Int J Pharm Pharm Sci, Vol 13, Issue 10, 43-46Original Article

LIQUID CHROMATOGRAPHY TANDEM MASS SPECTROMETRY DETERMINATION METHOD OF BENCYCLOQUIDIUM BROMIDE: APPLICATION TO DRUG INTERACTION STUDY IN HUMAN

JANVIER ENGELBERT AGBOKPONTO1,2*, LOCONON ACHILLE YEMOA2, ASSOGBA GABIN ASSANHOU2, RUIJUAN LIU1, HABIB GANFON2, LI DING1*

1Department of Pharmaceutical Analysis, China Pharmaceutical University, Nanjing, China, 2UFR/Pharmacie, Faculte Des Sciences de la Sante, UAC, Cotonou, BENIN
*Email: aengelbert@yahoo.fr

Received: 27 Mar 2015, Revised and Accepted: 30 Aug 2021


ABSTRACT

Objective: This study was conducted to develop a sensitive and effective LC-MS/MS method for the determination of bencycloquidium bromide (BCQB) and its application in pharmacokinetic drug interaction study between BCQB and paroxetine.

Methods: The chromatographic separation was performed on Hedera ODS-2 C18 column with a mobile phase consisted of acetonitrile-10 mmol/l ammonium acetate containing 0.2% acetic acid (33:67, v/v) at 550 μl/min, and the plasma samples were processed using solid-phase extraction. The MS/MS transitions were m/z 330.2 → 142.0 for BCQB and m/z 344.2 → 156.1 for the I. S in positive ESI mode.

Results: The validated method was linear over the concentration range of 2-1200 pg/ml with the correlation coefficient r2>0.998. The intra-and inter-batch precisions of the assay were lower than 8.2% and 9.1%, respectively. The lower limit of quantification (LLOQ) was 2 pg/ml. The stability data at different storage conditions of BCQB were within±5% RE. The mean AUC0-36 of BCQB was increased by approximately 33%, after the administration of BCQB alone and upon co-administration with paroxetine during the drug interaction study.

Conclusion: The LC-MS/MS method validated in this study was robust, reproducible, accurate, precise and reliable and was successfully applied in the pharmacokinetic drug interaction studies.

Keywords: Bencycloquidium bromide, LC-MS/MS, Pharmacokinetic drug interaction, Paroxetine


INTRODUCTION

Bencycloquidium bromide (BCQB) is a selective muscarinic M1/M3 receptor antagonist developed for the treatment of rhinitis, asthma and chronic obstructive pulmonary disease (COPD) [1-3]. Studies on general pharmacological actions of BCQB suggested that it had no obvious effect on cardiovascular and respiratory in beagle dogs, and could decrease the extraction of the bronchus gland and inhibit the peristalsis of the small intestine in mice [4, 5]. Under the clinical trial, an early study has shown its tolerability and efficacy [6]. However, the investigations of drug interactions of BCQB in humans remain an important part of its safety. Our recent study on in vitro metabolism and disposition of BCQB in human revealed that BCQB is the substrate of several metabolic enzymes. It is metabolized mainly by CYP2D6 and also weekly by CYP3A4/5 and CYP2C19 [7-8]. During BCQB drug development phase, it is required to perform pharmacokinetic drug interaction studies with other drugs (known as inhibitors or inducer of metabolic enzymes) based on blood concentration measurements. Most often, plasma is prepared and used for analytical investigation in such studies [9-10]. A number of bioanalytical methods have been described for the determination of BCQB in biological media [11-12]. Previous publications have described methods for the analysis of BCQB in animals’ samples by LC-MS. However, the lower limit of quantitation (LLOQ) of the methods was too high (3 ng/ml and 0.05 ng/ml) and not applicable. BCQB is an anticholinergic agent used in rhinitis, COPD and asthma, and is administered nasally at a very low dosage (180 µg). Therefore a highly sensitive and selective determination method is required. An LC-MS method for the determination of BCQB in human plasma was reported [13], but was less sensitive for drug interactions study and required a long analytical run time.

In order to perform BCQB plasma measurements in connection with a clinical trial, the goal was to establish an analytical method with both high sensitivity and high capacity due to the expected low concentration of BCQB. We, therefore, designed and validated an effective LC-MS/MS method for BCQB determination. Our method was successfully applied in a pharmacokinetic drug interaction study between BCQB and paroxetine, a strong inhibitor of CYP2D6, and fulfilled the high demands of a low measuring range and a time constraint schedule.

MATERIALS AND METHODS

Chemicals and reagents

The reference standard of BCQB (>99.7% purity) and 1-ethyl-bencycloquidium bromide (IS) (>99.9% purity) (fig. 1) were supplied by Beijing Shiqiao Biological and Pharmaceutical Co. Ltd. (Beijing, China). The weak cation-exchange solid-phase extraction (WCE-SPE) columns were purchased from Cleanert TM Angela Technologies (Beijing, China). Methanol and Acetonitrile were of HPLC grade and purchased from Merck KGaA (Darmstadt, Germany). Formic acid, acetic acid and ammonium acetate were of analytical grade and purchased from Nanjing Chemical Reagent Co., Ltd. (Nanjing, China). Distilled water was used throughout the experiment.

Fig. 1: Chemical structure of BCQB (A) and IS (B)

LC–MS/MS instrumentation and conditions

The liquid chromatography was done on an Agilent 1200 Series liquid chromatography (Agilent Technologies, Palo Alto, CA, USA), which included an Agilent 1200 binary pump (model G1312B), vacuum degasser (model G1322A), Agilent 1200 autosampler (model G1367C), temperature-controlled column compartment (model G1330B). The chromatographic separation was achieved on a Hedera ODS-2 C18 column (150 mm×2.1 mm i.d., 5 μm d. p, Hanbon Sci. and Tech) protected by a security guard C18 column (4 mm × 2.0 mm i.d., 5μm d. p, Phenomenex, Torrance, CA, USA) with a mobile phase of acetonitrile-10 mmol/l ammonium acetate solution containing 0.2% acetic acid (33:67, v/v) at a flow rate of 550 μl/min. The column temperature and auto-sampler temperature were maintained at 39 °C and 15 °C, respectively. The injection volume was 10 μl. The LC system was coupled with an Agilent 6410B triple quadrupole mass spectrometry (Agilent Technologies, USA) equipped with an electrospray ionization source (model G1956B). The mass spectrometry was operated in positive ESI mode with the drying gas (N2) flow of 12 L/min, nebulizer pressure of 50 psi, drying gas temperature of 350 °C, the capillary voltage of 4.5kV. The fragmentation transitions for the multiple reaction monitoring (MRM) were m/z 330.2 → 142.0 for BCQB and m/z 344.2 → 156.1 for the IS (fig. 2). The fragmentor voltage value set for BCQB and the IS was 170V, and the collision energy was 40eV.

Fig. 2: Positive product ion mass spectra of BCQB (A) and IS (B)

Preparation of calibration standards and quality control sample

Calibration standards and quality control (QC) samples were prepared from independently weighed stocks. Standard stock solutions of BCQB and IS were prepared in methanol to a concentration of 1.006 mg/ml and 1.010 mg/ml. The stock solution of BCQB was further serially diluted to yield working solutions at several concentration levels, 100.6, 48.29, 40.24, 32.19, 16.10, 4.829, 4.024, 1.207, 0.4024, 0.2012, 0.1408 and 0.0804 ng/ml. The working solution of I. S was prepared at the concentration of 6.05 ng/ml by diluting the standard stock solution in methanol. All stock and working solutions were kept at-20 °C. Calibration standards and quality control samples were prepared by spiking blank plasma with the appropriate amount of working solutions. Calibration standards were of 2.01, 5.03, 10.06, 30.18, 100.6, 402.4, 804.8, 1207 pg/ml. QC samples were prepared at concentration levels of 3.52 pg/ml (Low), 120.7 pg/ml (Middle) and 1006 pg/ml (High).

Sample preparation

In this study, gravity was used to elute the solvents from the SPE column. The conditioning step involved activating the cartridge (1 ml) with 2 ml of methanol followed by 1 ml of H2O and then conditioning the cartridge with 2 ml of ammonium acetate buffer (25 mmol, pH 7.0). Aliquot of 1 ml plasma sample was transferred to a 2 ml capped tube, into which 30 µl of the I. S. solution (6.05 ng/ml) was spiked. The sample mixtures were vortexed for 30 s and centrifuged at 16,000 rpm for 5 min, and loaded onto the conditioned cartridge drop-wise. The lockstep involved treating the cartridge with 2 ml of ammonium acetate buffer (25 mmol, pH 7.0) to adjust the pH of the system to ensure that the ionization of the sorbent bed and its ion-exchange interactions with the analytes were enabled. The wash step utilized 2 ml of methanol to remove all unretained species from the sorbent bed. Elution was achieved by the addition of 2 ml of methanol containing 2% formic acid. No vacuum system was employed in the SPE process. All plasma samples, condition and elution solutions were allowed to pass through the SPE cartridges with the aid of gravity to ensure that there was enough time for the equilibrium of ion-exchange reactions in every SPE step.

The eluted solution was transferred to a 10 ml glass tube and evaporated to dryness at 40 ◦C under a stream of nitrogen. The dried extract was then dissolved in 100 ml of the mobile phase. The reconstituted solution was transferred to an autosampler vial and an aliquot of 10 µl injected into the chromatographic system.

Method validation

The method was validated according to the FDA’s industrial guidance for the bioanalytical method validation [14]. The method was validated for selectivity, linearity, recovery, matrix effect (ME), precision, accuracy, and stability. Method sensitivity was determined by the limit of detection (LOD) and low limit of quantification (LLOQ) based on a signal-to-noise ratio of 3:1 and 7:1, respectively. Selectivity and matrix effect was assessed by comparing the chromatograms of six different batches of blank plasma obtained from six different sources with those of corresponding spiked plasma. Each blank sample was tested for no endogenous interferences. Extraction recovery in plasma matrix for BCQB was determined at the three levels of QC and calculated as the ratio of analyte peak area from extracted QC samples to that from extracted blank matrices spiked with BCQB standard solution. To assess carryover effects, blanks were injected immediately after the highest calibration standard (ULOQ), and the response of any interfering peak had to be less than 20% of the response of an LLOQ sample. All validation experiments were carried out at three QC levels (Low QC, Middle QC and High QC) for precision and accuracy assessment. The precisions and accuracies should be within±15% except for LLOQ level, which should be within±20%. Auto-sampler stability, benchtop stability, freeze-thaw stability, post preparative stability and long-term stability of the analyte were assessed. Samples were considered to be stable when their relative error (RE) was less than 15%.

Pharmacokinetic study

The proposed analytical method was applied to the study of pharmacokinetic drug interaction between BCQB and paroxetine. The clinical pharmacokinetic trial was performed in accordance with guidelines established by the Declaration of Helsinki. The Ethics Committee of the West China Hospital of Sichuan University approved the study protocol and written informed consent had been obtained from each participant. The design of the study was an open-label, single-dose, two periods, single sequence crossover study. Chinese healthy volunteers were administered nasally a single dose of 180 μg of BCQB alone on day 1. Blood samples for pharmacokinetic evaluation were collected at 0 (pre-dose), 2 min, 5 min, 10 min, 15 min, 30 min, 1 h, 2 h, 4 h, 6 h, 9 h, 12 h, 15 h, 24 h and 36 h after BCQB administration. After a 7 d wash-out period, subjects were administered 20 mg of paroxetine once a day from day 8 to day 17 and 180 μg of BCQB were co-administered with 20 mg of paroxetine on day 18. Blood samples were collected as mentioned above. The plasma fractions were stored at −20◦C until analysis. An aliquot of 1 ml of thawed plasma samples was spiked with the IS and processed as mentioned in Section 2.4 above. Each analytical run was validated according to the FDA guidance for industry: Bioanalytical and method validation.

RESULTS AND DISCUSSION

Method development and optimization

Chromatographic conditions, especially the composition of the mobile phase, were optimized to enhance the sensitivity and achieve better separation from an endogenous matrix, as well as shorten the total run time. In this study, acetonitrile rather than methanol was chosen as organic eluent because it provided a higher mass spectrometric response and lower background noise. Acetonitrile had a strong eluting strength on endogenous compounds, eliminated matrix effect and shortened the total analytical run time to 7.5 min instead of 12 min in previous methods. The LLOQ and ULOQ were improved and the calibration range was extended (2–1200 pg/ml) to fit into the drug drugs interaction study without further dilution step. The mass spectrometry valve was diverted to waste from 5.5 min to 7.5 min when impurities from endogenous compounds were eluting from the HPLC.

Method validation

Selectivity and carryover

The selectivity of the method was determined by analyzing blank controls from six different individuals. There was no endogenous interference observed at the retention times of BCQB and the IS, which were 3.35 and 4.25, respectively. No carry-over peaks were observed at the retention times of BCQB and the IS in the chromatogram of blank plasma injected after the highest concentration (ULOQ) sample. Typical MRM chromatograms of blank plasma samples, blank plasma spiked with BCQB at LLOQ level and the internal standard, and a plasma sample from a healthy volunteer at 1h after dosing, respectively, are shown in fig. 3.

Linearity, accuracy and precision

The Calibration curves were linear over the concentration range of 2–1200 pg/ml with a correlation coefficient r2>0.998. The typical equations of the calibration curves were f = 0.006380×C+0.01538, where f represents the peak area ratio of the analytes to the IS and C represents the concentration of the analytes. Validation samples of five replicates of the LLOQ and QC samples were prepared and analyzed in three separate analytical batches to evaluate the accuracy and intra-day and inter-day precision of the methods. Assay precision was calculated using the relative standard deviation (R. SD %) and performing a one-way analysis of variance (ANOVA). The precision (RSD) and accuracy (RE) for quantification of BCQB in human plasma are summarized in table 1. The results showed that both intra-day and inter-day values were all within the acceptable ranges. The method was accurate and precise.

Matrix effect and recovery

The matrix effects evaluated for the QC standards at three concentration levels ranged from 98.3% to 103.3% for BCQB, suggesting no ion suppression or enhancement from the plasma matrix to the analytes. The mean recoveries, mean (RSD), of analytes at three concentration levels (3.52, 120.7, and 1006 pg/ml) were 88.2% (4.7%), 85.3% (7.0%) and 87.2% (2.8%) for BCQB, respectively. The Matrix effect and recovery of the IS were 104.0 % and 89.5% (3.0%), respectively.

Fig. 3: Typical MRM chromatograms of BCQB and IS. Blank plasma sample (A), blank plasma sample spiked with the analytes at LLOQ and IS (B), and plasma sample from a healthy volunteer at 1h after dosing (C)

Table 1: Precision and accuracy data for the analysis of BCQB in human plasma (n =5)

Analytes  Concentration level (pg/ml) RSD (%) RE (%) 
Added Measured Intra-batch Inter-batch
Low QC 3.520 3.652±0.3 8.2 5.0 3.8
Middle QC 120.7 119.1±5.5 4.6 9.1 -1.3
High QC 1006 997.1±45.1 4.5 6.2 -0.9

Table 2: Stability of BCQB in human plasma under various storage conditions (n = 3)

Storage conditions 10.06 pg/ml 1006 pg/ml
mean±SD RE (%) mean±SD RE (%)
Room temperature, 15 h 4.034±0.11 12.4 1012±25 -1.4
Auto-sampler stability, 14h 3.733±0.57 4.0 983.1±29.7 -4.2
Post-preparative stability, 48h 3.716±0.41 3.5 1030±21 0.4
Three freeze/thaw cycles 3.852±0.25 7.4 1028±10 0.2
Long term stability, 15 w 3.747±0.48 4.4 1076±14 4.9

Stability studies

The stability results summarized in table 2 revealed that BCQB was stable in the plasma sample for 15 h at room temperature and after three freeze-thaw cycles of 48 h. The analytes in processed plasma samples were stable in the auto-sampler for 14h at 15 °C. The post-preparative stability was accessed for 48h. The spiked plasma samples with BCQB stored at-20 °C for long-term stability were found stable for a minimum period of 15 w.

Application

The validated LC-MS/MS method was successfully applied to the pharmacokinetic drug interaction studies of BCQB in twenty-one healthy Chinese volunteers [15]. The pharmacokinetic results of BCQB alone and BCQB co-administered with paroxetine are presented in fig. 4. Absorption of BCQB after nasal administration was rapid with a median Tmax of 10 min in both groups. The plasma concentrations decreased in a biphasic manner with the mean t½ of approximately 10 to 11 h across the doses. The co-administration of paroxetine with BCQB decreased the elimination rate of BCQB and increased its plasma concentration at the terminal phase. The geometric mean AUC0-36 of BCQB was increased by approximately 33% during concomitant administration with paroxetine. The mean Cmax and t1/2 data showed no statistically significant difference (p>0.05). The results showed large inter-individual variability in BCQB plasma concentration; this was shown by the mean Cmax data for both treatments 240.1±186.8 pg/ml and 247.3±235.9 pg/ml, respectively.

Fig. 4: Mean plasma concentration-time profiles of BCQB after single-dose administration and co-administration with paroxetine in healthy Chinese subjects, respectively [15]

CONCLUSION

A new sensitive, accurate, selective, and simple LC-ESI-MS/MS method has been developed and validated for the quantitative determination of BCQB in human plasma. The LC-MS/MS method validated in this study was robust, reproducible, accurate, precise and reliable. The method was successfully applied for the pharmacokinetic drug interaction studies between BCQB and other drugs.

CONFLICT OF INTERESTS

The authors have declared no conflict of interest.

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