TX_1~ABS:AT/TX_2:ABS~AT 24 UHD Journal of Science and Technology | July 2022 | Vol 6 | Issue 2 1. INTRODUCTION Montelukast sodium (MTK) which has the following chemical structure (Fig. 1) is considered as a good alternative to corticosteroid inhaler in treating asthma and rhinitis since it has fewer side effects [1]. MTK mechanism of action is by blocking the action of CysLT receptor Type 1 in respiratory system that results in relaxing smooth muscle and decreasing inflammation. MKT hydrophobic acidic drug that has water solubility about 0.2–0.5 µg/mL at room temperature; therefore, it is considered as Class II compound according to biopharmaceutic category system [2]. Montelukast base solubility enhanced through salt formation as sodium salt of montelukast MTK. MTK possess acidic lipophilic property with a PKa between 2.7 and 5.8 and logP 8.79 which make it soluble in higher pH media [2]. MTK is available as a tablet dosage form under the brand name of Singulair for both adult and children from age 6 months and older with no detected adverse effect [3]. Different methods have been studied to determine amount of MTK in its dosage form such as capillary electrophoresis [4], cyclic voltammetry [5], high performance liquid chromatography (HPLC) with florescence detection [6], and HPLC with ultraviolet (UV) detection [7], this study develop simple, specific, accurate, and precise method by UV-spectrophotometry and validate it according to International Council for Harmonisation (ICH) guideline, and evaluate this new method with previously published method that has the same way of determination. 2. MATERIALS AND METHODS 2.1. Instrumentation For deter mination UV double beam (Spekol 2000, analytikjena, Canada) with two identical 1 cm quartzes cell Newly Simple Quantitative Determination of Montelukast Sodium by Ultraviolet-Spectrophotometry Dlivan Fattah Aziz1, Yehia Ismail Khalil2 1Department of Pharmaceutics, College of Pharmacy, University of Sulaimani, Sulaimanyia, Iraq, 2Department of Pharmaceutics, College of Pharmacy, University of Baghdad, Baghdad , Iraq A B S T R A C T Montelukast sodium is well known pharmaceutically for its action as leukotriene antagonist and reliving symptoms associated with asthma is available in the market as tablet, chewable tablet, and powder. The aim of this study was to develop newly simple selective ultraviolet spectrophotometry (UV) method for daily routine analysis of quality control department. The UV method was developed with wavelength at 287.0 nm. This newly developed method was effectively applied to tablet dosage form of the motelukast sodium follow the Beer’s Lamberts at range 2.5–50 µg/mL. The validated parameters were carryout such as linearity, accuracy, precision, and specificity. The result of validation statistically studied and found to be satisfactory. Index Terms: Ultraviolet, Montelukast, Determination, Validation, Quantitative, Method Corresponding author’s e-mail:  Dlivan Fattah Aziz, Department of Pharmaceutics, College of Pharmacy, University of Sulaimani, Sulaimanyia, Iraq. E-mail : dlivan.aziz@univsul.edu.iq Received: 03-04-2022 Accepted: 01-08-2022 Published: 15-08-2022 Access this article online DOI: 10.21928/uhdjst.v6n2y2022.pp24-28 E-ISSN: 2521-4217 P-ISSN: 2521-4209 Copyright © 2022 Aziz and Khalil. This is an open access article distributed under the Creative Commons Attribution Non-Commercial No Derivatives License 4.0 (CC BY-NC-ND 4.0) O R I G I N A L RE SE A RC H A RT I C L E UHD JOURNAL OF SCIENCE AND TECHNOLOGY Aziz and Khalil: Quantitative Determination of Montelukast Sodium by UV UHD Journal of Science and Technology | July 2022 | Vol 6 | Issue 2 25 was used, all materials were weighed by electronic sensitive balance (Sartorius, Germany), water bath sonicator (Starsonic, Italy) used to aid dissolving solute in solvent during solution preparation. 2.2. Materials Pure MTK, lactose monohydrate, magnesium stearate, microcrystalline cellulose, and croscar melose sodium were kindly provided by PiONEER for pharmaceutical industry, Iraq. Ethanol 96% was purchased from Merck, Germany. 2.3. Standard Stock Solution and Calibration Curve Solution Preparation Stock solution of 100 µg mL-1 of active pharmaceutical ingredient (API) was prepared by dissolving 25 mg of API into 250 mL of diluent (Water: Ethanol) (1:1 V/V) sonicated for few minutes. Series solutions of the following concentration were prepared from stock solution in same the diluent (2.5, 5, 10, 15, 25, and 50 µg/mL). Each solution was read triplicate and average of each sample was put into linear graph. 2.4. Method Development Different media for dissolving MTK were evaluated to choose best solvent for API depending on solubility of MTK, stability, cost, selectivity, and toxicity. First water used as solvent then ethanol was added gradually till found that ethanol with water by 1:1 (V/V) will give clear solution. The prepared standard solution scanned and found that best absorption would be at 287.0 nm. 2.5. Stability Stability of MTK solution of calibration was determined at room temperature in day light condition for a period of 24 h by observing change in absorbance at the same wavelength. 2.6. Analytical Validation ICH (Q2) R guideline of validation of analytical procedure was applied for validating developed method as the following: 2.6.1. Precision Both interday and intraday of precision were analyzed with median concentration of API. Intraday precision was completed by evaluating the median concentration of the MTK at the Fig. 1. Chemical structure of montelukast sodium. TABLE 1: Different concentration of MTK solution at different level with corresponding absorption Linearity sample 2 zero time level Conce ug/mL abs avearge Area 50% 2.50 0.1136 0.1138666667 slope 0.04699946417 0.114 intercept 0.01064293369 0.114 r 0.9996766948 r2 0.9994 75% 5.00 0.2447 0.245 0.245 0.2449 100% 10.00 0.4784 0.4784 0.4784 0.4784 125% 15.00 0.7093 0.7093 0.7093 0.7093 150% 25.00 1.225 1.226533333 1.2273 1.2273 200% 50.00 2.3433 2.3433 2.3433 2.3433 Aziz and Khalil: Quantitative Determination of Montelukast Sodium by UV 26 UHD Journal of Science and Technology | July 2022 | Vol 6 | Issue 2 same day while interday precision was studied over consecutive days for the same concentration repeated 6 times. Evaluating precision of an analytical procedure provide statistics data on the unsystematic error. It states agreement between numbers of measurements achieved from several sampling of the same identical sample under approved conditions. The percentage of relative standard deviation (% RSD) values were studied and the low value of % RSD indicated the precisely of the analytical procedure. The value % RSD for the precision study according to ICH guideline should be <2% (interday precision) this to confirms good precision of the method. 2.6.2. Recovery Recovery was completed using the method where identified quantity of standard MTK equivalent to 75, 100, and 125% of linear concentration had been added to placebo. The samples were read 3 times and percentage amount of API was calculated at each level. 2.6.3. Linearity Calibration curve for standard MTK solution was obtained in range from 2.5 µg mL−1 to 50 µg mL−1 for MTK. Peak absorbance for each concentration must plot against respective concentrations and linear regression analysis should obtain the correlation coefficient higher than 0.999 to confirm that there is an excellent relationship between the absorbance and concentration of the samples and method have linear in response. 2.7. Statistical Analysis Basic statistical analysis was applied such as mean, standard deviation, average, and RSD% using Microsoft Excel. 3. RESULTS AND DISCUSSION This rapid technique for determination of the MTK is useful in drug analysis especially in pharmaceutical industry when time costs especially using HPLC for determination of MTK is time consuming and requires effort and high cost. Choosing the best solvent for preparing solution of MTK is a bit challenging in this study. Different solvents have been tried and found that equal volume of (water: ethanol) give clear solution, its cheap, available in almost every laboratory, and easy to use. This diluent makes this study different from other previously studies in which in most of them, Methanol 100% [8]-[10], Methanol 50% [11], [12], methanol with 0.1N NaOH [13], chloroform [14], or 7.4 pH phosphate buffer with 0.5% sodium lauryl sulfate [15] were used during solution preparation of MTK. Different wavelengths have been suggested for reading MTK standard solution in different articles such as 344.4 [11], 359 [8], 344.3 [10], 283 [9], 287.3 [15], 286.5 [13], and 280 nm [12] but in the present research when standard solution of MTK in equal mixed volume of (ethanol: water) scanned by UV absorbance to find characteristic peak at wavelength between 400 and 200 nm by 0.2 nm interval, it was found that best absorbance is at 287.0 nm at nominal concentration of 10–15 µg/mL. The suggested method was validated regarding to ICH guideline in the following aspects. 3.1. Specificity and Selectivity MTK solution of concentration 10 µg/mL in diluent was prepared in both alone and mixed with common excipient such as (lactose monohydrate, magnesium stearate, microcrystalline cellulose, and croscarmelose sodium) separately to know the interference of these excipients with API. Both solutions were scanned at wavelength between 400 and 200 nm. Method was specific and selective and there was no interference in reading between API and excipients. 3.2. Linearity For linearity, six different concentrations were prepared from lower concentration 2.5 µg/mL to higher concentration 50.0 µg/mL. Each concentration was read 3 times as shown in the Table 1. Linear relationship was observed between Fig. 2. Calibration curve of MTK at different concentration. TABLE 2: Precision of the method (n=6). Parameter Amount obtained by the proposed method in (mg) Interday Intraday Mean 10.13 10.44 SD 0.00923 0.0105 RSD% 0.91% 1.01% Aziz and Khalil: Quantitative Determination of Montelukast Sodium by UV UHD Journal of Science and Technology | July 2022 | Vol 6 | Issue 2 27 concentrations of MTK besides mean reading of absorbance at each point as it is clear in Fig. 2 the determination correlation coefficient (γ2) equal to 0.999. 3.3. Precision The method was evaluated to confirm precise in repeatability of analyzing six samples. The samples were prepared and the percentage of label claim of API of each sample was statistically evaluated. Results are shown in Table 2. The results were accepted according to acceptance criteria for assay value obtained from single analyst %RSD should be <2.0% while %RSD of two analyst performing the same samples that terminated in both days should not be more than 3.0%. 3.4. Recovery Accuracy and recovery of assay for the method was demonstrated by analyzing data achieved from standard addition into placebo solution at three levels. The amount of recovery of each sample was determined in percentage at each level and % RSD was calculated that was <2.0% shows a good accuracy of method. As it is clear in Table 3, according to ICH guidelines, good recovery of API should lie within the range of 98–102% which means the percentage recovery of API added to placebo should be in range of 100 ± 2.0% for average of three weight samples at each level. 3.5. Stability The prepared solutions were stored at room temperature 25°C, analyzed after 24 h and it was found that MTK is stable for this period of analysis in diluent. 4. CONCLUSION The validated UV method for MTK determination indicated that the method is linear, accurate, rapid, and specific. The simplicity of method allows it to be used in laboratories that have simple equipment and lack HPLC, liquid chromatography mass spectrometry, or ultra-performance liquid chromatography especially for repetitive analysis of MTK in pharmaceutical dosage form or during development of new dosage form of MTK. The current method is also useful for quantitative determination of MTK in quality control department in pharmaceutical industry. 5. ACKNOWLEDGMENT The author would like to thank PiONEER pharmaceutical industry for providing facility. REFERENCES [1] N. Kittana, S. Hattab, A. Ziyadeh-Isleem, N. Jaradat and A. N. Zaid. “Montelukast, current indications and prospective future applications”. Expert Review of Respiratory Medicine, vol. 10, pp. 943-956, 2016. [2] S. Sawatdee, T. Nakpheng, B. T. W. Yi, B. T. Y. Shen, S. Nallamolu and T. Srichana. “Formulation development and in-vitro evaluation of montelukast sodium pressurized metered dose inhaler”. Journal of Drug Delivery Science and Technology, vol. 56, pp.101534, 2020. [3] C. Cingi, N. B. Muluk, K. Ipci and E. Şahin. “Antileukotrienes in upper airway inflammatory diseases”. Current allergy and asthma reports, vol. 15, pp. 1-11, 2015. TABLE 3: Accuracy of MTK Standard Data Weight dil. Factor Conc. µg/mL Area Average Area SD RSD% 10.000 0.47840 0.4784 0.00 0.0% 0.47840 0.47840 Accuracy - recovery of MTK Level Quantity spiked µg/mL Area Quantity recovered µg/mL % recovery Average Recovery (%) %RSD 75 5.00 0.2395 5.01 100.13 100.25 0.11 0.2400 5.02 100.33 0.2399 5.01 100.29 100 10.00 0.4760 9.95 99.50 99.45 0.04 0.4757 9.94 99.44 0.4756 9.94 99.41 125 15.00 0.7105 14.85 99.01 99.04 0.04 0.7110 14.86 99.08 0.7107 14.86 99.04 Average 99.58 Aziz and Khalil: Quantitative Determination of Montelukast Sodium by UV 28 UHD Journal of Science and Technology | July 2022 | Vol 6 | Issue 2 [4] Y. Shakalisava and F. Regan. “Determination of montelukast sodium by capillary electrophoresis”. 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