Abstracts

ARTICLE

Simultaneous determination of clobutinol hydrochloride and doxylamine succinate from syrups by RP HPLC using a new stationary phase containing embedded urea polar groups

Paulo Cesar Pires RosaI,^* * Correspondence: P.C.P. Rosa. Departamento de Ciências Exatas e da Terra, Instituto de Ciência Ambiental, Química e Farmacêutica, Universidade Federal de São Paulo - UNIFESP. Rua Prof. Artur Riedel, 275 - Jd. Eldorado, 09972-270 - Diadema - São Paulo, Brazil. E-mail: paulo.pires@unifesp.br ; Isabel Cristina Sales Fontes Jardim^II

^IDepartament of Hard and Earth Science, Institute of Environmental Science, Chemical and Pharmaceutical, Federal University of São Paulo-UNIFESP, Diadema, São Paulo

^IIDepartment of Analytical Chemistry, Institute of Chemistry, University of Campinas

ABSTRACT

A new, simple, fast, reproducible and sensitive reversed phase HPLC method, using a new stationary phase containing embedded urea polar groups, has been developed and validated for the simultaneous determination of clobutinol hydrochloride (CLO) and doxylamine succinate (DOX) in syrups. The determination was carried out on a C8 urea column (125 mm x 3.9 mm i.d., 5 µm particle size) synthetized at the Liquid Chomatography Laboratory (LabCrom) of the Chemistry Institute of Unicamp. The mobile phase consisted of a mixture of acetonitrile:methanol:phosphate buffer (pH 2.5) in the gradient mode. The diode array detector (DAD) was operated at 230 nm for CLO and 262 nm for DOX. The method showed adequate precision, with relative standard deviations (RSD) less than 1%. The presence of the excipients did not interfere in the results of the analysis. Accuracy was determined by adding standards of the drugs to a placebo and good recovery values were obtained. The analytical curves were linear (r² 0.9999 for CLO and 0.9998 for DOX) over a wide concentration range (2.4-336 µg mL^-1 for CLO and 2.3-63 µg mL^-1 for DOX). The solutions were stable for at least 72 hours at room temperature. The criteria for validation using the ICH guidelines were fulfilled.

Uniterms: Clobutinol hydrochloride/determination. Doxylamine succinate/determination. High performance liquid chromatogralhy/quantitative analysis.

RESUMO

Um novo método simples, fácil e reprodutível, de fase reversa para CLAE, usando uma fase estacionária contendo um grupo polar, uréia, embutido, foi desenvolvido e validado para determinação simultânea de cloridrato de clobutinol (CLO) e succinato de doxilamina (DOX) em xarope. A determinação foi realizada em uma coluna C8 uréia (125 mm x 3,9 mm d.i., 5 µm tamanho de partícula) sintetizada em nosso laboratório (LabCrom). A fase móvel consistiu de mistura de acetonitrila:metanol:tampão fosfato pH 2,5, em eluição por gradiente. O detector por arranjos de diodo (DAD) foi utilizado a 230 nm para CLO e a 262 nm para DOX. O método apresentou precisão adequada, com desvio padrão relativo menor que 1%. A presença de excipientes não interferiu nos resultados obtidos. A exatidão foi realizada pela adição dos padrões dos fármacos ao placebo e valores de recuperação aceitáveis foram obtidos. As curvas analíticas mostraram-se lineares (r² 0,9999 para CLO e 0,9998 para DOX) em uma ampla faixa de concentração (2,4-336 µg mL^-1 para CLO e 2,3-63 µg mL^-1 para DOX). A solução padrão foi estável por 72 horas a temperatura ambiente. Os parâmetros de validação foram realizados conforme o guia ICH.

Unitermos: Cloridrato de clobutinol/determinação. Succinato de doxilamina/determinação. Cromatografia líquida de alta eficiência/análise quantitativa.

INTRODUCTION

Clobutinol hydrochloride, (CLO), 2-(4-chlorobenzyl)-3-(dimethylaminomethyl)butan-2-ol hydrochloride, is widely used as a centrally acting cough suppressant for non-productive cough (Martindale, 1996; USP 31, 2008). It is effective and safe, at the recommended daily dose, for coughs from cancer, including advanced cancer cough (Homsi et al., 2001). Clobutinol hydrochloride is not cited in any pharmacopoeia and a literature survey reveals that the number of the analytical methods referring to the drug is relatively limited. The drug has been determined in biological fluids by gas chromatography using surface ionization detection (Ishi et al., 1993). Derivative UV spectrophotometric and high performance liquid chromatographic (HPLC) methods have also been reported (Malliou et al., 2002). Recently, a HPLC method to determine this drug together with some anti-inflammatory drugs in urine has been described (Malliou et al., 2004). A potentiometric ion-selective electrode method based on clobutinol-tetraphenyl borate has also been reported (Issa, Zayed, 2006).

Doxylamine succinate, (DOX), chemically N,N-dimethyl-2-[-methyl-(2pyridyl)benzyloxy]ethylamine hydrogen succinate, is an antihistaminic with antimuscarinic and pronounced sedative effects. It is used for treating nausea during pregnancy and it is present in over the counter cold and sedative pharmaceuticals (Sthal, 1998). Some chromatographic methods have been proposed for its determination at trace levels (Argekar, Sawant, 1999; Argekar, Sawant, 2005), mass spectrometry (Hansen et al., 1985), capillary electrophoresis (Tang et al., 2000), UV spectrometry in a micellar medium (Monferrer-Pons et al., 1996) and Fourier transform infrared spectroscopy (FTIR) (Ventura-Gayete et al., 2006) have also been used. Simultaneous determination of DOX in combination with carbinoxamine maleate by spectrophotometry (Monferrer-Pons at al., 1996), in combination with dextromethorphan hydrobromide by HPTLC (Indrayanto, 1996), in combination with pseudoephedrine hydrochloride and dextromethorphan hydrobromide by HPLC (Fong, Eickhoff, 1989), and in combination with pyridoxine hydrochloride by HPLC (Argekar, Sawant, 2005) have been reported in the literature. Simultaneous determination of DOX in combination with other antihistamines in pharmaceutical preparations by liquid chromatography with a micelar mobile phase of sodium dodecyl sulfate and pentanol (Paciolla et al., 2001; Gil-Augusti et al., 2001A), of DOX in combination with phenethylamine-antihistamine using C8, C18 or cyano columns with a micellar sodium dodecyl sulfate-pentanol mobile phase (Gil-Augusti et al., 2001B), and of DOX in combination with phenylpropanolamine hydrochloride, chlorpheniramine maleate, dextromethorphan hydrobromide, paracetamol and gaifenesin using ion pair reversed-phase by HPLC, have also been reported.

The simultaneous determination of CLO and DOX by HPLC has not been reported. The objective of this study is to develop a new, simple and fast analytical method using HPLC to quantify CLO and DOX in syrup, followed by a validation study.

EXPERIMENTAL

Material and reagents

Clobutinol hydrochloride and doxylamine succinate (Figure 1) were obtained from Forchemic d'Heuman Pharma GMBA (Germany). The standards of CLO and DOX were purchased from United States Pharmacopeia (USP). Potassium dihydrogen phosphate was obtained from J. T. Baker (Eldorado de Mexico, Mexico). Orthophosphoric acid was obtained from Mallinckrodt (Phillipsburg, USA). HPLC grade acetonitrile and methanol were purchased from J.T. Baker (Phillipsburg, USA). Water was deionized and purified by means of a Milipore Milli-Q (Bedford, MA USA). 0.45 µm nylon filters were obtained from Millipore. Syrups having clobutinol hydrochloride in combination with doxylamine succinate were purchased on the Brazilian market. A placebo, for the validation study, was prepared with the declared excipients, to verify possible interferences. These were: hydroxyethylcellulose, sodium saccaride, sodium benzoate, sorbitol, water, flavor and glycerol.

Chromatographic instrument and conditions

The HPLC system used to develop this technique was a Merck-Hitachi Elite LaChrom consisting of a quaternary pump (L-7130), degasser, column oven (L-2300) and automatic injector (L-2200). Quantification and peak purity were checked with a diode array detector (L-2450). Data acquisition was performed using the chromatography software package EZCHrom Elite, version 3.1.3. The pH meter (model 744) was from Metrohm (Herisau-Switzerland).

The chromatographic separations of CLO and DOX were performed using a 125 mm x 3.9 mm i.d. column packed with a C8 urea stationary phase containing an embedded urea (polar) group prepared in our laboratory by a modification of the procedure from preparation of stationary phases with polar groups (Silva et al., 2001, 2002, 2003). The injection volume to carry out the chromatography was set at 5 µL. The chromatographic parameters: retention factor (k), plate number (N), resolution (R_S) and tailing factor (TF) were calculated to evaluate the separation. The detector wavelengths were at 262 nm for DOX and 230 nm for CLO.

• Mobile phase

The mobile phase used in this study consisted of a mixture of acetonitrile:methanol:phosphate buffer (pH 2.5) in the gradient mode, as shown in Table I. The pH 2.5 phosphate buffer solution was prepared by dissolving 340 mg of potassium monobasic phosphate in 1000 mL of water; the pH was adjusted to 2.5 with 10% v/v orthophosphoric acid. The solvents and buffer were filtered through a 0.45 µm GH-membrane filter and degassed ultrasonically prior to use. The temperature of the column was held at 25 ºC.

Preparation of solutions

• Standard stock solutions

A standard stock solution of DOX was prepared by accurately weighing 45.0 mg of the DOX standard, dissolving it in water and diluting to 100.0 mL in a volumetric flask (0.45 mg mL^-1). A standard stock solution of CLO was prepared by accurately weighing 48.0 mg of the standard of CLO, dissolving it in 5.0 mL of acetonitrile and diluting it with water in a 100.0 mL volumetric flask (0.48 mg mL^-1).

• Working solution

A 1.0 mL volume of the stock solution prepared for DOX and a 5.0 mL volume of the stock solution of CLO were transferred to 10.0 mL volumetric flasks. The working solutions were diluted to volume with mobile phase to obtain 45 µg mL^-1 of DOX and 240.0 µg mL^-1 of CLO. An aliquot was taken and filtered through a PVDF membrane filter (0.45 µm), before injection. For the calibration solutions, aliquots of the standard stock solutions of CLO and DOX were taken in different volumetric flasks and diluted with mobile phase to obtain final concentrations in the range 2.4-336.0 µg mL^-1 for CLO and 2.3-63.0 µg mL^-1, for DOX.

• Sample solutions

A 6.0 mL volume of sample was transferred to a 100.0 mL volumetric flask, 50.0 mL of mobile phase was added and the solution was stirred for 10 minutes. After that the solution was diluted to volume with mobile phase. Appropriate proportions were taken and filtered through a PVDF membrane filter (0.45 µm) and used for the assays. To verify possible interferences, a placebo was prepared with all of excipients of the syrup and a solution was obtained from dilution of the placebo in mobile phase using the same dilution and procedures used for the preparing sample solution. Each of the solutions prepared were injected in triplicate into the chromatographic system.

Validation of method

Validation of an analytical method must demonstrate that it fulfills all the requirements of the analytical application, ensuring the reliability of the results. The validation was carried out by studying the parameters specificity, linearity, precision, sensitivity, accuracy, solution stability and limits of detection and quantification adequate for the analysis (ANVISA, 2003; ICH, 1995A; ICH, 1995B; INMETRO 2007).

System suitability

For system suitability studies, five replicate injections of the mixed standard solution were made, and parameters such as RSD of the peak area, column efficiency, resolution and the tailing factor of the peaks were calculated.

Specificity

The specificity of the method was investigated by analyzing chromatograms obtained from the placebo, mobile phase, standard and sample solutions and comparing the retention times of components of the samples to be analyzed with standards of CLO and DOX. The peak purity of CLO and DOX in the sample and in the standard preparation was also verified by comparisons of the spectra obtained with the diode array detector.

Calibration and linearity

The linearity of the method was tested in the range of 5-140% of the target level of the assay concentration of DOX (45 µg mL^-1) and from 1-140 % of the target level of the assay concentration of CLO (240 µg mL^-1). Mixed standard solutions containing 2.3-63.0 µg mL^-1 of DOX and 2.4-336.0 µg mL^-1 of CLO at each linearity point were prepared. The intervals used for linearity was 2.3, 9.0, 18.0, 27.0, 36.0, 45.0, 54.0 and 63.0 µg mL^-1 of DOX and 2.4, 24.0, 96.0, 144.0, 192.0, 240.0, 264.0 and 336.0 µg mL^-1 of CLO. Each of the levels of concentration was injected in triplicate. In simultaneous determinations, the peak area versus concentration data were performed by linear least-squares regression analysis and the analytical curves were found to be linear for both analytes in the mentioned concentrations.

Detection limit and quantitation limit

The LOD and LOQ were determined based on signal-to-noise ratios of the analytical responses at 3 and 10 times the background noise, respectively.

Precision

The precision was evaluated by intraday (repeatability) and interday (intermediate precision) studies. The intraday precision was investigated using six different sample solutions prepared from a syrup at 100% of the target level for both the analytes. Each solution was injected in triplicate and the peak areas obtained were used to calculate mean and RSD values of each ingredient. The interday precision was checked by preparing, and analyzing in triplicate, six different sample solutions from the syrup at the same concentration levels as used for intraday precision, on different days, by different analysts and/or different HPLC systems (ANVISA, 2003). The percent of the assay for the two components was calculated using the analytical curve.

Accuracy

The accuracy of the method was evaluated by recovery experiments. The recovery experiments were performed by fortifying the excipient mixture with three known concentrations of the drugs, at the levels of 80%, 100% and 120% of the target concentrations (45 µg mL^-1 of DOX and 240 µg mL^-1 of CLO). Three samples were prepared for each recovery level. The amount of DOX and CLO recovered were calculated in relation to the added amount. Each solution was injected in triplicate and peak areas were used to calculate the mean and % RSD values.

Robustness

A study of robustness was carried out by testing the susceptibility of the measurements to deliberate variations of the analytical conditions. The factors chosen for this study were the temperature (ºC), pH, flow rate (mL min^–1), mobile phase (percentage of acetonitrile), injection volume (µL), different columns dimensions.

Solution stability

To determine the stability of the standard and sample solutions of CLO and DOX, the assay method was carried out after leaving the test solutions of both sample and reference in tightly capped volumetric flasks at room temperature for 72 h. The sample solutions were assayed at 6 h intervals throughout the study period. Mobile phase stability was also analyzed by assaying the freshly prepared sample solutions against freshly prepared reference standard solutions at 6 h intervals up to 72 h. Mobile phase was kept constant during the study period.

Stability-indicating ability

A stability study is an integral part of pharmaceutical product development (ICH, 2006). The data collected during a stability study determine the shelf life, storage conditions and impurity profile of the product. If the assay method itself indicates stability, it is considered to be versatile. Therefore, an attempt was made to investigate the stability-indicating ability of the proposed method. Sample solutions containing 4.0 mg mL^-1 of CLO and 0.75 mg mL^-1 of DOX, equivalent to the concentrations found in syrups, were kept at 80 ºC; or with 1 mL of 0.1 mol L^-1 HCl; or 1 mL of 0.1 mol L^-1 NaOH; or 1 mL of 10% H₂O₂ added or in the presence of UV light, each for 24 hours. Simultaneosly, 4.0 mg of CLO and 0.75 mg of DOX in syrup, and a mixture of 4.0 mg of CLO and 0.75 mg of DOX standards were exposed to the same stress conditions. All the exposed standards and syrup samples then were analyzed by the validated method.

RESULTS AND DISCUSSION

Optimization of the chromatographic conditions

The organic solvents acetonitrile and methanol have different effects on the solvation of the analytes and therefore they also affect the symmetry and selectivity of the peaks (Argekar, Sawant, 2005). The best chromatographic condition was obtained with a mobile phase containing a mixture of 27% acetonitrile, 2% methanol and 71% buffer; this condition provided the best resolution of CLO and DOX.

Variations of the buffer concentration helped to achieve a longer retention time for DOX. A decrease in ionic strength leads to an increase in retention for DOX (Pacciolla et al., 2001). A concentration of 0.025 mol L^-1 KH₂PO₄ was the optimum concentration for the separation. A concentration less than 0.020 mol L^-1 KH₂PO₄ increased the retention of DOX and a concentration exceeding 0.030 mol L^-1 KH₂PO₄ resulted in decreased resolution between DOX, CLO and the earlier eluting excipients.

The retention times were also affected by variation of the pH of the mobile phase. In the pH range 4.0-5.5 no changes in retention for DOX were observed. At pH 2.5-4.0 several changes were observed. DOX is capable of being protonated twice, with reported pKa values of 4.0 (pyridinium group) and 9.2 (tertiary amine group). The rapid increases in retentions as the pH are due to large concentration of the dication it forms (Sa'sa et al., 1987). A buffer of pH 2.5 was chosen since provides baseline separation with sharp peaks and reasonable retention times.

The good separation between CLO, DOX and the excipients is due to the new stationary phase with embedded polar groups, which shows different selectivities and retentions for basic and polar compounds. This effect can be attributed to the weakening of the interaction between basic analytes and residual silanol groups on the silica surface (Ascah et al., 1996; O'Gara et al., 2001). Some mechanisms that have been proposed are the interaction of the polar function with the unwanted silanols through hydrogen bonding and an increase in the water concentration on the surface because of the hydrogen bonding ability of the polar groups. As a result, the surface layer should have a higher dielectric constant, weakening the interactions between residual surface silanols and basic analytes (Silva et al., 2002). Another advantage is that the phase containing embedded polar groups requires a mobile phase with a lower concentration of organic solvent (Silva et al., 2001).

The wavelengths of 263 nm and 230 nm were selected for the UV detection because at these wavelengths there was maximum absorption in the spectra of DOX and CLO, respectively.

Validation of Method

System suitability

Results of system suitability parameters are shown in Table II.

Specificity

Figure 2 shows chromatograms of standard and sample solutions. The placebo solution afforded three peaks, also observed in the sample solutions, with low retention times with no potential to interfere with the CLO and DOX peaks. In the chromatogram of mobile phase no interference was observed. The retention times of CLO and DOX were similar in the chromatograms of the standard and sample solutions.

The peak purities for CLO and DOX were 0.9993 and 0.9991, respectively, showing that the analyte peaks are pure, without the interference of analog compounds and also that the formulation excipients do not interfer with the analyte peaks.

Calibration and linearity

The correlation coefficients, linearity range and percent RSD of concentration/area ratio of the analytical curves were calculated and are in Table III.

Detection limit and quantitation limit

The LOD and LOQ are 0.65 µg mL^-1 and 2.4 µg mL^-1 for CLO and 0.62 µg mL^-1 and 2.3 µg mL^-1 for DOX, respectively.

Precision

The assay results and % RSD, calculated from the peak areas and shown in Table IV, indicate that the method is reliable.

Accuracy

The recovery values for CLO and DOX ranged from 98.4% to 100.2% and 98.8% to 99.2%, respectively. The average recovery of the three levels (nine determinations) for DOX and CLO were 99.0% and 99.3%, respectively. The results are shown in Table V.

Robustness

The results are shown in Table VI. To exemplify the use of the method, a comparation with a X-Terra C8, 150 x 4.6 mm i.d., 5 µm particle size column from Waters was carried out. The results obtained from analysis with the commercial column were similar to the chromatographic separation from the C8 stationary phase containing an embedded urea polar group.

Solution stability

The percent RSD for the assay values determined up to 72 h for the sample preparation were 0.85 for CLO and 0.76 for DOX; in the standard preparation the values were 0.85 for CLO and 0.76 for DOX. The assay values were within 2 % after 72 hours. The results indicate that the solutions were stable for at least 72 h at ambient temperature.

Stability-indicating ability

In the chromatograms of samples exposed to heat, alkali, acid and light, no degradation peaks were observed, and the assay values were not changed significantly for either ingredient. However, in the case of samples exposed to a strong oxidizing agent, H₂O₂, the assay values of both ingredients were found to decrease significantly. The peaks for CLO/DOX in the chromatograms of all exposed samples were investigated using the DAD detector and were found to be pure. These results are given in Table VII.

CONCLUSION

The proposed method is simple, precise, accurate and selective for the simultaneous determination of CLO and DOX in syrups. It can be easily and conveniently adopted for routine quality control analysis.

ACKNOWLEDGMENT

The authors acknowledge financial support from the Brazilian Agencies FAPESP (Fundação de Amparo à Pesquisa do Estado de São Paulo) and CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico). We also thank Prof. C. H. Collins for English revision.

Received for publication on 30^th November 2011

Accepted for publication on 09^th April 2012

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