Development and Validation of a Stability-Indicating LC Method for the Simultaneous Estimation of Levodropropizine, Chloropheniramine, Methylparaben, Propylparaben, and Levodropropizine Impurities Academic research paper on "Chemical sciences"

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Research article

Development and Validation of a Stability-Indicating LC-Method for the Simultaneous Estimation of Levodropropizine,

Chlorpheniramine, Methylparaben, Propylparaben, and Levodropropizine Impurities

Palakurthi Ashok Kumar * 1, Thummala Veera Raghava Raju 1, Dongala Thirupathi 1, Ravindra Kumar 1, Jaya Shree 2

Analytical Research and Development, Integrated Product Development, Dr. Reddy's Laboratories Ltd., Bachupally, Hyderabad-500 072, India.

2 Centre for Chemical Science and Technology, J. N. T. University, Kukatpally, Hyderabad, A.P., India.

* Corresponding author. E-mail: ashokchem2000@gmail.com (P. A. Kumar)

Sci Pharm. 2013; 81: 139-150 doi:10.3797/scipharm.1210-18

Published: November 17th 2012 Received: October 18th 2012

Accepted: November 17th 2012

This article is available from: http://dx.doi.org/10.3797/scipharm.1210-18

© Kumar et al.; licensee Österreichische Apotheker-Verlagsgesellschaft m. b. H., Vienna, Austria.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract_

A simple, fast, and ef ficient RP-HPLC method has been developed and validated for the simultaneous estimation of Levodropropizine, Chlorpheniramine, Methylparaben, Propylparaben, and the quantification of Levodropropizine impurities in the Reswas syrup dosage form. A gradient elution method was used for the separation of all the actives and Levodropropizine impurities by using the X-Bridge C18, 150 mm * 4.6 mm, 3.5 ^m column with a flow rate of 1.0 mL/min and detector wavelength at 223 nm. The mobile phase consisted of a potassium dihydrogen orthophosphate buffer and acetonitrile. All the peaks were symmetrical and well-resolved (resolution was greater than 2.5 for any pair of components) with a shorter run time. The limit of detection for Levodropropizine and its Impurity B was 0.07 ^g/ml & 0.05 Mg/ml, whereas the limit of quantification was 0.19 ^g/ml & 0.15 ^g/ml respectively. The m ethod was validated in terms of precision, accuracy, linearity, robustness, and s pecificity. Degradation products resulting from the stress studies were well-resolved and did not interfere with the detection of Levodropropizine, Chloropheniramine, Methylparaben, Propylparaben, and Levodropropizine Impurity B, thus the test method is stability-indicating.

Validation of the method was carried out as per International Conference on Harmonization (ICH) guidelines.

Keywords

L-Dropropizine • Chlorpheniramine • HPLC • ICH Guidelines • Development • Validation Introduction

Levodropropizine (LDP), a phenylpiperazinopropane derivative, is a non-opioid antitussive agent. Chemically, levodropropizine is (2S)-3-(4-phenylpiperazin-1-yl)propane-1,2-diol and is the 'levo'-isomer of dropropizine. Levodropropizine has been proven to be an effective antitussive against non-productive cough associated with different lung pathologies [1]. Chlorpheniramine (CP) is a first-generation antihistamine belonging to the class of alkylamines. It is used in the prevention of symptoms of allergic conditions such as rhinitis and utricaria. Its sedative effects are relatively weak compared to other first-generation antihistamines. It is used not only for the treatment of cough, but also for other related allergy symptoms such as sneezing, itchy and/or watery eyes, itchy nose or throat, and runny nose caused by hay fever (allergic rhinitis), or other respiratory allergies. Methylparaben (MP) and Propylparaben (PP) are the preservatives used to prevent decomposition by microbial growth or by undesirable chemical changes. Preservatives can desirably be incorporated into the composition to protect against the growth of potentially harmful microorganisms. Microorganisms tend to grow in an aqueous phase, so to prevent their growth, a preservative has to be ad ded to the pharmaceutical composition. The chemical structures of all the actives are shown in Fig. 1.

Levodropropizine LDP

(2S)-3-(4-phenylpiperazin-1-yl)propane-1,2-diol

Chlorpheniramine CP

3-(4-chlorophenyl)-W,W-dimethyl-3-(pyridin-2-yl)propan-1-amine

Methylparaben MP

methyl 4-hydroxybenzoate

Propylparaben PP

propyl 4-hydroxybenzoate

Fig. 1. Structures and IUPAC names of LDP, CP, MP, PP

The objective of this work is to develop and validate a s imple, precise, and accurate stability-indicating HPLC method for the estimation of LDP, CP, MP, PP, and Impurity B of LDP with a shorter run time. Literature surveys revealed that there is no HPLC method for the simultaneous determination of LDP, CP, MP, PP, and Impurity B of LDP. Several analytical methods such as liquid chromatography with a UV spectrophotometer [2-7], have been reported for the determination of LDP and CP individually. According to the literature [8], Levodropropizine has three impurities: Impurity A (Dextropropizine), Impurity B (1-Phenylpiperazine), Impurity C (Glycidol). Impurity A & C were estimated by the normal-phase-HPLC & GC respectively. Impurity B and any other unknown impurities were estimated by the RP-HPLC method.

Experimental

Chemicals, reagents, and samples

LDP Impurity B was obtained from Spectro Chem. India PVT Ltd. LC grade potassium dihydrogen orthophosphate and 1-Hexanesulphonic acid sodium salt, methanol, and acetonitrile were purchased from Merck India Limited. Pure water was prepared by using a Millipore Milli-Q Plus Water Purification System (Bedford, MA, USA).

Equipments

The LC system was a Waters model 2996 equipped with a PDA Detector (Waters Corporation, Milford, USA). The output signal was monitored and pro cessed using Empower software (Waters Corporation, Milford, USA) on a Pentium computer (Digital Equipment Co.).

Chromatographic conditions

The chromatographic column X-Bridge C18 column (150 x 4.6) mm with 3.5^m particles was used. Mobile phase-A consisted of a mixture of 0.025M aqueous potassium dihydrogen orthophosphate buffer and 0.005M 1-Hexanesulphonic acid sodium salt buffer. Mobile phase-B consisted of a mixture of water and acetonitrile (10:90, v/v). The mobile phase was filtered through a 0.45 ^m nylon membrane filter. The flow rate of the mobile phase was 1.0mL/min with a column temperature of 40°C and the detection wavelength at 223nm. The injection volume was 10^L. A water and methanol (80:20, v/v) mixture was used as a diluent during the preparation of the standard and s ample. The LC gradient programme is as follows:

Time %A %B Time %A %B

0 min 80 20 12 min 90 10

5 min 45 55 13 min 80 20

10 min 90 10 16 min 80 20

Preparation of Standard

CP and PP stock preparation

0.4 mg/mL of CP and 0.2 mg/mL of PP solution were prepared in methanol.

LDP and MP stock preparation

6.0 mg/mL of LDP and 2.0mg/mL of MP solution were prepared in methanol. Standard preparation (For assay)

10mL of each of the above two stock solutions were transferred into a 100mL volumetric flask and diluted to volume with water and mixed well.

Standard preparation (For impurities)

0.3 mg/mL of the LDP standard solution was prepared in diluent. Then 1.0mL of this solution was further transferred to a 100mL volumetric flask and di luted to volume with diluent and mixed well.

Sample Preparation

About 10mL of the syrup was weighed and transferred into a 100 mL volumetric flask, to which was added about 70m L of diluent. It was then sonicated for 5m in and diluted to volume with diluent and mixed well.

Results and Discussion

Optimization of chromatographic conditions

The main difficulty in this study was to get symmetrical peaks for all the actives and better separation between LDP Impurity B and LDP in a single method without any interference. The presence of the amine group functionality in LDP and CP led to peak tailing. Initially as part of the method development, different stationary phases like C8, C18 were tried by using the gradient elution method with a phosphate buffer and found that the peak shapes were not symmetrical (more tailing observed). Different ionic strengths (ranging from 0.025M to 0.1M) were employed with phosphate, acetate, perchlorate, and formic acid buffers to reduce the peak tailings, but the ionic strength did not play any role in peak tailing. From the above experiments, it was observed that getting a symmetrical peak for the LDP buffer played a role and for CP, MP, and PP the organic phase played a role. We tried different gradient programmes by increasing the organic phase, where LDP and LDP Impurity B were merging.

We further tested different chromatographic parameters like column temperature (40°C to 60°C), column particle size (5^m & 3.5^m), pH (3.5 to 7.5) of buffer, and ion pair reagent incorporation in the mobile phase buffer to improve peak shapes and resolution. Finally, the chromatographic separation was achieved by a reverse phase X-Bridge C18 150 x 4.6 mm, 3.5^m particle size column operated at 40°C with gradient elution at 1.0 mLmin-1 using mobile phase A as a m ixture of 0.025M aqueous potassium dihydrogen orthophosphate and 0.005M 1-Hexanesulphonic acid sodium salt in 1000ml water. Mobile phase B consisted of a mixture of water and acetonitrile (10:90, v/v). The detection wavelength was at 223nm and the injection volume was 10^L. The LC gradient program was set as: time (min)/% mobile phase B: 0.01/20, 5/55, 10/10, 12/10, 13/20, and 16/20. All the peaks (including active, blank, and the Impurity) were well-separated with a resolution greater than 2.5. No chromatographic interference was observed due to the blank (diluent) and other excipients (placebo) at the retention time of the active peaks and their impurities. Typical chromatograms are shown in Fig. 2-5.

Fig. 2. A typical chromatogram of the blank

Fig. 3. A typical chromatogram of the assay standard

*lo tis

Fig. 4. A typical chromatogram of the Impurity-spiked sample

Fig. 5. A typical overlaid zoomed chromatogram of the blank and spiked sample

Establishment of Relative Response Factor for LDP Impurity B

We prepared and injected a series of solutions consisting of LDP Impurity B and LDP in the range of 0.4% to 1.2% (0.4%, 0.6%, 0.8%. 1.0%, 1.2%). The load of 10 Ml injection volume of the sample was injected into the liquid chromatograph and we then calculated the Relative Response Factor (RRF) of LDP Impurity B with respect to LDP from the calibration curve data. The R RF value of LDP Impurity B was found to be 1.26. The Relative Retention Time (RRT) of LDP Impurity B was found to be 1.1

Method Validation

After satisfactory development of the method, it was subjected to method validation as per ICH guidelines [9]. The m ethod was validated to demonstrate that it is suitable for its intended purpose by the standard procedure to evaluate adequate validation characteristics (system suitability, specificity, accuracy, precision, linearity, robustness, ruggedness, solution stability, LOD and LOQ, and stability-indicating capability).

Specificity, linearity, precision, accuracy, robustness, and ruggedness were done as a part of the method validation.

Tab. 1. The results table for System Suitability of the Assay standard

Component Tailing factor USP plate count % RSD

Levodropropazine 1.3 16364 0.7

Methylparaben 1.0 28198 0.7

Chlorpheniramine 1.2 254055 0.8

Propylparaben 1.1 21567 0.8

System suitability

The system suitability parameters (Table 1) were evaluated by making the injection of the assay standard and the RS standard. The system was deemed to be suitable as the tailing factors for all the peaks were between 0.8 to 1.5 and the resolution between LDP and LDP Impurity B was >2.5.

Specificity

In order to determine whether the developed analytical method was stability-indicating, Reswas syrup and the LDP active pharmaceutical ingredient (API) was stressed under various conditions to conduct forced degradation studies. LDP is very soluble in water. The specificity was examined by analyzing the solution of a placebo, which consisted of all the excipients as per ICH guidelines [9]. The degradation study conducted for Levodropropizine used stress conditions like UV light, sunlight, thermal stress, water hydrolysis, acid hydrolysis, base hydrolysis, oxidation and humidity. The acidic, basic, and oxidative stress condition studies were carried out by refluxing the syrup for 6hours with 5N HCl, O.INNaOH, and 3% hydrogen peroxide respectively. The thermal stress was carried out by heating the drug product to 105°C for 24hours and the photodegradation was performed by exposing the drug product to 1.2million lux hours and 200 watt hours/m2 in a photostability chamber. It is interesting to note that all the peaks due to degradation were well-resolved. The chromatograms of the stressed samples were evaluated for peak purity using Waters Empower Networking Software. For all forced degradation samples, the purity angle was found to be less than the threshold angle and there was no purity flag for the LDP and its impurities. This confirms the stability-indicating power of the developed method. The results of the forced degradation study are shown in Table 2.

Tab. 2. The results table for the specificity of Levodropropazine

Sample Stress Purity Purity Purity

No. Conditions angle threshold flag

1 As such sample 1.135 3.215 NO

2 Acid stress 0.899 3.371 NO

3 Base stress 1.079 3.282 NO

4 Oxidation stress 0.718 1.250 NO

5 Sunlight stress 1.023 3.125 NO

6 UV light stress 1.158 3.098 NO

7 Thermal stress 0.963 3.264 NO

8 Humidity stress 1.564 3.598 NO

9 Water stress 1.132 3.201 NO

Precision

The precision of the test method was evaluated by analyzing six samples of Reswas syrup by spiking the LDP Impurity B at a target concentration level (i.e. 0.5%) with respect to the test concentration of LDP (0.6mg/mL). The % R.S.D of LDP, LDP Impurity B, MP, CP, and PP from six sample preparations was found to be below 2.0 which indicates the precision of the method for the quantification of LDP, LDP Impurity B, MP, CP, and PP. The results are shown in Table 4.

Tab. 3. The results table for the specificity of Levodropropazine Impurity B

Sample Stress Purity Purity Purity

No. Conditions angle threshold flag

1 As such sample 0.566 0.792 NO

2 Acid hydrolysis 0.614 0.785 NO

3 Base hydrolysis 0.610 0.674 NO

4 Oxidation 0.645 0.831 NO

5 Sunlight stress 0.592 0.801 NO

6 UV light stress 0.621 0.798 NO

7 Thermal stress 0.658 0.804 NO

8 Humidity stress 0.603 0.765 NO

9 Water hydrolysis 0.575 0.691 NO

Tab. 4. The results table of the precision of the test method

Component Average %RSD

% Assay of Levodropropazine 102.3 1.0

% of LDP IMP B 0.49 2.6

% Assay of Methylparaben 100.5 1.1

% Assay of Chlorpheniramine 100.9 1.7

% Assay of Propylparaben 96.2 1.1

Limit of detection and quantification

A series of different concentrations of LDP and LDP Impurity B solutions was prepared in diluent. The l imit of detection and l imit of quantification were established based on a signal-to-noise ratio. The LOQ concentrations for LDP & LDP Impurity B were found to be 0.032% & 0.025%. Concentrations at the LOD and LOQ levels are reported in Tab. 5.

Tab. 5. LOD and LOQ of LDP and LDP IMP B

Name of the _Test Name_S/N Ratio % at

component Conc. at LOD Conc. at LOQ lod LOQ LOQ _(pg/ml)_(pg/ml)_

LDP 0.07 0.19 3.15 10.32 0.032

LDP IMP B 0.05 0.15 3.30 9.91 0.025

Linearity

The linearity of LDP and LDP Impurity B was conducted from the LOQ level to 150% and for MP, CP, PP it was conducted from 50% to 150% of the target concentration (0.6mg/mL, 0.04mg/mL, 0.2mg/mL & 0.02mg/mL for LDP, CPM, and MP & PP respectively). The l inearity graphs were plotted for concentration (%) versus detector response (area). The c orrelation coefficient for all the peaks was found to be 0. 999. Linearity plots are shown in Fig. 6 to Fig. 10.

Fig. 6. Linearity of Detector Response of LDP

Fig. 7. Linearity of Detector Response of LDP IMP B

Fig. 8. Linearity of Detector Response of MP

Fig. 9. Linearity of Detector Response of CP

Propylparaben

280000 -

| 230000

!■ 180000

SL 130000 ra

I 80000

50 70 90 110 130 150 170

Conc(%)

Fig. 10. Linearity of Detector Response of PP

Accuracy

The accuracy study for LDP and LDP Impurity B was conducted from the LOQ level to 150% and for MP, CP, PP it was conducted from 50% to 150% by spiking the APIs of LDP, CP, MP & PP and LDP Impurity B at different levels starting from the LOQ to 150% of the target concentration level (i.e. 0.6mg/mL, 0.04mg/mL, 0.2mg/mL, 0.02mg/mL & 0.003mg/mL, for LDP, CP, MP, PP & LDP Impurity B respectively). % recovery of LDP, CPM, MP, PP & LDP Impurity B was found to be between 95% to 105%. Results are tabulated in Table 6.

Tab. 6. The results table of the Accuracy of the test method

Spike Levo-level dropropazine

LDP IMP B

Methylparaben

Chlorpheniramine

Propylparaben

Mean %RSD Mean %RSD Mean %RSD Mean %RSD Mean %RSD

LOQ% 0.032 1.4 0.025 1.1 NA NA NA NA NA NA

50% 102.3 0.1 0.234 0.9 100.9 0.2 102.4 0.4 99.2 0.4

75% 102.4 0.4 0.352 1.6 100.3 0.4 103.9 0.7 100.2 0.4

100% 101.2 0.4 0.540 1.6 99.2 0.4 104.5 0.3 99.2 0.3

125% 100.0 0.4 0.648 0.9 98.5 0.3 104.0 0.2 98.4 0.4

150% 98.4 0.2 0.734 1.5 99.2 0.1 105.2 0.2 99.9 0.2

Robustness

The robustness was investigated by varying the conditions with respect to a change in the flow rate, column temperature, and acetonitrile composition in mobile phase B. The study was conducted at the different flow rates of 0.8ml/min and 1.2ml/min instead of 1.0ml/min to study the effect of the change in flow rate. The column temperature was adjusted to 35°C and 45°C instead of the 40°C initial column oven temperature. The organic phase composition (acetonitrile) was studied from 90% to 110% in mobile phase B to study the effect of the organic phase composition variation in the mobile phase. The method was found to be robust with respect to flow rate, column temperature, and organic phase composition without any changes in system suitability parameters such as tailing factor and resolution (Table 7).

Tab. 7. System suitability results from robustness

Parameter

Flow rate (ml/min)

Column temperature

_(°C_

Organic phase (ACN) variation (±10%)

0.8 1.0 1.2 35 40 45 90 100 110

Tailing factor for LDP peak 1.5 1.3 1.5 1.2 1.3 1.2 1.2 1.3 1.2

Resolution between LDP& LDP IMP B 3.4 3.4 3.6 2.8 3.4 2.8 2.8 3.4 2.8

Tailing factor for MP peak 1.0 1.0 1.0 1.1 1.0 1.1 1.1 1.0 1.1

Tailing factor for CP peak 1.2 1.2 1.2 1.1 1.2 1.1 1.1 1.2 1.1

Tailing factor for PP peak 1.0 1.0 1.0 1.0 1.0 1.1 1.0 1.0 1.0

Conclusion

A simple, selective, gradient mode high-performance liquid chromatographic method provides the selective quantification of LDP, LDP Impurity B, MP, CP, and PP without interference from the blank, placebo, and any other degradants, thereby affirming the stability-indicating nature of the method. The pr oposed method is highly selective, reproducible, specific, and rapid. This developed method can be applied successfully to the quality control of commercial and routine analysis. The information presented herein could be very useful for monitoring the quality of bulk samples as well as checking the quality during stability studies.

Acknowledgement

The authors wish to thank the management of Dr. Reddy's group for supporting this work.

Authors' Statement

Competing Interests

The authors declare no conflict of interest.

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