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Tropical Journal of Pharmaceutical Research, Vol. 8, No. 1, February, 2009, pp. 79-86 Research Article Simultaneous quantitative determination of zidovudine and nevirapine in human plasma using isocratic, reverse phase high performance liquid chromatography Vibhuti Kabra1* , Vivek Agrahari1 , Chandrabose Karthikeyan2 and Piyush Trivedi2 1 Department of Pharmacy, Shri G. S. Institute of Technology & Science (SGSITS), Indore 452001, 2 School of Pharmaceutical Sciences, Rajiv Gandhi Technical University (RGTU), Bhopal 462036, Madhya Pradesh, India. Received: 30 July 2008 Revised accepted: 24 October 2008 Code Number: pr09011 Abstract
Purpose: To develop a sensitive and rapid reverse phase high performance liquid chromatography (HPLC) method for the measurement of the levels of zidovudine (ZVD) and nevirapine (NVP) in human plasma. Keywords: Assay, Zidovudine, Nevirapine, Human plasma, Reverse phase high-performance liquid chromatography. INTRODUCTION Major advances have been accomplished in recent years in the treatment of patients infected with human immunodeficiency virustype 1 (HIV-1). However, many patients experience treatment failure within one year after initiation of antiretroviral therapy1 . Combination therapy has now become the standard line of treatment to manage acquired immunodeficiency syndrome (AIDS)2 . The need for such a therapy has arisen due to the development of resistance by human immunodeficiency virus (HIV), to single anti-HIV drugs and also in order to minimize the dose-dependent side effects produced by these drugs3 . Many drugs have been tested for their activity against HIV-1. Nevirapine (NVP), a representative of a new class of antiretroviral drugs -the non-nucleoside reverse transcriptase inhibitors (NNRTIs) i.e., 11-cyclopropyl-5,11-dihydro-4-meth yl6H-dipyrido-[3,2-b:2,3 e] [1,4] diazepin-6-one, and zidovudine (ZVD), i.e., 3-azido-3deoxythymidine, are synthetic nucleoside analogues used for the treatment of HIV infections (Fig. 1). Several multi-drug high-performance liquid chromatography (HPLC) assays that measure a number of NNRTIs have been described in the literature in recent years. Numerous analytical methods, such as HPLC with UV detection, mass spectrometry detection and immunoassay, have been reported for ZVD and NVP but they either use a gradient method for separation or a complicated liquidliquid extraction method for preparation of plasma samples and also often involve complicated chromatography techniques. In the literature, numerous methods to individually quantify zidovudine4-7 and nevirapinehave8-11 been described. A few methods to estimate zidovudine and nevirapine simultaneously have also been reported12–17 . Some of these methods used liquid–liquid12-14 and solid phase extraction procedure for the extraction of the drugs from plasma15–17 . This could increase the time and cost of the assay. However, a combination of several characteristics makes this assay a unique and a useful analytical tool for quantification of these drugs. The objective of this work was to devise a simultaneous technique for the quantitative evaluation of zidovudine (ZVD) and nevirapine (NVP) in human plasma which involves rapid protein precipitation extraction and based on simple chromatographic conditions with detection at a single wavelength (246 nm) over a short run time. EXPERIMENTAL Reagents and chemicals Zidovudine and nevirapine were kindly provided by Ranbaxy Laboratories Ltd, Dewas, (M.P.), India. Methanol and acetonitrile were of HPLC grade and purchased from Merck Ltd, New Delhi, India. Water used was of HPLC grade water (Mili Q Water) was purchased from Ranbaxy Laboratories Ltd, (New Delhi, India). Human plasma was obtained from Blood Bank Department, Bhopal Memorial Hospital & Research Centre, Bhopal, (M.P.), India. All other chemicals were of analytical grade and used without further purification. Instrumentation The HPLC system (Shimadzu, Japan) consisted of a LC-10AT VP pump, a SPD-10A VP, PDA detector, a Phenomenex, Luna C18 (250mmX4.6mm, 5µm) column, a Phenomenex, HPLC guard cartridge system and a Class LC10/M10A software. Chromatographic conditions The chromatographic analysis was performed at ambient temperature on a Phenomenex LUNA analytical column with a mobile phase composed of water (pH 3.0, adjusted with orthophosphoric acid): acetonitrile (73:27, v/v) and was isocratically eluted at a flow rate of 0.9 mL min-1 . A small sample volume of 20 µL was used for each sample run, being injected into the HPLC system. The chromatogram was monitored with UV detection at a wavelength of 246 nm. Preparation of the calibration standards, mixed standard and quality control (QC) samples Standard stock solutions were prepared by dissolving 60 mg of ZVD and 40 mg of NVP in 100 mL of methanol to obtain final concentrations of 600 and 400 µg mL-1 for ZDV and NVP, respectively (stock-A). From this stock, 1 mL was taken and diluted to 10 mL-1 with methanol to give 60 µg mLof ZVD and 40 µg mL-1 of NVP standard solutions, respectively (Stock-B). Aliquots of stock-B were further diluted to obtain different concentrations: 300, 600, 1800, 3000, 4800, 6000, 7800, 9600 ng mL-1 for ZDV and 200, 400, 1200, 2000, 3200, 4000, 5200, 6400 ng mL-1 for NVP. To prepare standard spike plasma stock solutions, 1 mL was taken from stock-A, and diluted to 10mL with blank plasma to give 60 µg mL-1 of ZVD and 40 µg mL-1 of NVP (stock-C). From the working standard solution stock-C, different concentrations were prepared by taking 0.1, 0.2, 0.4, 0.6, 0.8, 1.2, 1.6, and 1.8 mL, and then the volume was made up, in each case, to 2 mL with blank plasma. For all the concentrations, 8 mL of precipitating agent (methanol) was added to obtain the final concentrations of 300, 600, 1800, 3000, 4800, 6000, 7800, 9600 ng mL-1 for ZVD and 200, 400, 1200 2000, 3200, 4000, 5200, 6400 ng mL-1 for NVP. QC samples at three different levels of HQC (high quality control, 6000/4000 ng mL-1 ), MQC (medium quality control, 3000/2000 ng mL-1 ), LQC (low quality control, 600/400 ng mL-1 ) and LLOQ (lowest limit of quantitation, 300/200 ng mL-1 ) for ZVD and NVP, respectively, were selected to perform different validation parameters. Sample pretreatment and extraction procedure Drugs were extracted from plasma samples using a protein precipitation technique. Methanol was selected as the precipitating agent. Each plasma sample gave satisfactory values for recovery with a single extraction. The satisfactory result was obtained when 1:4 ratios of plasma and methanol were mixed thoroughly, vortexed at room temperature and centrifuged at 12000 rpm for 10 min at 4°C. The clear supernatant liquid was decanted, filtered through a 0.45 µm syringe filter and injected (20 µL) into HPLC system. Limit of detection (LOD) and lowest limit of quantification (LLOQ) The limit of detection (LOD) was defined as the concentration that yields a signal-to-noise ratio of 3. The lowest limit of quantification (LLOQ) was calculated to be the lowest analyte concentration that could be measured with a signal-to-noise ratio of 10. To determine LLOQ and LOD, plasma samples were spiked with decreasing concentrations of the analytes and analyzed. The LLOQ and LOD were observed 300 and 63 ng mL-1 for ZVD while for NVP the values were 200 and 17 ng mL-1 , respectively. Linearity of method Calibration plots for the analytes in plasma were prepared by spiking drug-free plasma with standard stock solutions to yield concentrations of 300-9600 ng mL-1 for ZVD and 200-6400 ng mL-1 for NVP. The solutions were injected in replicates (n = 5) into the HPLC column while keeping the injection volume constant (20 µL). Calibration curves were constructed by using ratios of the observed analyte peak area versus concentration of analyte. Intercept, slope and correlation coefficient (r2 ) were determined by linear regression data analysis, which were then used to calculate the analyte concentration in each sample. Precision and accuracy of method The inter-day, intra-day, analyst to analyst precision and accuracy of the assay were determined by assaying three QC samples and LLOQ in replicates (n = 5) for each drug. Precision was reported as percent relative standard deviation (% RSD) and accuracy was as % nominal concentration and % bias. Recovery of zidovudine and nevirapine from plasma Recovery from plasma was determined for QC samples of each drug by comparing the peak area of each analyte after extraction with the respective non-extracted standard solutions at the same concentration. The percentage of the drug recovered from the plasma samples was determined by comparing the peak height ratio after extraction with those of unextracted sample containing same concentrations of the drugs as in plasma. Selectivity Selectivity is the ability of an analytical method to differentiate and quantify the analyte in the presence of other components in the sample. To evaluate the selectivity of the assay, blank samples of the appropriate biological matrix (plasma) were prepared from six different sources. Stability of method Stability of drugs in biological fluids is a function of the sample storage conditions, chemical properties of the drug, matrix and the container system18 . Blank samples were spiked with appropriate aliquots of diluted ZVD and NVP stock solutions to prepare LQC and HQC samples. The stability of drugs was evaluated under conditions likely to be encountered during actual sample handling and analysis. These samples were kept to evaluate different stability parameters such as stock solution stability (SSS, 6 h at room temperature), bench top stability (BTS, 12 h at room temperature), post processing stability (PPS, over the maximum time, i.e., from the completion of sample work-up to the completion of data collection), freeze and thaw stability (FTS, subjected to three freeze–thaw cycles of -20°C during 24 h) and longterm storage stability (LTS, subjected to freeze storage at -20°C during the entire period covered by the bioanalytical study, i.e., from the first day of sample preparation to the last day of sample analysis). For each concentration and storage conditions three replicates were analyzed. The concentration of ZVD and NVP after each storage period was related to the initial concentration as determined for the samples that were freshly prepared and processed immediately. RESULTS At the chromatographic conditions selected for this method, the retention time for blank plasma (Fig. 2) and extracted peaks of ZVD and NVP (Fig. 3) were 2.7 ± 0.3 min, 5.2 ± 0.3 min and 9.5 ± 0.3 min, respectively. The correlation coefficients for the linearity of the present method were 0.9997 and 0.9995 for ZVD and NVP respectively. The lowest limit of quantification and limit of detection were found to be 300 and 63.0 ng mL-1 and 200 and 17.0 ng mL-1 for ZVD and NVP, respectively. The recovery of the extraction procedure for ZVD was 95.39 %, 94.01 % and 89.51 % while for NVP, it was 94.93 %, 93.26 % and 92.13 % for HQC, MQC & LQC, respectively (Table 1). The accuracy (% nominal conc.) for HQC, MQC, LQC and LLOQ, samples were found to be in the range 93.42 to 109.79 and 89.04 to 105.15 for ZVD and NVP, respectively. The accuracy data are shown in the Table 1 and were well within the acceptance limit. The precision data for HQC, MQC, LQC & LLOQ samples were analyzed in replicates (n = 5) (Table 1). For intra-day, it was 1.47 to 8.59 % and 2.42 to 7.15 % for ZVD and NVP, respectively. For inter-day, the range was 1.93 to 9.38 % and 1.35 to 8.98 %, for ZVD and NVP, respectively, while for analyst to analyst precision, it was in the range 0.68 to 5.94 % and 1.79 to 6.82 % for ZVD and NVP, respectively. The stability test results (% change) for ZVD at 6000 and 600 ng mL-1 were [(4.94 and 1.13 for SSS), (-2.23 and -7.52 for BTS), (5.21 and -3.23 for PPS), (3.51 and -5.43 for FTS), (8.28 and 6.26 for LTS)] and for NVP at 4000 and 400 ng mL-1 , they were [(2.83 and -5.31 for SSS), (6.25 and -1.63 for BTS), (-9.69 and 1.11 for PPS), (8.95 and 5.49 for FTS), (11.97 and -0.51 for LTS)] as illustrated in Table 2. The result of % change demonstrates that stability testing of ZVD & NVP were within the acceptance range of ± 15% deviation from the nominal concentration. DISCUSSION The present study describes a sensitive, accurate, and reproducible HPLC method for the determination of ZVD and NVP in human plasma. Here, we used a simple protein precipitation with a small quantity of plasma and precipitating agent, which considerably reduced the sample processing time. There is no need to use an internal standard as recovery of the method was found to be more than 90 %. The mobile phase used in this study was economical, simple and the assay was entirely isocratic involving only two stable solvent components, water and acetonitrile; thus the chances of column damage were negligible, which gives the column a longer life span. In order to obtain the most suitable wavelength for the detection of ZVD and NVP, a UV spectrum was obtained. The UV spectrum revealed that maximum absorbance peaks were 266 nm for ZVD and 283 nm for NVP but the selected wavelength was 246 nm. Although this was not the maximum absorption wavelength for either of the drugs, it, nevertheless, provided good signal to noise ratio and selectivity. The retention time for ZVD and NVP were 5.2 ± 0.30 min & 9.5 ± 0.30 min, respectively. Blank plasma samples did not give any peak at the retention time of these drugs. The
LLOQ value, 300 and 200 ng mL-1 for ZVD and NVP, respectively, allowed us to avoid the use of expensive and sensitive detectors. The calibration curve derived from eight different concentration points ranging from 300 to 9600 ng mL-1 for ZVD and 200 to 6400 ng mL-1 for NVP, showed a linear relationship between area under curve (AUC) and concentration. The mean extraction recovery of 92.97 % for ZVD and 93.44 % for NVP is satisfactory since no comprehensive method of extraction was used. The accuracy and precision data are well under the acceptance limit (± 20% for LLOQ, and ± 15% for LQC, MQC and HQC). The stability data of analytes show that the drugs are stable in plasma under the varying conditions of the tests. CONCLUSION A simple, sensitive, isocratic, reverse phase HPLC-UV assay was developed and validated for the simultaneous analysis of zidovudine and nevirapine in human plasma. The small volume plasma sample preparation involved rapid protein precipitation extraction, making it widely applicable for HIV clinical therapeutic drug monitoring programs. The results of this study indicates that the method would be applicable to toxicokinetic, pharmacokinetic, bioavailability, and bioequivalence studies.This HPLC method should also be useful for analyzing plasma concentrations of the drugs evaluated as well as pharmacokinetic parameters in HIV-infected patients for the purpose of evaluating clinical pharmacology and clinical therapeutic drug monitoring (TDM) programs for these drugs in HIV studies. ACKNOWLEDGEMENT This work was supported by grants from the Ministry for Human Resource Development (MHRD), New Delhi, India. The authors are grateful to Professor PB Sharma (Vice Chancellor, RGPV, Bhopal, Madhya Pradesh, India) for providing laboratory facilities, and to the Blood Bank Department, Bhopal Memorial Hospital & Research Centre, Bhopal, Madhya Pradesh, India, for providing plasma samples. REFERENCES
© Pharmacotherapy Group, Faculty of Pharmacy, University of Benin, Benin City, 300001 Nigeria. The following images related to this document are available:Photo images[pr09011f3.jpg] [pr09011t2.jpg] [pr09011f2.jpg] [pr09011t1.jpg] [pr09011f1.jpg] |
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