decreasing order of Akaike information criterion (AIC) change) were: maraviroc treatment, high-weighted overall susceptibility to background treatment, absence of an undetectable maraviroc concentration, high baseline CD4 count (BCD4), low viral load (VL), race (other than black), absence of non-R5 baseline tropism (BTRP), and absence of fosamprenavir (FPV). No concentration-response relationship was found with treatment (maraviroc vs. placebo) and presence/absence of undetectable maraviroc concentration (adherence marker) in the model. The maraviroc doses studied (300 or 150 mg with potent CYP3A4 inhibitors once (q.d.)/twice daily (b.i.d.)) deliver concentrations near the top of the concentration-response curve.CPT: Pharmacometrics & Systems Pharmacology (2013) 2, e64; doi:10.1038/psp.2013.42; published online 14 August 2013.

A comprehensive hepatitis C viral kinetic model explaining cure.

We propose a model that characterizes and links the complexity and diversity of clinically observed hepatitis C viral kinetics to sustained virologic response (SVR)-the primary clinical end point of hepatitis C treatment, defined as an undetectable viral load at 24 weeks after completion of treatment)-in patients with chronic hepatitis C (CHC) who have received treatment with peginterferon alpha-2a +/- ribavirin. The new attributes of our hepatitis C viral kinetic model are (i) the implementation of a cure/viral eradication boundary, (ii) employment of all hepatitis C virus (HCV) RNA measurements, including those below the lower limit of quantification (LLOQ), and (iii) implementation of a population modeling approach. The model demonstrated excellent positive (99.3%) and negative (97.1%) predictive values for SVR as well as high sensitivity (96.6%) and specificity (99.4%). The proposed viral kinetic model provides a framework for mechanistic exploration of treatment outcome and permits evaluation of alternative CHC treatment options with the ultimate aim of developing and testing hypotheses for personalizing treatments in this disease.

Modelling response time profiles in the absence of drug concentrations: definition and performance evaluation of the K-PD model.

The plasma concentration-time profile of a drug is essential to explain the relationship between the administered dose and the kinetics of drug action. However, in some cases such as in pre-clinical pharmacology or phase-III clinical studies where it is not always possible to collect all the required PK information, this relationship can be difficult to establish. In these circumstances several authors have proposed simple models that can analyse and simulate the kinetics of the drug action in the absence of PK data. The present work further develops and evaluates the performance of such an approach. A virtual compartment representing the biophase in which the concentration is in equilibrium with the observed effect is used to extract the (pharmaco)kinetic component from the pharmacodynamic data alone. Parameters of this model are the elimination rate constant from the virtual compartment (KDE), which describes the equilibrium between the rate of dose administration and the observed effect, and the second parameter, named EDK(50) which is the apparent in vivo potency of the drug at steady state, analogous to the product of EC(50), the pharmacodynamic potency, and clearance, the PK "potency" at steady state. Using population simulation and subsequent (blinded) analysis to evaluate this approach, it is demonstrated that the proposed model usually performs well and can be used for predictive simulations in drug development. However, there are several important limitations to this approach. For example, the investigated doses should extend from those producing responses well below the EC(50) to those producing ones close to the maximum response, optimally reach steady state response and followed until the response returns to baseline. It is shown that large inter-individual variability on PK-PD parameters will produce biases as well as large imprecision on parameter estimates. It is also clear that extrapolations to dosage routes or schedules other than those used to estimate the parameters should be undertaken with great caution (e.g., in case of non-linearity or complex drug distribution). Consequently, it is advised to apply this approach only when the underlying structural PD and PK are well understood. In any case, K-PD model should definitively not be substituted for the gold standard PK-PD model when correct full model can and should be identified.

A combined specific target site binding and pharmacokinetic model to explore the non-linear disposition of draflazine.

The capacity-limited high-affinity target site binding of draflazine to the nucleoside transporters located on the erythrocytes is a source of nonlinearity in the pharmacokinetics of the drug. An attractive feature of draflazine is that the specific target site binding characteristics can be determined easily by simultaneously measuring plasma and whole blood concentrations of the drug. Measured drug concentrations following various infusion rates and infusion durations were used to develop a model in which the interrelated blood-plasma distribution, elimination, and specific target site binding of draflazine were incorporated simultaneously. The estimated binding (dissociation) constant Kd was 0.57 ng/ml plasma and the maximal specific erythrocyte binding capacity (BmaxRBC) was 163 ng/ml RBC. The maximal specific binding capacity to the tissues (Bmaxtissue) was estimated to be about 1 mg. The estimated volume of the central compartment (Vplasma + tissue fluids) was 12.9 L and the total intrinsic CL was 645 ml/min. After validation, the model was used to further investigate the impact of the specific high-affinity target site binding of draflazine on its disposition in plasma. The time required to reach steady-state plasma concentrations of draflazine decreased with an increasing infusion rate. Time profiles of the plasma concentrations were not always representative for the time profiles of the specific target site (RBC) occupancy of draflazine, but the t1/2,z in plasma paralleled that of the drug at target sites. The apparent Vd and the t1/2,z decreased with increasing single doses whereas the total CL remained constant. The recovery of draflazine was also dose dependent and increased with increasing doses. Finally, the total CL and apparent Vd of the first dose were greater than those of the second dose of draflazine.

Physiological red blood cell kinetic model to explain the apparent discrepancy between adenosine breakdown inhibition and nucleoside transporter occupancy of draflazine.

A physiological red blood cell (RBC) kinetic model is proposed for the adenosine (ADO) transport into erythrocytes and its subsequent intracellular deamination into inactive inosine (INO) and further breakdown into hypoxanthine (HYPO). The model and its parameters were based on previous studies investigating the kinetics of the biochemical mechanism of uptake and metabolism of ADO in human erythrocytes. Application of the model for simulations of the breakdown of ADO in a RBC suspension revealed that the predicted adenosine breakdown inhibition (ABI) of draflazine corresponded well with the ABI measured ex vivo. The model definitely explained the apparent discrepancy between the ex vivo measured ABI and the nucleoside transporter occupancy of draflazine. Intracellular deamination of ADO rather than its transport by the nucleoside transporter is the rate-limiting step in the overall catabolism of ADO. Consequently, at least 90% occupancy of the transporter by draflazine is required to inhibit adenosine breakdown ex vivo substantially. Simulations on basis of the validated model were performed to evaluate the ABI for different experimental conditions and to mimic the clinical situation. The latter may be very helpful for the design of optimal dosing schemes of draflazine. It was demonstrated that the short half-life of released ADO was prolonged substantially in a dose-related manner after a continuous infusion of draflazine. Finally, the previously found different sigmoidal Emax relationships between the measured ABI and the concentrations of draflazine in plasma and whole blood could be explained by the ADO transport and breakdown RBC kinetic model and the capacity-limited specific RBC binding characteristics of draflazine.

Repeated-dose pharmacokinetics of an oral solution of itraconazole in infants and children.

The safety, tolerability, and pharmacokinetics of an oral solution of itraconazole and its active metabolite hydroxyitraconazole were investigated in an open multicenter study of 26 infants and children aged 6 months to 12 years with documented mucosal fungal infections or at risk for the development of invasive fungal disease. The most frequent underlying illness was acute lymphoblastic leukemia, except in the patients aged 6 months to 2 years, of whom six were liver transplant recipients. The patients were treated with itraconazole at a dosage of 5 mg/kg of body weight once daily for 2 weeks. Blood samples were taken after the first dose, during treatment, and up to 8 days after the last itraconazole dose. On day 1, the mean peak concentrations in plasma after the first and last doses (Cmax) and areas under the concentration-time curve from 0 to 24 h (AUC0-24) for itraconazole and hydroxyitraconazole were lower in the children aged 6 months to 2 years than in children aged 2 to 12 years but were comparable on day 14. The mean AUC0-24-based accumulation factors of itraconazole and hydroxyitraconazole from day 1 to 14 ranged from 3.3 to 8.6 and 2.3 to 11.4, respectively. After 14 days of treatment, Cmax, AUC0-24, and the half-life, respectively, were (mean +/- standard deviation) 571+/-416 ng/ml, 6,930+/-5,830 ng.h/ml, and 47+/-55 h in the children aged 6 months to 2 years; 534+/-431 ng/ml, 7,330+/-5,420 ng.h/ml, and 30.6+/-25.3 h in the children aged 2 to 5 years; and 631+/-358 ng/ml, 8,770+/-5,050 ng.h/ml, and 28.3+/-9.6 h in the children aged 5 to 12 years. There was a tendency to have more frequent low minimum concentrations of the drugs in plasma for both itraconazole and hydroxyitraconazole for the children aged 6 months to 2 years. The oral bioavailability of the solubilizer hydroxypropyl-beta-cyclodextrin was less than 1% in the majority of the patients. In conclusion, an itraconazole oral solution given at 5 mg/kg/day provides potentially therapeutic concentrations in plasma, which are, however, substantially lower than those attained in adult cancer patients, and is well tolerated and safe in infants and children.

Population analysis of the non linear red blood cell partitioning and the concentration-effect relationship of draflazine following various infusion rates.

AIMS: To investigate the impact of the specific red blood cell binding on the pharmacokinetics and pharmacodynamics of the nucleoside transport inhibitor draflazine after i.v. administration at various infusion rates. It was also aimed to relate the red blood cell (RBC) occupancy of draflazine to the ex vivo measured adenosine breakdown inhibition (ABI). METHODS: Draflazine was administered to healthy volunteers as a 15-min i.v. infusion of 0.25, 0.5, 1, 1.5 and 2.5 mg immediately followed by an infusion of the same dose over 1 h. Plasma and whole blood concentrations were measured up to 120 h post dose, and were related to the ex vivo measured ABI, serving as a pharmacodynamic endpoint. The capacity-limited specific binding of draflazine to the nucleoside transporter located on the erythrocytes was evaluated by a population approach. RESULTS: The estimate of the population parameter typical value (%CV) of the binding constant Kd and the maximal specific binding capacity (Bmax) was 0.385 (3.5) ng ml-1 plasma and 158 (2.1) ng ml-1 RBC, respectively. The non-specific binding was low. The specific binding to the erythrocytes was a source of non-linearity in the pharmacokinetics of draflazine. The total plasma clearance of draflazine slightly decreased with increasing doses, whereas the total clearance in whole blood increased with increasing doses. The sigmoidal Emax equation was used to relate the plasma and whole blood concentration of draflazine to the ex vivo determined ABI. In plasma, typical values (%CV) of Emax, IC50 and Hill factor were 81.4 (1.9)%, 3.76 (9.3) ng ml-1 and 1.06 (3.4), respectively. The relationship in whole blood was much steeper with population parameter typical values (%CV) of Emax, IC50 and Hill factor of 88.2 (2.0)%, 65.7 (2.8) ng ml-1 and 4.47 (5.5), respectively. The RBC occupancy of draflazine did not coincide with the ex vivo measured ABI. The observed relationship between RBC occupancy and ABI was not directly proportional but similar for all studied infusion schemes. CONCLUSIONS: The findings of this study show that the occupancy of the nucleoside transporter by draflazine should be at least 90% in order to inhibit substantially adenosine breakdown in vivo. On the basis of these findings it is suggested that a 15 min infusion of 1 mg draflazine followed by an infusion of 1 mg h-1 could be appropriate in patients undergoing a coronary artery bypass grafting.

Population analysis of the non-linear red blood cell partitioning of draflazine following various infusion durations.

OBJECTIVE: The pharmacokinetics and non-linear red blood cell partitioning of the nucleoside transport inhibitor draflazine were investigated in 19 healthy male and female subjects (age range 22-55 years) after a 15-min i.v. infusion of 1 mg, immediately followed by infusions of variable rates (0.25, 0.5 and 1 mg.h-1) and variable duration (2-24 h). METHODS: The parameters describing the capacity-limited specific binding of draflazine to the nucleoside transporters located on erythrocytes were determined by NONMEM analysis. The red blood cell nucleoside transporter occupancy of draflazine (RBC occupancy) was evaluated as a pharmacodynamic endpoint. RESULTS: The population typical value for the dissociation constant Kd (%CV) was 0.648 (12) ng.ml-1 plasma, expressing the very high affinity of draflazine for the erythrocytes. The typical value of the specific maximal binding capacity Bmax (%CV) was 155 (2) ng.ml-1 RBC. The interindividual variability (%CV) was moderate for Kd (38.9%) and low for Bmax (7.8%). As a consequence, the variability in RBC occupancy of draflazine was relatively low, allowing the justification of only one infusion scheme for all subjects. The specific binding of draflazine to the red blood cells was a source of non-linearity in draflazine pharmacokinetics. Steady-state plasma concentrations of draflazine virtually increased dose-proportionally and steady state was reached at about 18 h after the start of the continuous infusion. The t1/2 beta averaged 11.0-30.5 h and the mean CL from the plasma was 327 to 465 ml.min-1. The disposition of draflazine in whole blood was different from that in plasma. The mean t1/2 beta was 30.2 to 42.2 h and the blood CL averaged 17.4-35.6 ml.min-1. CONCLUSION: Although the pharmacokinetics of draflazine were non-linear, the data of the present study demonstrate that draflazine might be administered as a continuous infusion over a longer time period (e.g., 24 h). During a 15-min i.v. infusion of 1 mg, followed by an infusion of 1 mg.h-1, the RBC occupancy of draflazine was 96% or more. As the favored RBC occupancy should be almost complete, this dose regimen could be justified in patients.

The implications of non-linear red blood cell partitioning for the pharmacokinetics and pharmacodynamics of the nucleoside transport inhibitor draflazine.

1. Draflazine, a nucleoside transport inhibitor, was administered as a 15 min i.v. infusion of 2.5 mg to eight healthy male subjects. Plasma and whole blood concentrations were measured up to 32 h post-dose, and were related to adenosine breakdown inhibition (ABI) measured ex vivo, which served as a pharmacodynamic endpoint. 2. The red blood cell/plasma distribution of draflazine was non-linear and characterized as a capacity-limited specific binding to the nucleoside transporter on the red blood cells. The binding (dissociation) constant Kd was 0.87 ng ml-1 plasma and the maximal specific binding capacity (Bmax) was 164 ng ml-1 RBC, which corresponds to about 14,000 specific binding sites per erythrocyte. Non-specific binding amounted to less than 15% of the total binding. 3. The pharmacokinetics of draflazine in blood were determined in each subject and characterized by a two-compartment pharmacokinetic model. The pharmacokinetic parameters (mean +/- s.d.) were: clearance 22.0 +/- 8.0 ml mm-1, volume of distribution at steady-state 39.8 +/- 4.7 l and terminal half-life 24.0 +/- 9.4 h. Concentrations in plasma were much lower, and could only be determined accurately in pooled plasma samples with a red blood cell binding assay. The pharmacokinetic parameters in pooled plasma were: clearance 551 ml min-1, volume of distribution at steady-state 349 l and terminal half-life 10.7 h. 4. A non-linear relationship was observed between the plasma or blood concentration of draflazine and the ABI determined ex vivo. This relationship was characterized by the sigmoidal Emax pharmacodynamic model. Based on concentrations in pooled plasma, values of the pharmacodynamic parameters were Emax 100%, IC50 10.5 ng ml-1 and Hill factor 0.9. When using whole blood concentrations, the relationship was much steeper with values (mean +/- s.d.) Emax 92.4 +/- 5.6%, IC50 76.0 +/- 15.3 ng ml-1 and Hill factor 3.5 +/- 0.9. 5. Binding to the nucleoside transporter on red blood cells is an important determinant of the pharmacokinetics of draflazine and a high degree of occupancy of the transporter by draflazine is required to inhibit adenosine breakdown ex vivo. It is suggested that red blood cell nucleoside transporter occupancy may serve as a useful pharmacodynamic endpoint in dose ranging studies with draflazine.

Antifungal pulse therapy for onychomycosis. A pharmacokinetic and pharmacodynamic investigation of monthly cycles of 1-week pulse therapy with itraconazole.

BACKGROUND AND DESIGN: In the treatment of onychomycosis, oral therapies have generally been given as a continuous-dosing regimen. For example, the suggested dose of itraconazole for the treatment of onychomycosis has thus far been 200 mg/d for 3 months. Based on the advances in our understanding of the pharmacokinetics of itraconazole, we investigated the efficacy and nail kinetics of intermittent pulse-dosing therapy with oral itraconazole in patients who were suffering from onychomycosis. Fifty patients with confirmed onychomycosis of the toenails, predominantly Trichophyton rubrum, were recruited and randomly assigned to three (n = 25) or four (n = 25) pulses of 1-week itraconazole therapy (200 mg twice daily for each month). Clinical and mycological evaluation of the infected toenails, and determination of the drug levels in the distal nail ends of the fingernails and toenails, were performed at the end of each month up to month 6 and then every 2 months up to 1 year. RESULTS: In the three-pulse treatment group, the mean concentration of itraconazole in the distal ends of the toenails ranged from 67 (month 1) to 471 (month 6) ng/g, and in the distal ends of the fingernails, it ranged from 103 (month 1) to 424 (month 6) ng/g. At month 11, the drug was still present in the distal ends of the toenails at an average concentration of 186 ng/g. The highest individual concentrations of 1064 and 1166 ng/g were reached at month 6 for toenails and fingernails, respectively. At end-point follow-up, toenails in 84% of the patients were clinically cured with a negative potassium hydroxide preparation and culture in 72% and 80% of the patients, respectively. In the four-pulse treatment group, the mean concentration of itraconazole in the distal ends of the toenails ranged from 32 (month 1) to 623 (month 8) ng/g, and in the distal ends of the fingernails, it ranged from 42 (month 1) to 380 (month 6) ng/g. The highest individual concentrations of 1549 and 946 ng/g were reached at month 7 for toenails and at month 9 for fingernails, respectively. At month 12, the drug was still present in the distal ends of the toenails at an average concentration of 196 ng/g. At end-point follow-up, toenails in 76% of the patients were clinically cured with a negative potassium hydroxide preparation and culture in 72% and 80% of the patients, respectively. There were no significant intergroup differences between the three- and four-pulse treatment groups for the primary efficacy parameters. The drug was well tolerated with no significant side effects in either patient group. CONCLUSIONS: Following pulse therapy with itraconazole (400 mg/d given for 1 week each month for 3 to 4 months), the drug has been detected in the distal ends of nails after the first pulse, and it has reached therapeutic concentrations with further therapy. After stopping the last pulse, the drug remains in the nail plate at levels above 300 ng/g for several months. Clinical cure rates between 76% and 84% and negative mycological examination findings between 72% and 80%, respectively, were observed in toenail onychomycosis. The data suggest that pulse therapy with itraconazole is an effective and safe treatment option for onychomycosis.

Paradoxical response to itraconazole treatment in a patient with onychomycosis caused by Microsporum gypseum.

A Columbian patient presented with a rare type of onychomycosis caused by Microsporum gypseum. Oral treatment with itraconazole formulation (Funazol) available in Columbia failed to improve the nail alteration. The fungitoxic effect of itraconazole was assessed on the M. gypseum strain cultured from the nail of the patient by using the method of culture of fungi on cyanoacrylate skin surface strippings (CSSS). In addition, a comparative evaluation of the oral bioavailability of itraconazole was made in volunteers after intake of Funazol and Sporanox. In the ex vivo bioassay on CSSS, topical itraconazole proved to be highly active against M. gypseum. After oral intake, however, the itraconazole bioavailability of Funazol relative to Sporanox averaged only 3.5%. Antifungal pulse therapy with Sporanox, 400 mg daily for 1 week per month for 4 months, cured the patient. This study shows that itraconazole is hardly or not absorbed from the oral formulation Funazol. Both the oral bioavailability and consequently therapeutic efficacy of the genuine drug (Sporanox) are highly superior.

A study of lactate metabolism without tracer during passive and active postexercise recovery in humans.

Tracers have been used extensively to study lactate metabolism in humans during rest and exercise. Nevertheless, quantification of in vivo lactate kinetics as measured by lactate tracers remains controversial and new data are necessary to clarify the issue. The present study has developed a simple kinetic model which does not require labelled molecules and which yields proportional and quantitative information on lactate metabolism in humans during postexercise recovery performed at different levels of intensity. Five subjects took part in six experiments each of which began with the same strenuous exercise (StrEx; 1 min, 385 W, 110 rpm). The StrEx of each session was followed by a different intensity of recovery: passive recovery (PR) and active recoveries (AR) with power outputs of 60, 90, 120, 150 and 180 W, respectively. Blood lactate concentration was measured prior to and immediately after StrEX and regularly during the 1st h of recovery. Oxygen uptake (VO2) was measured every 30 s during the whole session. The results showed that the disappearance rate constant (ke) increases abruptly from PR [0.080 (SEM 0.004) min-1] to moderate AR [60 W: 0.189 (SEM 0.039) min-1] and decreases slowly during more intense AR [180 W: 0.125 (SEM 0.027) min-1]. The lactate apparent clearance (Cl.F-1) was calculated from the area under the lactate concentration-time curve. The Cl.F-1 increased 1.81 (SEM 0.17) fold from PR to moderate AR (60 W) and only 1.31 (SEM 0.14) from PR to the most intense AR (180 W). Using the model, the apparent lactate production (F"K0) was also calculated. The F"K0 increased regularly following a slightly curvilinear function of VO2 and was 2.61 (SEM 0.53) fold greater during the most intense AR (180 W) than during PR. Because of the lack of data concerning the size of apparent lactate distribution volume (Vd), the apparent turnover rate (Rbl) has been presented here related to Vd. The Rbl.Vd-1 increased also following a slightly curvilinear function of VO2. The Rbl.Vd-1 was 85.90 (SEM 14.42) mumol.min-1.l-1 during PR and reached 314.09 (SEM 153.95) mumol.min-1.l-1 during the most intense AR (180 W). In conclusion the model presented here does not require labelled molecules and firstly makes it possible to follow the proportional change of apparent lactate clearance and apparent lactate production during active postexercise recovery in comparison with passive recovery conditions and secondly to estimate the blood lactate turnover.

Characterization of Binding of an RGD Mimetic, [(3)H]-SC-52012, to Platelet GPIIb/IIIa.

In order to compare binding of small peptide mimetics on activated vs resting platelets and with fibrinogen (fgn) on activated platelets, the binding of [(3)H]-SC-52012, a low molecular weight (483) mimetic of the RGDF sequence present in fgn, was evaluated. This compound is a potent inhibitor of fgn binding to activated platelets, IC, 9.0 ± 0.6 nM (mean ± SEM), and inhibits ADP induced human platelet aggregation (IC, 44 ± 5 nM). The dissociation constant (Kd) of [(3)H]-SC-52012 was 21.6 ± 4.7 nM (n = 13) in ADP-induced human washed platelets while the Kd for resting platelets was 156 ± 8.3 nM (n = 3). The maximum number of binding sites on ADP-activated and resting platelets were 60846 ± 7158 and 59464 ± 5898 molecules/platelet, respectively. By comparison, results with [(125)I]-fgn binding to activated platelets gave values of 363 ± 73 nM and 58046 ± 6386 molecules/platelet (n = 8) for the Kd and receptor number, respectively. These data suggest that the small molecule binds regardless of activation state of the platelet with only a change in affinity. [(3)H]-SC-52012 could be displaced by unlabelled SC-52012 with an IC(50) of 135 ± 20 nM.

Variations in lactate apparent clearance during rest and exercise in normal man.

The purpose of this study is to present a simple kinetic model for the study of the lactate metabolism. This model based on pharmacokinetic theory, does not require labelled molecules and yields a finer approach to lactate metabolism than does a simple observation of blood lactate concentration. The variations in parameter values have been studied in six male subjects after intensive exercise (385 W, 110 rpm and 1 min) (IE) followed by three different recovery periods: passive recovery (RE), moderate exercise (ME) and heavy exercise (HE). Blood lactate concentration was measured prior to IE and during the first hour of recovery. After mathematical treatment, the results show that the apparent clearance increases 2.83 +/- 0.76 fold from RE to ME and 1.96 +/- 0.61 fold from RE to HE. The steady state blood lactate concentration induced by the intensity of recovery (La(ss)) increases slightly (1.53 +/- 0.37 fold) from RE (1.40 +/- 0.36 mmol.l-1) to ME (2.04 +/- 0.32 mmol.l-1). Then La(ss) increases markedly (3.78 +/- 0.91 mmol.l-1) during HE (2.81 +/- 0.78 fold the La(ss) value at RE). The ratio between the apparent rates of lactate production (F"K0) during RE, ME and HE was calculated. F"K0 increases in a linear way versus intensity of exercise recovery. It was concluded that in the human: 1) the blood lactate concentration is not an accurate indicator of lactate production, 2) in our experiment, the apparent lactate production is a linear function of exercise intensity and 3) the abruptly increasing blood lactate concentration at a high level of exercise intensity is due to a decrease in apparent clearance.

Irreversible binding to proteins after single and repeated daily oral administration of 4-(2,2-diphenylethyl) imidazole (SC-46264) to the Cynomolgus monkey.

SC-46264 is an antagonist of the alpha 2-adrenergic receptor. Distribution and excretion of [14C]-SC-46264 were studied after single and repeated daily oral administrations to the Cynomolgus monkey at a 1.5 mg/kg dose. After a single oral administration, more than 95% of the administered dose was recovered within 48 h in the urine (+/- 60%) and faeces (+/- 40%). Approximately 1.7% remained in the gastro-intestinal (GI) tract and 2% in the animal body. However, the radioactivity remaining in the animal body decreased very slowly from 2 to 1% between 48 and 144 h. An accumulation of very small amounts of radioactivity could be suspected in the plasma, the liver, the thyroid, the adrenals and the kidneys. In a 2 week daily oral administration of [14C]-SC-46264, the amount of total radioactivity remaining in the animal body 24, 48 and 216 h after the last administration was approximately 21, 11 and 5% of the daily administered dose, respectively. It confirmed the accumulation of [14C]-SC-46264 related compound in the plasma, the liver, the thyroid, the adrenals and the kidneys. The minimum plasma concentrations of total radioactivity observed before each administration increased during the treatment and apparently did not yet reach an equilibrium after 14 days. In these plasma samples obtained throughout the study, an increasing fraction of the total radioactivity could not be extracted and was recovered with precipitable material. These observations lead to the hypothesis of an irreversible binding of some material to the proteins.(ABSTRACT TRUNCATED AT 250 WORDS)

The maximum lactate clearance: a new concept to approach the endurance level of an athlete.

The purpose of this study is to present a mathematical model based on physiological observations which describes the evolution of the blood lactate concentration ([LA-]) versus the oxygen uptake (VO2) during a continuous graded exercise test. This model is based on several assumptions: 1) [LA-] reflects the balance between the rates of appearance and disappearance of the lactate in the blood compartment; 2) VO2 measured at the end of each step, is a linear function of the power output and thus of the time; 3) the appearance rate of lactate into the blood is an exponential function of VO2; 4) the rate of disappearance is a saturable process which can be modelized by Michaelis-Menten kinetics; 5) the volume of distribution of lactate in the blood compartment is a constant during exercise. The parameters used in this model correspond to the integration of several biochemical and physiological phenomenons. The originality of this approach is to express the rate of lactate appearance and disappearance versus VO2 rather than time. Whatever the general pattern of the data, the fitted curve gives always very good results. Especially, the theoretical curve fits the decrease in [LA-] usually observed during the first steps of such an exercise. From the computed parameters the evolution of lactate clearance during a continuous graded exercise test may be modelized. A strong relationship exists between the level of endurance training and the maximum lactate clearance (Clmax) reached during the exercise test. The VO2 for Clmax is an indicator of the shift of the relationship [LA-]-VO2. Then, we propose to use the maximum lactate clearance which is individually determined, to characterize the endurance level of an athlete.

Safety, pharmacokinetics and efficacy of once-a-day netilmicin and amikacin versus their conventional schedules in patients suffering from pelvic inflammatory disease.

The safety, pharmacokinetics and efficacy of one daily injection (qd) of amikacin (AK) and netilmicin (NT) was compared with the recommended schedules (cs), i.e. twice-daily or thrice-daily, respectively. Women (17-43 years, n = 78) suffering from pelvic inflammatory disease were randomly assigned to qd or cs of either AK (14 mg/kg per day) or NT (6.6 mg/kg per day). Biometric parameters were similar in the 4 groups and all patients received ampicillin (4 g/day) and tinidazole (0.8 g/day). The Repeated Measures Analysis of Variance was used to distinguish the effects of the schedules and of the drugs choice on critical parameters. Efficacy was similar in the 4 groups and not influenced by the schedule of administration. No significant differences in nephro- and oto-toxicity were observed as assessed by serum creatinine and losses of hearing at low frequencies, but early phospholipiduria and auditory losses at high frequencies were significantly reduced with the qd administration compared to cs and by AK compared to NT. These data suggest that the qd schedule of AK and of NT is as efficacious as their cs schedules, and causes less renal and auditory alterations.