Validation of a High-Performance Liquid Chromatography-Tandem Mass Spectrometry Method for the Determination of Perhexiline and Cis-Hydroxy-Perhexiline Plasma Concentrations.

BACKGROUND: The polymorphic nature of cytochrome P450 2D6 has made therapeutic drug monitoring of the anti-anginal agent perhexiline a compulsory step in reducing adverse events associated with plasma concentrations above the therapeutic range (0.15-0.60 mg/L). The aim of this study was to develop a high-performance liquid chromatography-mass spectrometry/mass spectrometry method for the determination of plasma perhexiline concentrations and its major metabolite cis-hydroxy-perhexiline to reduce sample extraction procedures and improve sample turnaround times. METHODS: The method was validated by determining the precision and accuracy of calibrators and quality control material, comparing quality assurance program samples and patient samples measured by a previously reported liquid-liquid extraction fluorescence (FL) detection high-performance liquid chromatography method and performing matrix effects investigations. RESULTS: Replicates of calibrators at concentrations of 3.00 and 0.05 mg/L demonstrated imprecision of <10.8% and inaccuracy of <8.2% for perhexiline and <10.1% and <4.5% for cis-hydroxy-perhexiline, respectively. All samples measured by the 2 methods (n = 102) demonstrated Deming regression of perhexiline = 1.20 FL + 0.00 (Sy.x = 0.08, 1/slope = 0.67); cis-hydroxy-perhexiline = 1.48 FL - 0.20 (Sy.x = 0.40, 1/slope = 0.67). CONCLUSIONS: The assay performance was deemed acceptable and integrated into the routine therapeutic drug monitoring program of the department.

Effects of aging, renal dysfunction, left ventricular systolic impairment, and weight on steady state pharmacokinetics of perhexiline.

MATERIALS AND METHODS: Two hundred patients at steady-state on long-term perhexiline were identified retrospectively. The ratio of maintenance dose to steady-state plasma concentration (dose:[Px]) was correlated with the following putative determinants via simple and multiple linear regression analyses: age, weight, left ventricular ejection fraction (LVEF), and creatinine clearance (CrCl, Cockroft-Gault formula). A Mann-Whitney U test was performed to determine if severe left ventricular systolic impairment affected maintenance dose. RESULTS: Advanced age, left ventricular systolic impairment, and renal impairment were frequently encountered. Using simple linear regression, age was a negative correlate of dose:[P] (R = 0.23, P = 0.001), whereas weight (R = 0.27, P = 0.0001) and CrCl (R = 0.30, P < 0.0001) were positive correlates. Mann-Whitney U analysis showed no difference between dose: [Px] among patients with LVEF of less than 30% versus 30% or greater. Advancing age was strongly associated with decreasing weight (R = -0.45, P < 0.00001) and calculated CrCl varied directly with weight, as expected (R = 0.66, P < 0.0001). Stepwise multiple linear regression using age, LVEF, CrCl, and weight as potential predictors of dose:[P] yielded only weight as a significant determinant. DISCUSSION: Perhexiline has become a "last-line" agent for refractory angina as a result of complex pharmacokinetics and potential toxicity. Use has increased predictably in the aged and infirm who have exhausted standard medical and surgical therapeutic options. Beyond genotype, the effect of patient characteristics on maintenance dose has not been explored in detail. In this study, dose requirement declined with age in a frail and wasting population as a result of weight-related pharmacokinetic factors. LVEF had no apparent effect on maintenance dose and should not be considered a contraindication to use. CONCLUSION: A weight-adjusted starting dose may facilitate the safe and effective prescription of perhexiline and is calculated by 50 + 2 × weight (kg) mg/d, rounded to the closest 50 mg/day.

Steady-state pharmacokinetics of the enantiomers of perhexiline in CYP2D6 poor and extensive metabolizers administered Rac-perhexiline.

UNLABELLED: What is already known about this subject. Perhexiline (PHX) is administered as a racemic mixture and exhibits enantioselective pharmacokinetics in both poor and extensive metabolizers of CYP2D6 (PM and EM, respectively). Extensive metabolism by CYP2D6 is primarily responsible for the observed enantioselectivity in EM, but the process responsible in PM is unknown. Analysis of the steady-state plasma concentration-time profiles of the enantiomers of PHX in PM and EM was undertaken in order to elucidate the observed enantioselectivity, particularly with respect to PM. What this study adds. This is the first study to examine the steady-state plasma concentration-time profiles of the enantiomers of PHX in EM and PM over the course of an interdosing interval. The apparent oral clearance of each enantiomer was calculated from their respective AUC rather than from trough concentrations and was enantioselective in both phenotypes, with higher apparent oral clearances of (-)-than (+)-PHX. Renal clearance, calculated for EM and subsequently assumed for PM, constitutes a greater proportion of the total apparent oral clearance of each enantiomer in PM than EM, but was not enantioselective and thus unable to explain the enantioselectivity observed in PM. AIMS: To determine the steady-state pharmacokinetics of perhexiline (PHX) enantiomers over one interdosing interval in CYP2D6 extensive and poor metabolizer (EM and PM, respectively) patients administered rac-PHX. To elucidate the processes responsible for enantioselectivity, particularly in PM patients. METHODS: Blood samples were taken over one interdosing interval from six EM and two PM patients at steady-state with respect to rac-PHX metabolism. Complete urine collections were taken from five EM patients. PHX concentrations in plasma and urine were determined with enantioselective high-performance liquid chromatography methods. RESULTS: EM patients had 16- and 10-fold greater median apparent oral clearances of (+)- and (-)-PHX, respectively, than PM patients (P < 0.05 for both) and required significantly larger doses of rac-PHX (69 vs. 4.2 microg kg(-1) h(-1), P < 0.05) to maintain therapeutic concentrations in plasma. Patient phenotypes were consistent with CYP2D6 genotypes. Both groups displayed enantioselective pharmacokinetics, with higher apparent oral clearances for (-)-PHX compared with (+)-PHX, although PM patients exhibited significantly greater enantioselectivity (P < 0.05). The renal clearance of PHX enantiomers was not enantioselective and accounted for <1% of the median apparent oral clearance of each enantiomer in EM patients. Assuming the same renal clearances for PM patients accounts for approximately 9 and 4% of their median apparent oral clearances of (+)- and (-)-PHX, respectively. CONCLUSIONS: The enantioselective pharmacokinetics of PHX are primarily due to metabolism by CYP2D6 in EM patients. The mechanism responsible for the enantioselective pharmacokinetics of PHX in PM patients is unknown, but may be due to enantioselective biliary or intestinal excretion.

The validation of an LC-MS/MS assay for perhexiline and major hydroxy metabolites, and its application to therapeutic monitoring in patient plasma.

AIM: Perhexiline (PEX), being developed to treat hypertrophic cardiomyopathy, is toxic at levels above the therapeutic range. Plasma level monitoring is therefore essential. The absence of a UV-absorbing chromophore has in the past required quantitative analysis of PEX in plasma using lengthy derivatization methods, followed by HPLC and fluorescence detection. The routine and urgent analysis of a large number of patient plasma samples necessitates faster and reliable analytical methodology. RESULTS: An LC-MS/MS method, using two novel internal standards, has been validated for the quantitative measurement of PEX and its major hydroxy metabolites in human plasma. CONCLUSION: The assay has been applied to therapeutic drug monitoring (TDM), where PEX and the ratio of the drug to cis-hydroxy perhexiline, were measured at designated intervals.

Enantioselective assay for the determination of perhexiline enantiomers in human plasma by liquid chromatography.

Effective use of the antianginal agent perhexiline is difficult because saturable metabolism by the polymorphic cytochrome P450 2D6 (CYP2D6) isoform produces elevated plasma perhexiline concentrations that have been associated with serious hepatic and neurological toxicity. Perhexiline is marketed for therapeutic use as a racemate and there is evidence for differences in the disposition of its enantiomers. The current study describes an enantioselective HPLC-fluorescent method utilising pre-column derivatization with (R)-(-)-1-(1-napthyl)ethyl isocyanate. Following derivatization, the enantiomers are resolved on a C18 column with gradient elution using a mobile phase composed of methanol and water. The method described is suitable for the quantification of (+)- and (-)-perhexiline in human plasma following clinical doses and demonstrates sufficient sensitivity, accuracy and precision between 0.01 and 2.00 mg/l for each enantiomer, with intra-assay coefficients of variation and bias <20% at 0.01 mg/l and <10% at 2.00 mg/l, and inter-assay coefficients of variation and biases <15% at 0.03 mg/l and <10% at 0.40 and 0.75 mg/l. The application of this method to plasma samples collected from a patient treated with perhexiline revealed that (+)-perhexiline concentrations were higher than (-)-perhexiline concentrations, confirming the stereoselective disposition of perhexiline. The current study describes an enantioselective method that utilises pre-column formation of fluorescent diastereomers that are resolved on a C18 HPLC column using a gradient of methanol and water.

Use of 'dilute-and-shoot' liquid chromatography-high resolution mass spectrometry in preclinical research: application to a DMPK study of perhexiline in mouse plasma.

This work describes a simple, sensitive and rapid liquid chromatography-high resolution mass spectrometry method for the quantitation of perhexiline and the simultaneous detection of perhexiline metabolites in C57bl/6 mice plasma. Only 5 µL of plasma was used for analysis. Pretreatment was limited to a 100-fold dilution ('dilute-and-shoot'). The analyte was detected by high resolution mass spectrometry (Orbitrap™ technology). Three scan events were performed over the entire chromatogram. Targeted single ion monitoring with data dependent acquisition was employed for perhexiline quantitation and confirmation, while full scan was used to perform untargeted detection of perhexiline phase I and phase II circulating metabolites. The calibration curve was linear (r(2)=0.990) ranging from 0.305 ng/mL (LLOQ) to 10000 ng/mL. Matrix effect was limited to 6.1%. The method was applied to a pharmacokinetic study of perhexiline in mouse plasma and the results obtained were compared to a standard sample preparation method based on protein precipitation and liquid chromatography-tandem mass spectrometry (MRM mode) detection. The new approach provided comparable results in terms of pharmacokinetics parameters estimate with a high sensitivity, additional information on perhexiline circulating metabolites and a low consumption of biological sample. The combination of the 'dilute-and-shoot' approach together with HRMS targeted and untargeted detection represents a suitable alternative to classic bioanalytical approaches in preclinical research.

Determination of perhexiline and hydroxyperhexiline in plasma by liquid chromatography-mass spectrometry.

A method for the quantitative determination of perhexiline and its main hydroxylated metabolites in human plasma, based on liquid chromatography-mass spectrometry (LC-MS), was developed. The method used protein precipitation with acetonitrile followed by dilution with water and subsequent direct injection of the extract into the LC-MS system. Hexadiline was used as internal standard and the intra-assay coefficients of variation were

High-performance liquid chromatographic assay of perhexiline maleate in plasma.

A sensitive assay is described for the calcium antagonist perhexiline maleate. Alkalinized plasma was extracted with nb-hexane, the organic phase was evaporated, and the residue was dansylated prior to analysis by reversed-phase high-performance liquid chromatography using a fluorescence detector. Perhexiline was resolved from its mono- and dihydroxylated metabolites, and the limit of sensitivity was 5 ng of perhexiline/ml. This limit represents approximately 100 times the sensitivity of the previously described GLC assay. Single-dose pharmacokinetic studies were performed with 150- and 300-mg oral doses of perhexiline maleate in five patients with severe angina pectoris and impaired left ventricular function. Peak plasma perhexiline levels occurred 3-6 hr after drug ingestion in four patients and after 12-18 hr in the fifth patient. The mean elimination half-life, measured 24 hr after drug ingestion, varied with plasma perhexiline concentration. It was 11.2 +/- 2.1 hr after the 150-mg dose and 19.1 +/- 2.8 hr after the 300-mg dose. The mean ratio of areas under the concentration-time curve for the 300-versus 150-mg doses ws 5.3:1, suggesting that hepatic metabolism of perhexiline may be saturable and that the bioavailability of perhexiline is dose dependent.

Therapeutic monitoring of the anti-anginal drug perhexiline maleate.

Patients taking oral doses of perhexiline maleate have been examined. Measurement of serum perhexiline concentrations established that different dose requirements between patients were necessary due to the different doses at which drug saturation was achieved. Measurement of serum perhexiline concentrations are essential if side-effects from the drug are to be avoided.

A rapid method for the determination of perhexiline in serum using gas-liquid chromatography.

A rapid method for the estimation of perhexiline in serum is presented. The procedure employs a single extraction, and no derivatisation is required. The procedure is linear over the range 0.4-4.0 mg/l, and the limit of detection is 0.09 mg/l. The within- and between-batch coefficients of variation at a concentration of 2.0 mg/l were 2.5 and 4.1%, respectively. Recoveries over the range 0.4-4.0 mg/l produced a mean of 104%. The method is free from interference by other common drugs used in the treatment of angina.

[The classic anti-anginal agents and molsidomine]. / Les anti-angineux classiques et la molsidomine.

In the face of the recent introduction of beta-blockers and calcium inhibitors, the author examines the role of Amiodarone, Perhexiline and Molsidomine in the treatment of angina pectoris. Amiodarone, introduced in 1967, remains a very useful anti-anginal drug. The beta and alpha-sympathetic inhibition it produces, makes it effective in effort and resting angina. It is particularly useful in anginal patients with arrhythmias as it has a potent anti-arrhythmic effect at all levels. It can be used in patients with bronchial asthma, in elderly patients and in cardiac failure. However, it may give risk to hypo or hyperthyroidism and so, should not be used in patients with a history or thyroid disorders. Perhexiline has been used in France since 1973 and is a second-line drug to be used in cases of intolerance or contraindications to other anti-anginal drugs. It is effective but may cause severe, undesirable hepatic and neurological complications. These side effects are however rare at low doses. Molsidomine, a more recent molecule, has an action similar to that of the nitrate derivatives: it mainly reduces left ventricular preload. It has a slower onset of action than the classical nitrate derivatives but its duration of action seems to be longer; Molsidomine and betablockade can be a useful therapeutic association.

Metabolic manipulation in chronic heart failure: study protocol for a randomised controlled trial.

BACKGROUND: Heart failure is a major cause of morbidity and mortality in society. Current medical therapy centres on neurohormonal modulation with angiotensin converting enzyme inhibitors and ß-blockers. There is growing evidence for the use of metabolic manipulating agents as adjunctive therapy in patients with heart failure. We aim to determine the effect of perhexiline on cardiac energetics and alterations in substrate utilisation in patients with non-ischaemic dilated cardiomyopathy. METHODS: A multi-centre, prospective, randomised double-blind, placebo-controlled trial of 50 subjects with non-ischaemic dilated cardiomyopathy recruited from University Hospital Birmingham NHS Foundation Trust and Cardiff and Vale NHS Trust. Baseline investigations include magnetic resonance spectroscopy to assess cardiac energetic status, echocardiography to assess left ventricular function and assessment of symptomatic status. Subjects are then randomised to receive 200 mg perhexiline maleate or placebo daily for 4 weeks with serum drug level monitoring. All baseline investigations will be repeated at the end of the treatment period. A subgroup of patients will undergo invasive investigations with right and left heart catheterisation to calculate respiratory quotient, and mechanical efficiency. The primary endpoint is an improvement in the phosphocreatine to adenosine triphosphate ratio at 4 weeks. Secondary end points are: i) respiratory quotient; ii) mechanical efficiency; iii) change in left ventricular (LV) function. TRIAL REGISTRATION: ClinicalTrials.gov: NCT00841139 ISRCTN: ISRCTN72887836.

Determination of perhexiline and its metabolite hydroxyperhexiline in human plasma by liquid chromatography/tandem mass spectrometry.

Perhexiline is a drug that is used for treatment of moderate to severe angina pectoris that has not responded to other treatment. It has a low therapeutic index, and saturable metabolism that is also subject to genetic polymorphism (CYP2D6). Concentration monitoring of the parent drug and its major metabolite is considered necessary to optimise efficacy and reduce the risk of hepatotoxicity and neuropathy. A rapid, simple and sensitive liquid chromatography/tandem mass spectrometry (LC-MS/MS) assay was developed for the determination of perhexiline and its metabolite cis-hydroxyperhexiline in human plasma. After proteins were precipitated with acetonitrile, perhexiline, the major metabolite cis-hydroxyperhexiline and nordoxepin as the internal standard were resolved on a phenyl-hexyl column using gradient elution of 0.05% formic acid and methanol. The three compounds were detected using electrospray ionisation in the positive mode. Standard curves were linear over the concentration range 10-2000microg/L (r>0.999), bias was

The influence of CYP2D6 genotype on trough plasma perhexiline and cis-OH-perhexiline concentrations following a standard loading regimen in patients with myocardial ischaemia.

AIMS: CYP2D6 protein expression is determined by the number of functional CYP2D6 alleles. It is also higher in individuals with at least one CYP2D6*2 allele. This study has investigated the effect of the number of functional CYP2D6 alleles and the influence of CYP2D6*2 alleles on plasma perhexiline concentrations in patients administered a standard loading regimen over 3 days. METHODS: Eighteen patients with myocardial ischaemia who were not taking any drugs known to inhibit CYP2D6 metabolism in vivo commenced treatment with 200 mg of perhexiline twice per day. On the fourth day, blood was drawn for genotyping and the measurement of trough plasma concentrations of perhexiline and its major metabolite, cis-OH-perhexiline. RESULTS: The only genotypic CYP2D6 poor metabolizer had a trough plasma perhexiline concentration of 2.70 mg l-1 and no detectable cis-OH-perhexiline. The mean+/-SD trough plasma perhexiline concentration in patients with one functional allele was significantly higher (0.63+/-0.31 mg l-1, n=8, P=0.05) than in patients with two functional alleles (0.37+/-0.17 mg l-1, n=9). Conversely, the mean metabolic ratio was significantly lower in patients with one functional allele (2.90+/-1.76, P<0.01) compared with patients with two functional alleles (6.52+/-3.26). Patients with at least one CYP2D6*2 allele had a lower plasma perhexiline concentration (0.20+/-0.09 mg l-1, n=5, P<0.001) and a higher metabolic ratio (7.86+/-2.51, P<0.01) than the non-poor metabolizer patients with no CYP2D6*2 alleles (0.62+/-0.23 mg l-1 and 3.55+/-2.54, respectively, n=12). CONCLUSION: Patients with only one functional allele and not CYP2D6*2 have diminished CYP2D6 metabolic capacity for perhexiline.

Simultaneous determination of perhexiline and its monohydroxy metabolites in biological fluids by gas chromatography-electron-capture detection.

A rapid and sensitive method for the simultaneous determination of perhexiline and its cis-4-axial and trans-4-equatorial monohydroxy metabolites (M1 and M3, respectively) in human plasma, urine and bile is described. The assay utilises a single diethyl ether extraction, heptafluorobutyric acid anhydride derivatisation and separation and detection by gas chromatography-electron-capture detection. The limits of detection are 0.1 microgram/ml for perhexiline and 0.025 microgram/ml for the M1 and M3 metabolites. This method has been used in a five-day kinetic study of three healthy adult males who ingested a single 300-mg dose of perhexiline maleate. One of these volunteer subjects exhibited elevated plasma perhexiline and markedly reduced plasma and urinary M1 concentrations together with profoundly prolonged plasma and urinary M1 elimination times when compared with the other two subjects. These differences are thought to be of genetic origin. There were also obvious differences in urinary M3 concentrations which were discussed.

Further studies on the pharmacokinetics of perhexiline maleate in humans.

We have performed single-dose pharmacokinetic studies on perhexiline in eight young volunteers, each given 300 mg of Pexid orally, using an h.p.l.c. method for the separation and quantification of the drug and its monohydroxy metabolites in plasma and urine. The plasma concentration of the cis-monohydroxyperhexiline (peak of 473 +/- 43 ng/ml at 7.5 +/- 2.0 h) was always higher than for unchanged perhexiline (peak of 112 +/- 20 ng/ml at 6.5 +/- 2.0 h) whereas the concentration of the transmetabolite was either low or undetectable in plasma. These findings indicate the occurrence of stereospecific pre-systemic metabolism of perhexiline which reduces the bioavailability of the parent drug. The plasma elimination half-life of perhexiline was 12.4 +/- 6.1 h (range 7-23 h) while that for cis-monohydroxyperhexiline was 19.9 +/- 7.7 h (range 10-29 h). Not more than 0.3% of unchanged perhexiline was excreted in the urine over five days in eight subjects. Between 3 and 23% of the orally administered drug was excreted as the cis- or trans-monohydroxy metabolites, the ratio of trans to cis metabolites being 0.52 +/- 0.20.

Single-dose pharmacokinetics of perhexiline administered orally to humans.

A high-performance liquid chromatographic method for the simultaneous determination of perhexiline and its major metabolites, the cis- and trans-monohydroxyperhexilines M1 and M3, respectively, in human plasma or urine has been developed. Perhexiline and its metabolites are extracted from plasma or urine and derivatized with 1-fluoro-2,4-dinitrobenzene. The extracted dinitrophenyl derivatives of drug and metabolites are separated on a Spherisorb S5 ODS column by gradient elution. The limits of detection for perhexiline and its monohydroxy metabolites were 15 and 3 ng/ml, respectively. The inter-assay coefficients of variation for 100 ng/ml perhexiline, 100 ng/ml M1 and 400 ng/ml M3 were 10.5, 7.6 and 5.6%, respectively (n = 9). The method has been employed in a limited kinetic study with five healthy adult male volunteers who received 150-mg and 300-mg Pexid tablets at an interval of one week. In four subjects perhexiline exhibited marked first pass effects, with plasma M1 levels higher than unchanged perhexiline; in the urine M1 was the predominant metabolite except in one subject who had higher M3 than M1 in the 300-mg Pexid study. The fifth subject exhibited a defective capacity to hydroxylate perhexiline; M1 and M3 were not detectable in plasma, and the urinary excretion of the monohydroxyperhexilines was relatively less, with M3 present in higher amounts than M1.

[Perhexilline maleate: relationship between side-effects, plasma concentrations and rate of metabolism (author's transl)]. / Maléate de perhexiline: relations entre effets secondaires, concentrations plasmatiques et vitesse du métabolisme.

In three individuals (2 male and 1 female) with severe side-effects apparently related to the regular ingestion for a period of at least 5 months of perhexiline maleate, the authors studied the rate of fall in plasma levels of the drug, of its monohydroxylated metabolite, blood transaminase and glucose levels following the interruption of therapy. The relationship between these data would indicate two hypotheses which could be tested during future studies: the manner in which the body metabolises the drug would appear to vary in relation to plasma concentration and/or hepatic involvement.

Investigations of long-term treatment with perhexiline maleate using therapeutic monitoring and electromyography.

Experience is reported with 41 patients taking perhexiline maleate for angina pectoris for periods of up to 70 months, while serum concentrations of the drug were monitored, and liver function tests and electromyographic tests were made before and during treatment. Severe side effects did not occur unless serum perhexiline levels were greater than 1.5 mg/L. The drug seems effective for prolonged dosage, and the monitoring of weight, liver function test results, and serum concentrations should prevent or reduce toxicity. A starting dose of 100 mg daily is recommended. The drug is not recommended for routine use in angina pectoris.