Bleeding Complications in a Patient After the Unexpected Interaction between Valproic Acid and Phenprocoumon

BACKGROUND

Phenprocoumon is a vitamin K antagonist that is widely prescribed in Europe and Latin America for the prophylaxis and treatment of thromboembolic events.

CASE PRESENTATION

A 90-year-old female was admitted to our hospital with tonic-clonic seizures, possibly due to dementia syndrome. Valproic acid (VPA) was prescribed for the treatment of seizures. VPA is an inhibitor of cytochrome P450 (CYP) 2C9 enzymes. A pharmacokinetic interaction with phenprocoumon occurred, which is a substrate for CYP2C9 enzymes. The interaction resulted in a strong INR increase and subsequent clinically relevant bleeding in our patient. Valproic acid is not specifically mentioned in the phenprocoumon drug label as a CYP2C9 inhibitor, and in the Dutch medication surveillance database, no medication alert is shown when prescribing this combination, and no interaction with phenprocoumon has been reported so far.

CONCLUSION

When prescribing this combination, the prescriber should be warned and advised to intensify INR monitoring if the combination is to be continued.

The pediatric acenocoumarol dosing algorithm: the Children Anticoagulation and Pharmacogenetics Study

Essentials A pediatric pharmacogenetic dosing algorithm for acenocoumarol has not yet been developed. We conducted a multicenter retrospective follow-up study in children in the Netherlands. Body surface area and indication explained 45.0% of the variability in dose requirement. Adding the genotypes of VKORC1, CYP2C9 and CYP2C18 to the algorithm increased this to 61.8%.

SUMMARY

Background The large variability in dose requirement of vitamin K antagonists is well known. For warfarin, pediatric dosing algorithms have been developed to predict the correct dose for a patient; however, this is not the case for acenocoumarol. Objectives To develop dosing algorithms for pediatric patients receiving acenocoumarol with and without genetic information. Methods The Children Anticoagulation and Pharmacogenetics Study was designed as a multicenter retrospective follow-up study in Dutch anticoagulation clinics and children's hospitals. Pediatric patients who used acenocoumarol between 1995 and 2014 were selected for inclusion. Clinical information and saliva samples for genotyping of the genes encoding cytochrome P450 (CYP) 2C9, vitamin K epoxide reductase complex subunit 1 (VKORC1), CYP4F2, CYP2C18 and CYP3A4 were collected. Linear regression was used to analyze their association with the log mean stable dose. A stable period was defined as three or more consecutive International Normalized Ratio measurements within the therapeutic range over a period of ≥ 3 weeks. Results In total, 175 patients were included in the study, of whom 86 had a stable period and no missing clinical information (clinical cohort; median age 8.9 years, and 49% female). For 80 of these 86 patients, genetic information was also available (genetic cohort). The clinical algorithm, containing body surface area and indication, explained 45.0% of the variability in dose requirement of acenocoumarol. After addition of the VKORC1, CYP2C9, and CYP2C18 genotypes to the algorithm, this increased to 61.8%. Conclusions These findings show that clinical factors had the largest impact on the required dose of acenocoumarol in pediatric patients. Nevertheless, genetic factors, and especially VKORC1, also explained a significant part of the variability.

Time to therapeutic range (TtTR), anticoagulation control, and cardiovascular events in vitamin K antagonists-naive patients with atrial fibrillation

BACKGROUND

Vitamin K antagonists (VKAs) reduce cardiovascular events (CVEs) in atrial fibrillation (AF) when a time in therapeutic range (TiTR) >70% is achieved. Factors affecting the time to achieve the TR (TtTR) are unknown.

METHODS

Prospective observational study including 1,406 nonvalvular AF patients starting VKAs followed for a mean of 31.3months (3,690 patient/year); TiTR, TtTR, and SAMe-TT₂R₂ score were calculated, and CVEs were recorded.

RESULTS

Median TtTR was 8.0days (interquartile range 5.0-18.0). Patients with high TtTR (ie, >75th percentile) were more likely to be in AF than in sinus rhythm at entry (odds ratio [OR]: 1.423, P=.011). Median TiTR was 60.0%; low TiTR (below median) was associated with SAMe-TT₂R₂ score (OR: 1.175, P=.001), high TtTR (>75th percentile, OR: 1.357, P=.017), and number of international normalized ratio checks (OR: 0.998, P=.049). We recorded 113 CVEs (3.1%/y), with a higher rate seen in patients with TtTR >75th percentile compared to those below (log-rank test, P=.006). A multivariable Cox regression analysis showed that SAMe-TT₂R₂ score (hazard ratio [HR]: 1.331, P<.001), TtTR >75th percentile (HR: 1.505, P=.047), TiTR <70% (HR: 1.931, P=.004), number of international normalized ratio checks (HR: 0.988, P<.001), digoxin (HR: 1.855, P=.008), and proton-pump inhibitors (HR: 0.452, P<.001) were independently associated with CVEs.

CONCLUSIONS

High TtTR is associated with poorer long-term quality of VKAs therapy. Patients with TtTR >18days or with high SAMe-TT₂R₂ score should be considered for treatment with non-vitamin K oral anticoagulants.

CYP2C9 and VKORC1 in therapeutic dosing and safety of acenocoumarol treatment: implication for clinical practice in Hungary

The purpose of this work was to investigate the contribution of CYP2C9 and VKORC1 to acenocoumarol (AC) dose variability, bleeding events in Hungary. The study recruited 117 patients on long-term AC therapy (INR 2-3), and 510 healthy individuals to model the findings. Patients were genotyped for alleles proved to affect lower AC overdose CYP2C9*2, CYP2C9*3, VKORC1*2. Additionally, we tested VKORC1*3, VKORC1*4 to examine their effect in patients with higher AC requirements. Most impact on dose reduction is accountable for CYP2C9*2/*3 (59%) and for VKORC1*2/*2 (45.5%), and on dose increase for newly evaluated VKORC1*3/*4 (22.5%) diplotypes. VKORC1*3 and *4 alleles seem to balance the dose-reducing effect of VKORC1*2 allele. Being a carrier of combination of VKORC1*2 and CYP2C9*2,*3 polymorphisms, rather than of one of these SNPs, is associated with higher risk of over-anticoagulation (up to 34.3%) in long-term AC treatment. The pharmacogenetic dosing algorithm involving VKORC1, CYP2C9 diplotypes and age explains 30.4% of AC dosing variability (p<6.10×10^-9). Correlation between the studied diplotypes and bleeding events could not be revealed.

Acenocoumarol: A Review of Anticoagulant Efficacy and Safety

Anticoagulant treatment is required for the treatment and prevention of thromboembolic disorders. Vitamin K antagonists are commonly used oral anticoagulants worldwide. Acenocoumarol is mono-coumarin derivative with racemic mixture of R (+) and S (-) enantiomers. Efficacy and safety of acenocoumarol has been evaluated in atrial fibrillation, cardiac valve replacement, after myocardial infarction, treatment of deep vein thrombosis, after major surgeries and after critical illness requiring prolonged hospitalization. Acenocoumarol is effective and safe in all age groups. It offers an advantage over warfarin in terms of better stability of anti-coagulant effect. Due to its economic advantage acenocoumarol may be suitable oral anticoagulant for long term use in countries like India.

Identification and weighting of the most critical "real-life" drug-drug interactions with acenocoumarol in a tertiary care hospital

PURPOSE

The objective of this study was to identify the most clinically relevant drug-drug interactions (DDIs) at risk of affecting acenocoumarol safety in our tertiary care university hospital, a 2,000 bed institution.

METHODS

We identified DDIs occurring with acenocoumarol by combining two different sources of information: a 1-year retrospective analysis of acenocoumarol prescriptions and comedications from our Computerized Physician Order Entry (CPOE) system (n = 2,439 hospitalizations) and a retrospective study of clinical pharmacology consultations involving acenocoumarol over the past 14 years (1994-2007) (n = 407). We classified these DDIs using an original risk-analysis method. A criticality index was calculated for each associated drug by multiplying three scores based on mechanism of interaction, involvement in a supratherapeutic international normalized ratio (INR) (≥ 6) and involvement in a severe bleeding.

RESULTS

One hundred and twenty-six DDIs were identified and weighted. Twenty-eight drugs had a criticality index ≥ 20 and were therefore considered at high risk for interacting with acenocoumarol by increasing its effect: 75% of these drugs involved a pharmacokinetic mechanism and 14 % a pharmacodynamic mechanism. An unknown mechanism of interaction was involved in 11 % of drugs.

CONCLUSION

Twenty-eight specific drugs were identified as being at high risk for interacting with acenocoumarol in our hospital using an original risk-analysis method. Most analyzed drugs interact with acenocoumarol via a pharmacokinetic mechanism. Actions such as the implementation of alerts in our CPOE system should be specifically developed for these drugs.

Long-term anticoagulant effects of the CYP2C9 and VKORC1 genotypes in acenocoumarol users

BACKGROUND

The required acenocoumarol dose and the risk of underanticoagulation and overanticoagulation are associated with the CYP2C9 and VKORC1 genotypes. However, the duration of the effects of these genes on anticoagulation is not yet known.

OBJECTIVES

In the present study, the effects of these polymorphisms on the risk of underanticoagulation and overanticoagulation over time after the start of acenocoumarol were investigated.

PATIENTS/METHODS

In three cohorts, we analyzed the relationship between the CYP2C9 and VKORC1 genotypes and the incidence of subtherapeutic or supratherapeutic International Normalized Ratio (INR) values (< 2 and > 3.5) or severe overanticoagulation (INR > 6) for different time periods after treatment initiation.

RESULTS

Patients with polymorphisms in CYP2C9 and VKORC1 had a higher risk of overanticoagulation (up to 74%) and a lower risk of underanticoagulation (down to 45%) in the first month of treatment with acenocoumarol, but this effect diminished after 1-6 months.

CONCLUSIONS

Knowledge of the patient's genotype therefore might assist physicians to adjust doses in the first month(s) of therapy.

A novel, single algorithm approach to predict acenocoumarol dose based on CYP2C9 and VKORC1 allele variants

The identification of CYP2C9 and VKORC1 genes has strongly stimulated the research on pharmacogenetics of coumarins in the last decade. We assessed the combined influence of CYP2C9 *2 and *3, and VKORC1 c.-1639G>A, 497C>G, and 1173C>T variants, on acenocoumarol dosage using a novel algorithm approach, in 193 outpatients who had achieved stable anticoagulation. We constructed an "acenocoumarol-dose genotype score" (AGS, maximum score = 100) based on the number of alleles associated with higher acenocoumarol dosage carried by each subject for each polymorphism. The mean AGS was higher in the high-dose (> 28 mg/week) compared with the low-dose (< 7 mg/week) group (mean(SEM) of 84.1+/-3.4 vs. 62.2+/-4.8, P = 0.008). An AGS > 70 was associated with an increased odds ratio (OR) of requiring high acenocoumarol dosage (OR: 3.347; 95%CI: 1.112-10.075; P = 0.032). In summary, although more research is necessary in other patient cohorts, and this algorithm should be replicated in an independent sample, our data suggest that the AGS algorithm could be used to help discriminating patients requiring high acenocoumarol doses to achieve stable anti-coagulation.

Pharmacogenetic differences between warfarin, acenocoumarol and phenprocoumon

Coumarin oral anticoagulant drugs have proven to be effective for the prevention of thromboembolic events. World-wide, warfarin is the most prescribed drug. In Europe, acenocoumarol and phenprocoumon are also administered. Yet it has been proven that variant alleles of the VKORC1 and CYP2C9 genotypes influence the pharmacokinetics and pharmacodynamics of these drugs. The combination of these two variant genotypes is a major cause of the inter-individual differences in coumarin anticoagulant drug dosage. Individuals who test positive for both variant genotypes are at increased risk of major bleeding. The impact of the CYP2C9 and VKORC1 genotype is most significant during the initial period of coumarin anticoagulant therapy. The effect of VKORC1 allelic variants is relatively similar for all three VKAs. The CYP2C9 polymorphism is associated with delayed stabilisation for coumarin anticoagulants. The effects of CYP2C9 polymorphisms on the pharmacokinetics and anticoagulant response are least pronounced in the case of phenprocoumon. In the long term, patients using phenprocoumon have more often international normalised ratio (INR) values in the therapeutic range, requiring fewer monitoring visits. This leads us to conclude that in the absence of pharmacogenetic testing, phenprocoumon seems preferable for use in long-term therapeutic anticoagulation. Pharmacogenetic testing before initiating coumarin oral anticoagulants may add to the safety of all coumarin anticoagulants especially in the elderly receiving multiple drugs.

Effect of aliskiren, an oral direct renin inhibitor, on the pharmacokinetics and pharmacodynamics of a single dose of acenocoumarol in healthy volunteers

OBJECTIVE

Aliskiren is a direct renin inhibitor approved for the treatment of hypertension. This study investigated the effects of aliskiren on the pharmacokinetics and pharmacodynamics of a single dose of acenocoumarol in healthy volunteers.

METHODS

This two-sequence, two-period, randomized, double-blind crossover study recruited 18 healthy subjects (ages 18-45) to receive either aliskiren 300 mg or placebo once daily on days 1-10 of each treatment period and a single dose of acenocoumarol 10 mg on day 8. Treatment periods were separated by a 10-day washout. Blood samples were taken frequently for determination of steady-state plasma concentrations of aliskiren (LC-MS/MS) and of R(+)- and S(-)-acenocoumarol (HPLC-UV), prothrombin time (PT) and international normalized ratio (INR).

RESULTS

Co-administration with aliskiren had no effect on exposure to R(+)-acenocoumarol. Geometric mean ratios (GMR; aliskiren:placebo co-administration) for R(+)-acenocoumarol AUC(0-t) and C(max) were 1.08 and 1.04, respectively, with 90% CI within the range 0.80-1.25. Co-administration of aliskiren resulted in a 19% increase in S(-)-acenocoumarol AUC(0-t) (GMR 1.19; 90% CI 0.92, 1.54) and a 9% increase in C(max) (GMR 1.09; 90% CI 0.88, 1.34). The anticoagulant effect of acenocoumarol was not affected by co-administration of aliskiren. Geometric mean ratios were 1.01 for all pharmacodynamic parameters (AUC(PT), PT(max), AUC(INR) and INR(max)), with 90% CI within the range 0.97-1.05.

CONCLUSION

Aliskiren has no clinically relevant effect on the pharmacokinetics or pharmacodynamic effects of a single dose of acenocoumarol in healthy volunteers, hence no dosage adjustment of acenocoumarol is likely to be required during co-administration with aliskiren.

[Prolonged diminished effect of coumarin derivatives after use of rifampicin]

A 73-year-old woman with endocarditis was treated with flucloxacillin and rifampicin. She already used the anticoagulant acenocoumarol because of a recent heart valve replacement. After starting rifampicin therapy the sensitivity for the acenocoumarol was reduced. The international normalised ratio (INR) did not exceed 2.0, while values of 2.5-3.5 were required. Increase of the daily dose of acenocoumarol with a factor 6 compared to the dose which resulted in a therapeutic INR before hospitalisation, proved insufficient to obtain a therapeutic INR during long-term rifampicin therapy. 21 days after rifampicin discontinuation the INR finally responded to high coumarin dosages. The breakdown of coumarins in the liver is increased by rifampicin due to induction of several isoenzymes of the cytochrome P450-system. This case illustrates that sensitivity to coumarins can be decreased profoundly even after discontinuation of rifampicin therapy. INR should be monitored closely not only at the start and discontinuation of rifampicin therapy, but also during the weeks after discontinuation of rifampicin treatment.

A model-based algorithm for the monitoring of long-term anticoagulation therapy

It has been shown that computerized algorithms for the prescription of coumarin derivates can improve the quality of long-term anticoagulation treatment. These algorithms are usually based on an empiric relationship between dosage and International Normalized Ratio and do not quantify the delaying effect of the drug's pharmacokinetics or the effect of alternating doses that are used to approximate a certain average dosage. Our objective was to develop a mathematical model that takes into account these effects and to develop a new algorithm based on this model that can be used to further optimize the quality of long-term anticoagulation treatment. We simplified a general model structure that was proposed by Holford in 1986 so that the parameters can be estimated using data that are available during long-term anticoagulation treatment. The constant parameters in the model were estimated separately for phenprocoumon and acenocoumarol using data from 1279 treatment courses from three different anticoagulation clinics in the Netherlands. The only variable parameter in the model is the sensitivity of the patient, which is estimated during the course of each treatment. A total of 194 dosage and appointment intervals that were proposed by the new algorithm were scored as 'good', 'acceptable', or 'bad' by two dosing experts. One hundred and seventy-eight (91.8%) proposals were considered good by at least one expert and bad by none. In 39 cases the experts disagreed. We believe that this algorithm will allow further improvement of anticoagulation treatments.

Comparative Pharmacokinetics of Vitamin K Antagonists

Vitamin K antagonists belong to the group of most frequently used drugs worldwide. They are used for long-term anticoagulation therapy, and exhibit their anticoagulant effect by inhibition of vitamin K epoxide reductase. Each drug exists in two different enantiomeric forms and is administered orally as a racemate. The use of vitamin K antagonists is complicated by a narrow therapeutic index and an unpredictable dose-response relationship, giving rise to frequent bleeding complications or insufficient anticoagulation. These large dose response variations are markedly influenced by pharmacokinetic aspects that are determined by genetic, environmental and possibly other yet unknown factors. Previous knowledge in this regard principally referred to warfarin. Cytochrome P450 (CYP) 2C9 has clearly been established as the predominant catalyst responsible for the metabolism of its more potent S-enantiomer. More recently, CYP2C9 has also been reported to catalyse the hydroxylation of phenprocoumon and acenocoumarol. However, the relative importance of CYP2C9 for the clearance of each anticoagulant substantially differs. Overall, the CYP2C9 isoenzyme appears to be most important for the clearance of warfarin, followed by acenocoumarol and, lastly, phenprocoumon. The less important role of CYP2C9 for the clearance of phenprocoumon is due to the involvement of CYP3A4 as an additional catalyst of phenprocoumon hydroxylation and significant excretion of unchanged drug in bile and urine, while the elimination of warfarin and acenocoumarol is almost completely by metabolism. Consequently, the effects of CYP2C9 polymorphisms on the pharmacokinetics and anticoagulant response are also least pronounced in the case of phenprocoumon; this drug seems preferable for therapeutic anticoagulation in poor metabolisers of CYP2C9. In addition to these vitamin K antagonists, oral thrombin inhibitors are currently under clinical development for the prevention and treatment of thromboembolism. Of these, ximelagatran has recently gained marketing authorisation in Europe. These novel drugs all feature some major advantages over traditional anticoagulants, including a wide therapeutic interval, the lack of anticoagulant effect monitoring and a low drug-drug interaction potential. However, they are also characterised by some pitfalls. Amendments of traditional anticoagulant therapy, including self-monitoring of international normalised ratio values or prospective genotyping for individual dose-tailoring may contribute to the continuous use of warfarin, phenprocoumon and acenocoumarol in the future.

[Plasma and milk concentrations of acenocoumarin in breast-feeding women during post partum]

BACKGROUND

Patients are receiving anticoagulants during postpartum. Literature data still is controversy in milk excretion of acenocoumarin; there are conducts in favor and against. Because of the benefits of maternal milk it's necessary to probe if acenocoumarin is excreted by human milk.

OBJECTIVE

To determine the milk excretion of acenocoumarin in different periods of the postpartum and the milk excretion index in anticoagulant women.

MATERIAL AND METHODS

It's an observational, descriptive and prospective study. The milk and plasma concentrations of acenocoumarin were determined in breast-feeding mothers with anticoagulation during the postpartum. ANOVA was used to determine the differences in pharmacokinetic constants in the different days of study.

RESULTS

Two patients required light anticoagulation, nine moderate and five intense. The 37.5% of the new born were full term hypotrophy and the 18.75% were preterm. The highest plasma average concentration of acenocoumarin was found in day 45th postpartum (0.21 microg/mL). Acenocoumarin present in milk was found until day 30th; the average concentrations were low 0.011 microg/mL. The value of the maternal milk excretion index was 0.057 in day 45, what represents that approximately the 5% of acenocoumarin is eliminated by milk. The calculated dose of acenocoumarin that a new born could receive through maternal milk was lower than the recommended doses (1.79 microg/kg/day).

CONCLUSION

These results allowed us to recommend breastfeeding in patients who are been anticoagulated with acenocoumarin.

[A patient with lessened sensitivity to acenocoumarol during a period of enteral feeding]

A 69-year-old man was operated on for a subdural haematoma which had developed during the use of acenocoumarol. Directly after the operation the patient was started on enteral feeding. The acenocoumarol was restarted at a later stage. The dose of acenocoumarol needed for an appropriate level of blood-dilution was twice as high during the period of enteral feeding than it had been preoperatively. After the transition from enteral feeding to oral feeding it was possible to lower the dose of acenocoumarol. The need for a higher dose was probably due to enhanced binding of the proteins in the enteral feeding. The patient was admitted to a nursing home. The combination of acenocoumarol and enteral feeding occurs frequently in patients being rehabilitated. It is important to monitor the blood-dilution when starting and stopping enteral feeding.

Pharmacogenetics of acenocoumarol pharmacodynamics

OBJECTIVE

The aim of this study was to investigate the respective contribution of the different cytochrome P450 (CYP) 2C9 genetic polymorphisms to the interindividual variability of acenocoumarol pharmacodynamic response.

METHODS

A total of 263 healthy volunteers were genotyped for CYP2C9*2, CYP2C9*3, CYP2C9*4, and CYP2C9*5 alleles, as well as for the nicotinamide adenine dinucleotide phosphate, reduced, quinone oxidoreductase 1 genetic polymorphism (NQO1*2). Moreover, the 5'-flanking region of the CYP2C9 gene was investigated for new polymorphisms, and haplotype analysis was then performed. Finally, CYP2C9 phenotype was evaluated after a single oral dose of 4 mg of acenocoumarol. Factor VII coagulant activity was measured before and 24 hours after acenocoumarol intake.

RESULTS

The CYP2C9*3 allele was the only nonsynonymous single nucleotide polymorphism (SNP) influencing acenocoumarol pharmacodynamics; the percentages of remaining factor VII were 60% +/- 19%, 39% +/- 17%, and 17% for CYP2C9*1/CYP2C9*1, CYP2C9*1/CYP2C9*3, and CYP2C9*3/CYP2C9*3 subjects, respectively (P =.001). Among the white subjects, the CYP2C9 promoter showed the existence of 6 SNPs at positions G-1538A, T-1189C, G-1097A, G-982A, T-640 del, and G-620T with allelic frequencies of 0.085, 0.0398, 0.136, 0.086, 0.005, and 0.0138, respectively. Four major haplotypes could be inferred among white subjects. The haplotype that contains the CYP2C9*3 allele was the only one influencing acenocoumarol pharmacodynamics, explaining 14.3% of its interindividual variability. Body weight explained 5% of acenocoumarol pharmacodynamic variability, whereas the NQO1*2 allele had no significant effect.

CONCLUSION

Overall, CYP2C9-related genetic variability accounts for 14% of the interindividual variability in acenocoumarol pharmacodynamic response. The information found by haplotype analysis is mainly related to the CYP2C9*3 SNP.

Pharmacokinetic Drug–Drug Interaction of the Novel Anticancer Agent E7070 and Acenocoumarol

E7070 is a novel sulfonamide anticancer agent that arrests cancer cells at the G1/S boundary of the cell cycle. Three patients receiving chronic therapy with the oral anticoagulant acenocoumarol experienced bleeding and/or a prolonged prothrombin time after treatment with E7070 at a dose of 700 mg/m2 given as a 1-h infusion. In vitro studies have shown that E7070 has the potential to inhibit several cytochrome P450 (CYP)-enzymes, including CYP2C9, CYP2C19, CYP2D6, CYP2E1, and CYP3A4. The major enzyme involved in the metabolism of acenocoumarol in man is CYP2C9. This study was performed to investigate the interaction between E7070 and acenocoumarol. Blood samples were obtained from two patients receiving daily oral maintenance treatment with acenocoumarol both prior to and following treatment with E7070. In addition, we incubated acenocoumarol enantiomers with pooled human microsomes with and without E7070 and measured the in vitro plasma protein binding of acenocoumarol after incubation with E7070. Pharmacokinetic parameters of acenocoumarol were calculated by noncompartmental analysis and revealed that in both patients the area under the concentration-time curve up to 24 h after the acenocoumarol administration was higher following E7070 (2.56 and 1.58 h*micromol/L) compared to the systemic exposure in the absence of E7070 (1.87 and 1.23 h*micromol/l). The formation of acenocoumarol metabolites was retarded by E7070 at already low concentrations (2.1 microM). The plasma protein binding of acenocoumarol was reduced at higher concentrations of E7070 (259 microM). These results indicate that E7070 may primarily interact with acenocoumarol by reducing its systemic clearance. Displacement of acenocoumarol's plasma protein binding by E7070 may also occur but to a minor extent. In the absence of careful monitoring this drug-drug interaction may result in hypoprothrombinemia and a hemorrhagic tendency.

The effect of nateglinide on the pharmacokinetics and pharmacodynamics of acenocoumarol

OBJECTIVE

The potential for a drug interaction was investigated between nateglinide, an oral antidiabetic agent, and acenocoumarol, an oral anticoagulant, as these drugs are primarily metabolized via CYP2C9.

METHODS

A two-period, randomized, double-blind, two-way crossover study design was employed to evaluate the effect of nateglinide on the pharmacokinetics and pharmacodynamics of acenocoumarol in 11 healthy male or female subjects. All subjects received either nateglinide 120 mg t.i.d. or placebo for 5 days in a crossover fashion and a single 10-mg dose of acenocoumarol on day 3. Plasma concentrations of R- and S-acenocoumarol and the anticoagulation parameters [prothrombin time (PT) and international normalized ratio of PT (PTINR)] were determined for 72 h following acenocoumarol administration. The pharmacokinetic and pharmacodynamic parameters of acenocoumarol were determined by noncompartmental analysis.

RESULTS

The mean (coefficient of variation (CV%)) area under the concentration-time curve (AUC(0-t)) of R-acenocoumarol in the presence and absence of nateglinide was 4217 (23%) and 3831 (24%) ng.h/ml, respectively. The corresponding values for S-acenocoumarol were 397 (20%) and 382 (23%), respectively. The mean (CV%) C(max) of R-acenocoumarol in the presence and absence of nateglinide was 304 (16%) and 316 (16%), respectively and the corresponding values for S-acenocoumarol were 142 (36%) and 141 (34%), respectively. The 90% confidence intervals indicated that exposure parameters, AUC(0-t) and C(max), of both R- and S-acenocoumarol were within the acceptable limits of 0.8-1.25. The mean (CV%) of area under the concentration-time curve of PT (AUC(PT)) following acenocoumarol administration in the presence and absence of nateglinide was 1170 (10%) and 1136 (8%), respectively. The corresponding AUC(INR) values were 104 (13%) and 99 (10%), respectively. Nateglinide co-administration has no influence on the PT or PTINR of acenocoumarol (p > 0.05).

CONCLUSION

Co-administration of nateglinide does not influence either the pharmacokinetics or the anticoagulant activity of R- and S-acenocoumarol in healthy subjects. This suggests that no dosage adjustments will be required when nateglinide and acenocoumarol are coadministered in clinical practice.

Acenocoumarol pharmacokinetics in relation to cytochrome P450 2C9 genotype

BACKGROUND AND OBJECTIVES

Cytochrome P450 (CYP) 2C9 is one of the major CYP enzymes involved in the biotransformation of drugs, among others, the oral anticoagulant acenocoumarol. The enzyme has several polymorphisms, with the CYP2C9*2 and CYP2C9*3 variants most commonly present in white patients. Patients with the CYP2C9*3 variant are known to require a lower maintenance dose of racemic acenocoumarol. We investigated the impact of the polymorphisms CYP2C9*2 and CYP2C9*3 on the pharmacokinetics of R- and S-acenocoumarol.

METHODS AND RESULTS

In the first study 26 healthy volunteers with the genotype *1/*1 (n = 9), *1/*2 (n = 7), *1/*3 (n = 6), *2/*3 (n = 3), and *2/*2 (n = 1) were given 8 mg of racemic acenocoumarol as a single oral dose. Plasma R- and S-acenocoumarol concentrations were assayed at 4, 7, and 24 hours. Mean plasma S-acenocoumarol concentrations at 7 hours were higher in subjects with a variant allele; the differences were significant (P =.01) for the *1/*3 and *2/*3 genotypes. In the second study, the oral pharmacokinetics of acenocoumarol was investigated in 6 subjects (*1/*1 [n = 3] and *1/*3 [n = 3]). The mean oral clearance of S-acenocoumarol was 45% lower in the CYP2C9*1/*3 genotypes (10.9 +/- 3.0 L/h versus 19.8 +/- 3.1 L/h, P =.02). Plasma half-life was prolonged from 1.0 +/- 0.2 hours to 2.0 +/- 0.7 hours (P =.09). R-acenocoumarol pharmacokinetics did not differ between the genotypes. There was no difference in mean international normalized ratio at 24 hours, which was 1.2 in both groups. In vitro enzyme kinetics showed reduced (85%) intrinsic activity of the *3 enzyme to catalyze the hydroxylations of S-acenocoumarol. The lower activity resulted from higher Michaelis-Menten constant (2-fold) and lower maximum rate of metabolism by an enzyme-mediated reaction (by 70%). The activity of the *2 enzyme was 50% of the wild-type one.

CONCLUSION

The results show S-acenocoumarol pharmacokinetics to be dependent on CYP2C9 polymorphism. In particular, the presence of the CYP2C9*3 allele impairs oral clearance of the coumarin.

Pharmacokinetic study of the digoxin-acenocoumarol interaction in rabbits

A study was carried out to evaluate the potential pharmacokinetic interaction between digoxin and acenocoumarol. The binding of digoxin to rabbit cardiac tissue homogenates was assessed in vitro, using the equilibrium dialysis technique. An increase in the first-order constant (p<0.05) and a reduction in the partition coefficient in the equilibrium situation (p<0.001) of digoxin were observed when the cardiac homogenates were previously treated with acenocoumarol. In the in vivo study, the kinetics of digoxin administered in single and multiple dosage regimens were compared in control rabbits and in rabbits treated simultaneously with acenocoumarol. Kinetic analysis of the results was performed using Non-linear Mixed Effects Modeling (NONMEM). In the presence of acenocoumarol, the population distribution volume (Vd) of digoxin was increased by 40-60%, no differences being found as regards the elimination clearance. Also, joint administration of both drugs led to a reduction in digoxin concentrations in the heart (p<0.01) at the end of the dosage regimen. Both sets of results point to the hypothesis of a hitherto unreported possible pharmacokinetic interaction between the two drugs affecting the distribution process. This interaction could lead to lower plasma digoxin levels, in view of the increased Vd, and a possible reduction in the therapeutic effect, owing to the decrease in affinity and in concentration in heart tissue.

Compliance and stability of INR of two oral anticoagulants with different half-lives: a randomised trial

The aim of the study was to assess the respective roles of the half-life of elimination of oral anticoagulants and patient education as causes of instability of anticoagulation level in patients on oral anticoagulant therapy. Patients were randomised to receive either warfarin (long half-life) or acenocoumarol (short half-life) and either intensive or standard education, according to a factorial design. Instability of oral anticoagulant therapy was evaluated by the percentage of INRs and the time within the target range, and the variability between successive measurements. Compliance was assessed by means of electronic pill bottles. Eighty-six patients were included. Apart from the variability index, instability was similar between groups. Correlations between compliance and instability were observed only in the acenocoumarol group. No difference was found between the education groups. In patients starting oral anticoagulant therapy, dose determination may be the most important factor contributing to instability.

A placebo-controlled pharmacodynamic and pharmacokinetic interaction study between tamsulosin and acenocoumarol

AIM

To evaluate pharmacokinetic and pharmacodynamic interactions between tamsulosin and acenocoumarol.

METHODS

Twelve healthy volunteers received tamsulosin 0.4 mg or placebo once daily for 9 days in a double-blind, cross-over study. On day 5 of each study period, a single 10-mg oral dose of racemic acenocoumarol was administered.

RESULTS

The ratios (point estimates (90% confidence intervals)) of values in the presence and absence of tamsulosin were: AUCPT 1.01 (0.98, 1.03); maximum prothrombin time (Ptmax) 0.99 (0.94, 1.05); AUC (R)-acenocoumarol 1.02 (0.90, 1.16), and AUC (S)-acenocoumarol 1.03 (0.89, 1.20). Both combinations, tamsulosin and placebo with acenocoumarol, were well-tolerated.

CONCLUSIONS

Multiple doses of tamsulosin had no effect on the pharmacokinetics or pharmacodynamics of a single high dose of acenocoumarol.

[Oral anticoagulation with vitamin K antagonists]

Coumarins are broadly employed in clinical practice and should therefore belong to the group of 'well known' drugs. The present review will deal with some concepts of anticoagulant therapy: the role of vitamin K in the synthesis of functional coagulation factors, some clinically relevant pharmacokinetic aspects of coumarins, the management of oral anticoagulant therapy with special emphasis on the laboratory monitoring, and the most frequent complication, bleeding.

Pharmacogenetics of acenocoumarol: cytochrome P450 CYP2C9 polymorphisms influence dose requirements and stability of anticoagulation

BACKGROUND AND OBJECTIVES

Cytochrome P4502C9 (CYP2C9) is the main enzyme implicated in coumarinic metabolism. Variant alleles, CYP2C9*2 and CYP2C9*3, have been related to decreased enzymatic activity, but their clinical relevance in acenocoumarol metabolism has not been established. We investigated CYP2C9 polymorphisms in relation to acenocoumarol dose requirement, stability of anticoagulation and bleeding.

DESIGN AND METHODS

CYP2C9 genotyping was performed in 325 acenocoumarol-treated patients (INR target between 2.0 and 3.0) and in an additional group of 84 patients with repeated bleeding.

RESULTS

Patients with the wild-type CYP2C9*1/*1 genotype (n=169) required a higher maintenance dose of acenocoumarol (17.1 8.7 mg/week) than did patients with the CYP2C9*2 (14.6 6.4 mg/week, p<0.05, N=97) or the CYP2C9*3 allele (11.2 6.2 mg/week, p<0.001, n=59). Out of 170 patients requiring a low-dose of acenocoumarol (<or= 2 mg/day), 27.1% carried the CYP2C9*3 allele, while among the patients requiring higher doses, 8.4% had CYP2C9*3 (OR=4.77, 95% CI = 2.40-9.48, p<0.001 vs. 2C9*1/*1 patients). In the multivariate analysis, independent predictive variables for low-dose acenocoumarol requirements were age >70 years (OR=3.73, 95%CI=2.29-6.08, p<0.001), and the CYP2C9*3 allele (OR=4.75, 95%CI=2.36-9.55, p <0.001). Carriers of CYP2C9*3 spent less time within the therapeutic range (64.7 23.1%) than did patients with the CYP2C9*1/*1 genotype (75.1 22.0%, p<0.01), and more frequently had an INR >4.5 at the initiation of treatment (43.9% vs.11.6%, p<0.001), but did not show repeated bleeding more frequently (19.0% vs.15.5%, p=NS).

INTERPRETATION AND CONCLUSIONS

CYP2C9*3 is related to lower acenocoumarol dose requirements, a higher frequency of over-anticoagulation at the initiation of therapy and an unstable anticoagulant response.

Altered pharmacokinetics of R- and S-acenocoumarol in a subject heterozygous for CYP2C9*3

OBJECTIVE

Our objective was to study the pharmacokinetics of R - and S -acenocoumarol in a subject who was highly sensitive to the anticoagulant effect of acenocoumarol. The subject was found to be heterozygous for CYP2C9*3.

METHODS

The plasma pharmacokinetics of the acenocoumarol enantiomers was established after an oral dose of 8 mg of racemic acenocoumarol. Urine was collected to establish the formation clearance of the 6- and 7-hydroxy metabolites of R - and S -acenocoumarol.

RESULTS

The pharmacokinetics of S -acenocoumarol in this subject differed greatly (oral clearance, 6%-10%; half-life of elimination, 400%-500%) from the values of a [wt/wt] control and from population values. R -acenocoumarol clearance was at the lower level of population values. The apparent formation clearances of the metabolites were low-approximately 10% of control activity for the hydroxylations (6- and 7-) of S -acenocoumarol and for the 7-hydroxylation of R -acenocoumarol. The rate of the 6-hydroxylation of R -acenocoumarol was about 50% of control values.

CONCLUSION

The presence of even one copy of CYP2C9*3 reduces profoundly the metabolic clearance of S -acenocoumarol. As a result the first-pass effect of elimination is abolished and the maintenance time is increased. S -Acenocoumarol, which is normally clinically inactive, will now exert main anticoagulant activity.

Cytochrome P4502C9 is the principal catalyst of racemic acenocoumarol hydroxylation reactions in human liver microsomes

The oral anticoagulant acenocoumarol is given as a racemic mixture. The (S)-enantiomer is rapidly cleared and is the reason why only (R)-acenocoumarol contributes to the pharmacological effect. The objective of the study was to establish the cytochrome P450 (CYP) enzymes catalyzing the hydroxylations of the acenocoumarol enantiomers. Of various cDNA-expressed human CYPs, only CYP2C9 hydroxylated (S)-acenocoumarol. Hydroxylation occurred at the 6-, 7-, and 8-position with equal K(m) values and a ratio of 0.9:1:0.1 for V(max). CYP2C9 also mediated the 6-, 7-, and 8-hydroxylations of (R)-acenocoumarol with K(m) values three to four times and V(max) values one-sixth times those of (S)-acenocoumarol. (R)-Acenocoumarol was also metabolized by CYP1A2 (6-hydroxylation) and CYP2C19 (6-, 7-, and 8-hydroxylation). In human liver microsomes one enzyme only catalyzed (S)-acenocoumarol hydroxylations with K(m) values < 1 microM. In most of the samples tested the 7-hydroxylation of (R)-acenocoumarol was also catalyzed by one enzyme only. The 6-hydroxylation was catalyzed by at least two enzymes. Sulfaphenazole could completely inhibit in a competitive way the hydroxylations of (S)-acenocoumarol and the 7-hydroxylation of (R)-acenocoumarol. The 6-hydroxylation of (R)-acenocoumarol could be partially inhibited by sulfaphenazole, 40 to 50%, and by furafylline, 20 to 30%. Significant mutual correlations were obtained between the hydroxylations of (S)-acenocoumarol, the 7-hydroxylation of (R)-acenocoumarol, the 7-hydroxylation of (S)-warfarin, and the methylhydroxylation of tolbutamide. The results demonstrate that (S)-acenocoumarol is hydroxylated by a single enzyme, namely CYP2C9. CYP2C9 is also the main enzyme in the 7-hydroxylation of (R)-acenocoumarol. Other enzymes involved in (R)-acenocoumarol hydroxylation reactions are CYP1A2 and CYP2C19. Drug interactions must be expected, particularly for drugs interfering with CYP2C9. Also, drugs interfering with CYP1A2 and CYP2C19 may potentiate acenocoumarol anticoagulant therapy.

Prediction of pharmacokinetic drug/drug interactions from In vitro data: interactions of the nonsteroidal anti-inflammatory drug lornoxicam with oral anticoagulants

CYP2C9 is involved in the metabolism of the oral anticoagulants warfarin, phenprocoumon, and acenocoumarol. It is also responsible for the 5'-hydroxylation of the nonsteroidal anti-inflammatory drug lornoxicam. Therefore, lornoxicam and the oral anticoagulants are potential inhibitors of their metabolism. Their inhibitory potency was investigated in microsomes from six human livers. An approach to predict pharmacokinetic interactions of lornoxicam from in vitro inhibition data was developed. Where possible, the forecasts were verified by comparison with data from clinical interaction studies. The following increases in steady-state plasma concentrations or areas under the plasma concentration-time curve of the oral anticoagulants by concomitant lornoxicam medication were predicted (values in parentheses are for healthy volunteers): (S)-warfarin, 1. 58-fold (1.32-fold for racemate); racemic-acenocoumarol, 1.28-fold (1.09-fold); (R)-acenocoumarol, 1.10-fold (1.0-fold); racemic-phenprocoumon, 1.11-fold (1.18-fold); and (S)-phenprocoumon, 1.13-fold (1.24-fold). Lornoxicam 5'-hydroxylation was competitively inhibited in vitro by both phenprocoumon (K(i) = 1.2 +/- 0.4 microM) and acenocoumarol (K(i) = 5.5 +/- 3.5 microM). The present results indicate that relatively close predictions of the interactions of lornoxicam with oral anticoagulants from in vitro data are possible under the assumption that hepatic lornoxicam concentrations are similar to its total plasma concentrations. The degree of pharmacokinetic interactions exhibited by oral anticoagulants and lornoxicam is dependent on the respective contribution of CYP2C9 to their total clearance.

No clinically relevant effect of lornoxicam intake on acenocoumarol pharmacokinetics and pharmacodynamics

OBJECTIVE

To investigate the effect of lornoxicam co-administration on acenocoumarol pharmacokinetics and pharmacodynamics.

METHODS

In an open crossover study, six healthy male volunteers received racemic acenocoumarol (10 mg) orally without/with lornoxicam co-administration (8 mg twice daily).

RESULTS

The median (range) areas under the concentration-time curve (AUC) for (R)-acenocoumarol were 3458 (3035-7312) microg x h 1(-1) in the absence of and 3667 (2907-7741) microg x h 1(-1) in the presence of lornoxicam. The corresponding values for (S)-acenocoumarol were 479 (381-853) microg x h 1(-1) and 612 (425-1241) microg x h 1(-1). The differences were not statistically significant. Lornoxicam co-administration did not influence the free fractions or acenocoumarol's effect on factor II and VII activities. Simulations based on the results of a model-based analysis predicted that in the case of lornoxicam co-administration, the factor VII activity of a person in steady-state at 26% will remain between 14% and 32%.

CONCLUSION

Co-administration of lornoxicam at the upper limit of recommended doses does not alter the pharmocokinetics of the clinically relevant (R)-acenocoumarol or the anticoagulant activity of acenocoumarol. These data clearly differ from the results of previous studies, which showed clinically relevant influences of lornoxicam on warfarin kinetics and of piroxicam on acenocoumarol kinetics.

Pharmacokinetic and pharmacodynamic variations of acenocoumarol orally administrated either once or twice daily in patients with deep venous thrombosis

The literature suggests that variations in anticoagulant effect occur when acenocoumarol is administrated in a daily dose. We assessed the anticoagulant effects of acenocoumarol with INR, factors VII and X and protein C in 12 randomly selected hospitalised patients with deep-vein thrombosis, six of them receiving a daily dose of acenocoumarol, the other six receiving twice daily doses. When the drug effect had been at a steady-state for at least 72 h, five blood samples were drawn per patient over a period of 24 h. No nycthemeral significant variations were noted for INR, factor X and protein C in the two groups (P > 0.10). Nycthemeral significant variation in factor VII when acenocoumarol was administered once daily was noted (P = 0.02), but the clinical relevance of factor VII variation at steady-state is uncertain. In spite of the short pharmacokinetic half-life of acenocoumarol, a stable nycthemeral pharmacodynamic activity was observed after once daily administration; twice-daily administration of acenocoumarol does not appear to be justified.

Lack of effect of omeprazole in oral acenocoumarol anticoagulant therapy

BACKGROUND

Omeprazole is eliminated almost completely by hepatic metabolism within the cytochrome P-450 system and might inhibit the oxidative metabolism of other drugs. This is particularly relevant for compounds with a narrow therapeutic range, such as acenocoumarol. In this study we evaluated the effect of omeprazole use in patients receiving continuous acenocoumarol therapy.

METHODS

One thousand and fifty-seven patients receiving long-term oral acenocoumarol combined with omeprazole were selected retrospectively. In 118 of these patients omeprazole was considered the only factor of possible influence on anticoagulant therapy. The control group consisted of 299 age- and sex-matched patients taking acenocoumarol without interfering medication. Dose adjustment of acenocoumarol on starting omeprazole therapy was indicated by clinically relevant changes in coagulation time.

RESULTS

No adaptation of the anticoagulant dose was necessary in 74 of 118 omeprazole patients (62.7%), compared with 169 of 299 controls (56.5%). A higher dose was necessary in 30 of 118 omeprazole patients (25.4%), compared with 84 of 299 controls (28.0%). In 14 of 118 omeprazole patients (11.9%) a lowering of the anticoagulant dose was required, compared with 46 of 299 controls (15.4%).

CONCLUSIONS

We found no evidence of any interaction between omeprazole and acenocoumarol. It seems likely that omeprazole can be administered safely to patients treated with acenocoumarol.

No effect of short-term omeprazole intake on acenocoumarol pharmacokinetics and pharmacodynamics

AIMS

To investigate the effect of omeprazole on the pharmacokinetics of R- and S-acenocoumarol and on their combined anticoagulant activity.

METHODS

Eight healthy male subjects completed a double-blind, randomized, placebo-controlled, two-way cross-over study. Subjects were given either omeprazole 40 mg or placebo once daily for 3 days. On day 2 of each study period, a single 10 mg oral dose of racemic acenocoumarol was administered and venous blood samples were collected for pharmacokinetic and pharmacodynamic assessments. A wash-out period of 2 weeks separated the two study periods.

RESULTS

The pharmacokinetics of R- and S-acenocoumarol (AUC 3016 +/- 221 and 233 +/- 14 ng ml(-1) h, respectively) did not change after omeprazole (AUC 2929 +/- 256 and 220 +/- 18 ng ml(-1) h, respectively). Anticoagulant activity (INRmax 1.7 +/- 0.1) was unaffected by co-administration of omeprazole (INRmax 1.7 +/- 0.1).

CONCLUSIONS

The short-term intake of omeprazole does not affect acenocoumarol pharmacokinetics or pharmacodynamics. These data differ from the results of previous studies on the effect of omeprazole on warfarin, suggesting a different in vivo interaction profile of omeprazole on acenocoumarol than on warfarin. Drug interaction studies with oral anticoagulants should not be restricted to the use of warfarin.

Stereoselective interaction between piroxicam and acenocoumarol

1. An open-label study was performed to assess the effect of piroxicam on the pharmacokinetics of acenocoumarol enantiomers. 2. Eight healthy male volunteers received an oral dose of 4 mg rac-acenocoumarol on days 1 and 8, plus 40 mg piroxicam orally 2 h before the anticoagulant on day 8. R- and S-acenocoumarol, piroxicam and their metabolites were measured in plasma over a 24 h interval. 3. The pharmacokinetics of R-acenocoumarol were markedly modified by piroxicam: Cmax+28.0% (s.d.23.8), P < 0.05; AUC(0, 24 h)+47.2% (21.5), P < 0.005; and t1/2 +38.0% (34.5), P < 0.01. A concomitant decrease of CL/F was observed: -30.8% (10.0), P < 0.0001. A similar, but statistically non-significant trend, was observed on the S-enantiomer: Cmax: +9.5% (s.d.36.6), AUC(0, 24 h): + 15.4% (23.4), t1/2: +19.9% (42.0), and CL/F: -9.8% (20.5). V/F remained unchanged for both enantiomers. 4. Piroxicam plasma AUC(0, 24 h) correlated closely with R- and S-acenocoumarol AUCs on day 1 (r = 0.901, P < 0.005 and r = 0.797, P < 0.05, respectively), as well as with the difference of AUC between days 1 and 8 for R-acenocoumarol (r = 0.903, P < 0.001) and S-acenocoumarol (r = 0.711, P < 0.05). 5. Piroxicam markedly reduced acenocoumarol enantiomer clearance, with a greater effect on the more active R-isomer. This interaction, which occurs in addition to the well documented pharmacodynamic one (effect on platelets), is expected to result in increased anticoagulant effect.

The effects of Danshen (Salvia miltiorrhiza) on warfarin pharmacodynamics and pharmacokinetics of warfarin enantiomers in rats

The effects of Danshen (Salvia miltiorrhiza), a popular traditional Chinese medicinal herb on the pharmacokinetics and pharmacodynamics of R- and S-warfarin stereoisomers were studied in rats. After a single oral dose of racemic warfarin (2 mg kg-1), treatment with oral Danshen extract (5 g kg-1, twice daily) for 3 days significantly altered the overall pharmacokinetics of both R- and S-warfarin and increased the plasma concentrations of both enantiomers over a period of 24 h and the prothrombin time over 2 days. At steady-state levels of racemic warfarin (0.2 mg kg-1 day-1 for 5 days) the 3-day treatment of Danshen extract (5 g kg-1, twice daily) not only prolonged the prothrombin time but also increased the steady-state plasma concentrations of R- and S-warfarin. The results indicate that Danshen extracts can increase the absorption rate constant, area under plasma concentration-time curves, maximum concentrations and elimination half-lives, but decreases the clearances and apparent volume of distribution of both R- and S-warfarin. The pharmacokinetic and pharmacodynamic interactions of warfarin during co-treatment with Danshen extract observed in this study indicate an explanation for the clinically observed incidents of exaggerated warfarin adverse effects when traditional Chinese medicinal herbs or herbal products such as Danshen and Danggui (observed in a previous study) were co-administered.

Pharmacokinetic analysis of a new acenocoumarol tablet formulation during a bioequivalence study

The pharmacokinetics of a new tablet formulation of acenocoumarol racemate, an oral anticoagulant agent, has been investigated in 8 normal healthy subjects. The drug was given as a single oral dose of 12 mg. 12 blood samples were collected after administration Plasma acenocoumarol concentrations were determined by a sensitive HPLC method. Areas under the plasma level-time curves for each subject were evaluated by means of the trapezoidal rule. The peak plasma concentration of 244.19-644.23 micrograms/l was reached 1-4 h after drug administration. The terminal phase half-life was 6.29-14.22 h and a systemic clearance was 1.86-5.62 l/h. The new table formulation of acenocoumarol seems to be bioequivalent when compared to the one used so far. For the prediction of systemic availability and estimation of the first-pass metabolism, from plasma level data, a hepatic blood flow rate limited model were used. The systemic availability was 94.22-98.01% and the elimination of the drug on its first-pass through the liver was 1.99-5.78%.

Human liver microsomal metabolism of the enantiomers of warfarin and acenocoumarol: P450 isozyme diversity determines the differences in their pharmacokinetics

1. To explain the large differences in (the stereoselectivity of) the clearances of the enantiomers of warfarin and acenocoumarol (4'-nitrowarfarin) their human liver microsomal metabolism has been studied and enzyme kinetic parameters determined. The effects of cimetidine, propafenone, sulphaphenazole, and omeprazole on their metabolism has been investigated. 2. The 4-hydroxycoumarins follow similar metabolic routes and are mainly hydroxylated at the 6- and 7-position (accounting for 63 to 99% of the metabolic clearances). 3. Due to the lower Km values of R- and S-acenocoumarol and higher Vmax values of S-acenocoumarol, the overall metabolic clearances of R/S acenocoumarol exceed those of R/S warfarin 6 and 66 times respectively. 4. The metabolism of both compounds is stereoselective for the S-enantiomers, which is 10 times more pronounced in the case of acenocoumarol. 5. Except for the 7-hydroxylation of the R-enantiomers (r = 0.90; P < 0.025), the 6- and 7-hydroxylation rates of R/S warfarin do not correlate with those of R/S acenocoumarol. 6. Sulphaphenazole competitively inhibits the 7- and in some samples partly (up to 50%) the 6-hydroxylation of S-warfarin as well as the 7-hydroxylation of R- and S-acenocoumarol and the 6-hydroxylation of S-acenocoumarol (Kis ranging from 0.5-1.3 microM). 7. Omeprazole partly (40-80%) inhibits the 6- and 7-hydroxylation of R-warfarin (Ki = 99 and 117 microM) and of R- (Ki = 219 and 7.2 microM) and S-acenocoumarol (Ki = 6.1 and 7.7 microM) but not S-warfarin in a competitive manner. 8. Differences in the partial (up to 40%) inhibition of the metabolism of the enantiomers of the 4-hydroxycoumarins were also observed for the relatively weak inhibitors, propafenone and cimetidine.9. The results suggest that the coumarin ring hydroxylations of both compounds are catalysed by different combinations of P450 isozymes. The 7-hydroxylation of R/S acenocoumarol and the 6-hydroxylation of S-acenocoumarol are at least partly conducted by (a) P450 isozyme(s) of the 2C subfamily different from P450 2C9 (the main S-warfarin 7- and 6-hydroxylase).

Lack of effect of ponsinomycin on the pharmacokinetics of nicoumalone enantiomers

Pharmacokinetic interaction between ponsinomycin-nicoumalone was studied in six subjects who received an 8 mg oral dose of racemic nicoumalone alone and 4 days into an oral regimen of ponsinomycin 800 mg twice daily. The concentrations of R(+) and S(-)-nicoumalone in plasma were measured using a stereospecific h.p.l.c. assay. The disposition characteristics of nicoumalone enantiomers in the control phase of this study were similar to those reported previously with the exception of the data for one subject whose oral clearance for S(-)-nicoumalone was seven times lower than those in the other subjects. A statistically significant effect of ponsinomycin on the kinetics of R(+) and S(-)-nicoumalone was not demonstrated.

Detection of drug interactions with single dose acenocoumarol: new screening method?

In this study, a design for the evaluation of drug interactions with an oral anticoagulant drug was investigated. The interaction between a single dose of acenocoumarol and cimetidine or pentobarbitone was studied. Nine healthy volunteers received three treatments: 1) 10 mg acenocoumarol in combination with cimetidine, 2) 10 mg acenocoumarol in combination with placebo, 3) 10 mg acenocoumarol after one week pretreatment with pentobarbitone. The pharmacokinetics and the pharmacodynamics of acenocoumarol were monitored for 36 h. In all subjects the plasma concentration of acenocoumarol remained consistently higher during cimetidine treatment and consistently lower after pentobarbitone pretreatment compared to placebo treatment. Cimetidine increased the anticoagulant response of acenocoumarol as measured by the Thrombotest and pentobarbitone decreased this response in all subjects. It is concluded from this study that both pharmacokinetic and pharmacodynamic drug interactions with acenocoumarol (and presumably other oral anticoagulants) can be detected after single doses, possibly obviating the use of long-term anticoagulation in healthy volunteers.

Interaction of the combined medication with the new low-molecular-weight heparinoid Lomoparan (Org 10172) and acenocoumarol

A high intravenous dose of the low-molecular-weight heparinoid Lomoparan (Org 10172) was administered to 6 healthy males in a steady state of anticoagulation (Thrombotest) by acenocoumarol. Prothrombin time, activated partial thromboplastin time and Stypven time were prolonged to a degree which was greater than that expected on the base of the summation of the effects by each drug alone. This effect was observed for a period of up to 1 h. The Thrombotest was affected for up to 5 h after the intravenous administration of Org 10172, therefore it is deemed unsuitable for monitoring the combined effects of these two anticoagulants during this period. Acenocoumarol did not affect the pharmacokinetic parameters of Org 10172 with the exception of a slight reduction of the clearance of plasma anti-Xa activity.

The interaction of the prostaglandin E derivative rioprostil with oral anticoagulant agents

The prostaglandin E1 analogue rioprostil was tested for potential interaction with oral anticoagulant therapy in healthy male volunteers. The effect of rioprostil (0.3 mg, twice a day) was investigated on acenocoumarol (10 mg per subject, n = 7) and phenoprocoumon (0.2 mg/kg, n = 6) single-dose pharmacokinetics and pharmacodynamics. Plasma levels of thrombotest, prothrombin (factor II), and factor VII activities were assayed. Rioprostil, 7 days pretreatment, did not affect control parameters of blood coagulation activity. During the rioprostil period the effect of phenprocoumon on thrombotest and factor VII activities was significantly weaker (p less than 0.02, ANOVA) compared with the control experiment. The effect of acenocoumarol on thrombotest activity was significantly weaker at 24 and 31 hours. None of the pharmacokinetic parameters tested were affected by rioprostil medication. The findings suggest that prostaglandins, at least those of the E series, attenuate the anticoagulant action of the oral anticoagulant agents by a mechanism not related to any pharmacokinetic interaction.

Cimetidine-nicoumalone interaction in man: stereochemical considerations

1. The cimetidine-nicoumalone interaction was studied in five subjects who received a single 10 mg oral dose of racemic nicoumalone alone and 3 days into an oral regimen of cimetidine of 200 mg three times daily and 400 mg at night. 2. The concentrations of R(+)- and S(-)-nicoumalone in plasma were measured using a stereospecific h.p.l.c assay; augmentation of prothrombin time was used as a measure of response. 3. Cimetidine increased the rate (but not extent) of absorption of both R(+)- and S(-)-nicoumalone, and reduced the clearance of R(+)-nicoumalone but not that of the S(-)-enantiomer. 4. Cimetidine increased the anticoagulant response produced by nicoumalone in some but not all subjects, despite a consistent effect on the pharmacokinetics of the oral anti-coagulant. 5. Cimetidine appears to produce its effect by stereoselectively inhibiting the elimination of R(+)-nicoumalone.

Phenylbutazone-hydroxycoumarol interactions. Effects on steady state disposition, hepatocellular distribution, and biliary excretion of (S)-acenocoumarol in rats

The effect of phenylbutazone on the disposition of (S)-acenocoumarol in the rat was studied at steady state conditions of distribution and elimination. (S)-Acenocoumarol was administered by constant rate infusions (1 microgram/min). The biliary excretion of 6- and 7-hydroxylated acenocoumarol was followed and the intrahepatic distribution was investigated. Phenylbutazone (50 mg/kg) increased the plasma unbound fraction about 4-fold. (S)-Acenocoumarol plasma clearance was enhanced (2.8 +/- 0.15 vs. 1.54 +/- 0.14 ml/min) but the unbound plasma clearance was reduced by 50% (67 +/- 9 vs. 140 +/- 27 ml/min). Phenylbutazone caused an intrahepatic redistribution of (S)-acenocoumarol, i.e. the drug shifted from the cytosol to the 10,000g pellet. The cytosolic unbound concentration, however, was increased. The (S)-acenocoumarol content in the microsomal fraction was not affected. The biliary excretion rate of total metabolite (free plus conjugated) comprised 50% of the (S)-acenocoumarol infusion rate in controls and was slightly stimulated (+20%) by phenylbutazone. The biliary excretion of free metabolites, however, was greatly increased (62 +/- 7 vs. 22 +/- 6 ng/min for 6-hydroxy-acenocoumarol; 337 +/- 38 vs. 141 +/- 32 ng/min for 7-hydroxy-acenocoumarol). This effect is probably due to stimulation of a hepatic biliary transport system; the rate constant for transport of 7-hydroxy-acenocoumarol was enhanced 5-fold (0.107 +/- 0.03 vs. 0.021 +/- 0.007 min-1).