|Year : 2015 | Volume
| Issue : 2 | Page : 74-78
A green analytical method for the simultaneous analysis of cefixime trihydrate and ambroxol HCl based on ultraviolet derivative spectroscopy
Ceema Mathew1, Suman Naik Bhukya1, Ajitha Makula2, R Sathesh Babu Puvvadi1
1 Department of Pharmaceutical Analysis, Gokaraju Rangaraju College of Pharmacy, Osmania University, Hyderabad, Telangana, India
2 Institute of Science and Technology, Jawaharlal Nehru Technological University, Hyderabad, Telangana, India
|Date of Web Publication||7-Aug-2015|
Gokaraju Rangaraju College of Pharmacy, Bachupally, Hyderabad - 500 090, Telangana
Source of Support: None, Conflict of Interest: None
Context: Until date, there is no reported derivative spectrophotometric method for the combination of cefixime trihydrate (CEF) and ambroxol HCl (ABH). So an urgent need was felt to develop an ultraviolet (UV) derivative spectroscopic method, which reduces the cost of analysis on comparing with high-performance liquid chromatography or high-performance thin layer chromatography method. Aims: To develop and validate an economical and ecofriendly derivative spectroscopic method that avoids the use of organic solvents for simultaneous quantification of both the drugs. Materials and Methods: A simple method based on the derivative spectrophotometric method at zero crossing wavelengths has been developed for the simultaneous quantification of CEF and ABH. As the method depends on hydrotropic dissolution, 0.1N urea is used as the solvent, and it yields an economical and ecofriendly method. Two wavelengths 253 nm (zero crossing point (ZCP) for CEF) and 306 nm (ZCP for ABH) were selected for the quantification of ABH and CEF respectively. Results: The first derivative amplitude-concentration plots were linear over the range of 5-35 μg/ml and 3-10.5 μg/ml with detection limits of 0.187 and 0.0937 μg/ml and quantification limits of 0.625 and 0.312 μg/ml for CEF and ABH respectively. The percentage recovery was within the range between 99.05% and 102%. The % relative standard deviation for precision and accuracy of the method was found to be <2%. Conclusion: The proposed method was found to be simple, accurate and precise and can be successfully applied to the routine quality control analysis of studied drugs in their tablet formulations.
Keywords: Ambroxol HCl, cefixime trihydrate, derivative spectrophotometry, hydrotropy
|How to cite this article:|
Mathew C, Bhukya SN, Makula A, Puvvadi R S. A green analytical method for the simultaneous analysis of cefixime trihydrate and ambroxol HCl based on ultraviolet derivative spectroscopy. Drug Dev Ther 2015;6:74-8
|How to cite this URL:|
Mathew C, Bhukya SN, Makula A, Puvvadi R S. A green analytical method for the simultaneous analysis of cefixime trihydrate and ambroxol HCl based on ultraviolet derivative spectroscopy. Drug Dev Ther [serial online] 2015 [cited 2017 May 27];6:74-8. Available from: http://www.ddtjournal.org/text.asp?2015/6/2/74/162450
| Introduction|| |
Cefixime trihydrate (CEF) ([6R,7R]-7-(2-[2-Amino-4 -thiazolyl]glyoxylamido)-8-oxo-3-vinyl-5-thia-1-azabicyclo (4.2.0)oct-2-ene-2-carboxylicacid,72-(Z)-[O- (carboxymethyl)oxime] is an orally absorbed third generation cephalosporin antibiotic that was approved by the U.S. Food and Drug Administration in 1997 for the treatment of mild to moderate bacterial infections. It has a broad antibacterial spectrum against various Gram-positive and Gram-negative bacteria, including Haemophilus influenzae, Neisseria gonorrhoeae, Escherichia coli and Klebsiella pneumoniae resistant to ampicillin, cephalexin, cefaclor and trimethoprim-sulfamethoxazole. It is used for the treatment of susceptible infections, including gonorrhea, otitis media, pharyngitis, lower respiratory-tract infections such as bronchitis and urinary-tract infections. ,, A detailed literature survey has shown that cefixime has been studied either alone or in combination with other drugs by various analytical methods such as spectrophotometric, ,,,, fluorimetric,  voltammetric, , high performance liquid chromatography (HPLC), ,,,,,, high performance thin liquid chromatography (HPTLC) ,,, and layer chromatograph-mass spectrometry (LC-MS).  Ambroxol hydrochloride (ABH) chemically, 4-([2-amino-3,5-dibromophenyl]-methyl)-amino] cyclohexanol hydrochloride is a mucolytic expectorant and used to reduce the viscosity of mucous secretions  (Budavari 1996). Methods available for the determination of ABHX alone or in combination with other drugs include ultraviolet (UV) spectroscopy, , capillary electrophoresis,  HPLC, ,,,,, gas chromatography, , and LC-MS.  There are very less analytical methods reported so far for this combination, and they are based on HPLC. , To the best of our knowledge, there is no reported method available for the analysis of this combination by derivative spectroscopy. So an urgent need was felt to develop a UV derivative spectroscopic method, which reduces the cost of analysis on comparing with HPLC or HPTLC method.
| Materials and Methods|| |
Instruments and chemicals
A double beam UV-visible spectrophotometer (Shimadzu, 1800) having UV-probe software was used for the analysis. Matched and calibrated quarts cuvettes were used as sample cell. The samples of CEF and ambroxol HCl (ABH) were procured from Dr. Reddy's laboratory, India. The tablets were purchased from local market.
Analytical method development and validation
Different solvents such as methanol, water, phosphate buffer, acetate buffer etc., were used as solvents and either zero crossing points (ZCPs) were not available for either drug or for both drugs. When the solvent was shifted to 0.1N urea, ZCPs were available for both the drugs and hence selected as the solvent. Moreover, it is more preferable as it yields an economical and ecofriendly method by avoiding the use of any organic solvents at any stage in the analysis. Standard solutions of CEF (10 μg/ml) and ABH (10 μg/ml) prepared in 0.1N urea were scanned in the spectrum mode between 200 and 400 nm so as to obtain the respective zero-order spectra. It was converted into first derivative spectra selecting delta λ =4 nm and scaling factor = 1. The overlapped spectra of CEF and ABH showed the presence of the ZCP for both the drugs. That is, ZCP of ABH at which CEF showed the derivative absorbance and vice versa for CEF were noted.
Preparation of stock solution and standard solution
Ten mg of each standard drug were weighed and dissolved separately in 0.1N urea to obtain stock solution (1000 μg/ml) of each drug. These solutions were diluted suitably with 0.1N urea to obtain the standard solutions of CEF and ABH.
The method was validated for accuracy, precision, linearity, LOD, and LOQ by the following procedures .
The stock solution of CEF (50 μg/ml) and ABH (50 μg/ml) were prepared in 0.1N urea. CEF solutions of various concentrations (5-35 μg/ml) were prepared by diluting appropriate volumes with 0.1N urea. In a similar manner, stock solution of ABH also diluted to prepare various concentrations (3-10.5 μg/ml).The first derivative spectra were recorded using the prepared solutions against 0.1N urea as blank.
The accuracy of the method was determined by calculating recoveries of CEF and ABH by standard addition method. Tablet powder equivalent to 10 mg of CEF was taken in three different volumetric flask and 80%, 100% and 120% of pure cefixime bulk drug was added respectively and diluted with 0.1N urea. Similarly, tablet powder equivalent to 3 mg of ABH was transferred into another three different 10 ml volumetric flasks and to it 80%, 100% and 120% of pure ABH bulk drug was added respectively and diluted with 0.1N urea. The amounts of CEF and ABH were estimated by measuring derivative response at the selected wavelength (306 nm for cefixime and 253 nm for ABH) and the concentrations were calculated from the computed regression equation resulting from the linearity studies. The recovery was performed in triplicate at each specified concentration level.
The intra-day precision of the proposed first derivative spectrophotometric method was determined by estimating the corresponding response 3 times on the same day for three different concentrations of CEF (10, 20, 30 μg/ml) and ABH (3, 6, 9 μg/ml). The inter-day precision was determined by estimating the corresponding response 3 times on 3 different days for the same concentrations of CEF and ABH.
Limit of detection and limit of quantitation
The limit of detection (LOD) and limit of quantitation (LOQ) were determined on samples containing very low concentrations of the analyte. LOD and LOQ were estimated at a signal to noise ratio of 3:1 and 10:1 respectively by analyzing a series of dilute solutions of known concentration. The values can be calculated by equation 1 and 2, respectively.
LOD = 3.3 σ/S equation 1
LOQ = 10 σ/S equation 2
σ = standard deviation of the response and S = slope of calibration curve.
Analysis of the dosage form (assay)
Twenty tablets of marketed formulation, each containing 300 mg of CEF and 100 mg of ABH were used. Solution was prepared from tablet powder so as to get a final solution containing 30 μg/ml CEF and 10 μg/ml ABH. The amount of CEF and ABH was determined by substituting derivative responses into the equation of the straight line representing the calibration curves for CEF and ABH.
| Results and Discussion|| |
Selection of zero crossing point
The first derivative spectrum of CEF has zero absorbance at 253 nm, where ABH gives the significant derivative response, while the first derivative spectrum of ABH has zero absorbance at 306 nm, where cefixime gives the significant derivative response. Therefore, 253 nm and 306 nm were selected for estimation of ABH and CEF, respectively as shown in [Figure 1].
|Figure 1: First order ultraviolet overlaid spectrum of cefixime trihydrate and ABH showing the zero crossing points of each drugs|
Click here to view
Calibration plot for cefixime trihydrate and ambroxol HCl
Cefixime trihydrate and ABH were showing a linear relationship between concentration (μg/ml) and derivative absorbance. CEF and ABH were linear in the range of 5-35 μg/ml and 3-10.5 μg/ml respectively. From the linear regression analysis, correlation coefficient value (r2 ) for CEF and ABH was 0.9999 and 0.9999 respectively, which indicated the linearity of the method. From [Figure 2], it was observed that with the increase in CEF concentration, the derivative response at 306 nm was increased. Similarly, the derivative response for ABH at 253 nm was increased with the increase in its concentration. The regression equation for CEF and ABH is shown in the linearity data given in [Table 1].
|Figure 2: First order ultraviolet overlaid spectra in the linearity range of cefixime trihydrate (5-35 μg/ml) and ABH (3-10.5 μg/ml)|
Click here to view
The accuracy was determined by standard addition method. Three different levels (80%, 100% and 120%) of standards were spiked to commercial tablets in triplicate. The mean of percentage recoveries and % relative standard deviation (RSD) values were calculated and reported in [Table 2]. The % recoveries of CEF and ABH were found to be in the range of 99.05-101 and 99.6-100.63, respectively which are satisfactory.
The repeatability (intra-day precision) of the method was determined by intra-day (n = 3) analysis of three standard solutions of CEF and ABH at the concentration of 10, 20 and 30 μg/ml and 3, 6 and 9 μg/ml respectively. The % RSD of repeatability was <2.0 for both the drugs. Intermediate precision was determined by the inter-day (n = 3) analysis of three standard solutions of CEF and ABH at the concentration of 10, 20 and 30 μg/ml and 3, 6 and 9 μg/ml respectively and reported in [Table 3]. The % RSD for inter-day analysis was <2.0 for both the drugs. These statistical data were indicative of good precision.
Limit of detection and limit of quantitation
Limit of detection and LOQ of CEF was found to be 0.187 μg/ml and 0.625 μg/ml respectively. For ABH, LOD was found to be 0.0937 μg/ml and LOQ was found to be 0.312 μg/ml.
Analysis of commercial tablets (assay)
The accuracy of proposed method was evaluated by the assay of commercially available tablets (Ceftas-AL) containing CEF (100 mg) and ABH (30 mg). The results obtained for CEF and ABH were compared with the corresponding labeled amounts and reported in [Table 4]. The amount of CEF and ABH found in formulation-I (Ceftas-AL) was 100.373 mg and 30.89 mg. The % RSD for assay results of the formulation (Ceftas-AL) was <2, which indicated the accuracy of the proposed method.
| Conclusion|| |
The main objective of the present work was to develop an economical and ecofriendly analytical method for the simultaneous analysis of CEF and ABH in the tablet dosage form, IPQC samples or dissolution samples. The validation study results indicated that the presence of excipients did not interfere with the analysis and hence the method can be employed for bulk drugs as well as formulations. The proposed method has some advantages as neither it requires any sophisticated instruments like HPLC or HPTLC nor costly reagents or solvents. Moreover, the solvent selected for the entire steps was urea which is a nature friendly chemical.
| References|| |
Brogden RN, Campoli-Richards DM. Cefixime. A review of its antibacterial activity. Pharmacokinetic properties and therapeutic potential. Drugs 1989;38:524-50.
Sweetman SC. The Complete Drug Reference. 33 rd
ed. London: Pharmaceutical Press; 2002.
Talebpour Z, Pourabdollahi H, Rafati H, Abdollahpour A, Bashour Y, Aboul-Enein HY. Determination of Cefixime by a Validated Stability-Indicating HPLC Method and Identification of its Related Substances by LC-MS/MS Studies. Sci Pharm 2013;81:493-503.
Elwalily AF, Gazy AA, Belal SF, Khamis EF. Quantitative determination of some thiazole cephalosporins through complexation with palladium (II) chloride. J Pharm Biomed Anal 2002;22:385-92.
Attimarad M, Anroop B. Simultaneous determination of ofloxacin and cefixime by first and ratio first derivative UV spectrophotometry. Chron Young Sci 2011;2:144-9.
Maheshwari RK, Kinariwala M, Saxena M, Gahlot M, Chaki R, Jagwani Y. Spectrophotometric Analysis of cefixime trihydrate tablets using metformin hydrochloride as hydrotropic solubilizing agent. Asian J Chem 2008;3:43-5.
Vishal S, Raj H. Development and validation of derivative spectroscopic method for simultaneous estimation of cefixime trihydrate and azithromycin dihydrate in combined dosage form. Int J Pharm Sci Res 2012;3:1753-60.
Dolly TG, Bagada HL. Simultaneous equation method for the estimation of cefixime trihydarte and linezolid in their combined tablet dosage form by UV-visible spectrophotometry. Int Bull Drug Res 2013;3:29-38.
Bebawy LI, El Kelani K, Fattah LA. Fluorimetric determination of some antibiotics in raw material and dosage forms through ternary complex formation with terbium (Tb(3+)). J Pharm Biomed Anal 2003;32:1219-25.
Golcu A, Dogan B, Ozkan SA. Anodic voltammetric behavior and determination of cefixime in pharmaceutical dosage forms and biological fluids. Talanta 2005;67:703-12.
Jain R, Gupta VK, Jadon N, Radhapyari K. Voltammetric determination of cefixime in pharmaceuticals and biological fluids. Anal Biochem 2010;407:79-88.
Dhoka MV, Sandage SJ, Dumbre SC. Simultaneous determination of cefixime trihydrate and dicloxacillin sodium in pharmaceutical dosage form by reversed-phase high-performance liquid chromatography. J AOAC Int 2010;93:531-5.
Muhammad AH, Shahnaz G, Raheela B, Muhammad IN. Development of HPLC-UV method for analysis of cefixime in raw materials and in capsule. Jordan J Pharm Sci 2009;2:53-65.
Khan IU, Sharif S, Ashfaq M, Asghar MN. Simultaneous determination of potassium clavulanate and cefixime in synthetic mixtures by high-performance liquid chromatography. J AOAC Int 2008;91:744-9.
Manna L, Valvo L. Development and validation of a fast reversed-phase ion-pairing liquid chromatographic method for simultaneous determination of eight cephalosporin antibiotics in pharmaceutical formulations. Chromatographia 2004;60:645-9.
Gonzalez-Hernandez R, Nuevas-Paz L, Soto-Mulet L, Lopez-Lopez M, Hoogmartens J. Reversed phase high performance liquid chromatographic determination of cefixime in bulk drugs. J Liq Chromatogr Related Technol 2001;24:2315-24.
Khandagle KS, Ganddhi SV, Deshpande PB, Gaikwad NV. A simple and sensitive RPHPLC method for simultaneous estimation of cefixime and ofloxacin in combined tablet dosage form. Int J Pharm Pharm Sci 2011;3:46-8.
Eric-Jovanovic S, Agbaba D, Zivanov-Stakic D, Vladimirov S. HPTLC determination of ceftriaxone, cefixime and cefotaxime in dosage forms. J Pharm Biomed Anal 1998;18:893-8.
Pawar SJ, Kale AP, Amrutkar MP, Jagade JJ, Pore NS, Bhosale A. HPTLC estimation of cefixime and cloxacillin in tablet dosage form. Asian J Res Chem 2010;3:299-301.
Raval PL, Mehta FA, Ahir KB, Bhatt KK. Simultaneous estimation of azithromycin dihydrate and cefixime trihydrate in pharmaceutical formulation by HPTLC method. J Liq Chromatogr Related Technol 2014;37:1805-18.
Deshpande MM, Kasture VS, Gosavi SA. Application of HPLC and HPTLC for the simultaneous determination of cefixime trihydrate and Ambroxol hydrochloride in pharmaceutical dosage form. Eurasian J Anal Chem 2010;5:227-38.
Meng F, Chen X, Zeng Y, Zhong D. Sensitive liquid chromatography-tandem mass spectrometry method for the determination of cefixime in human plasma : a0 pplication to a pharmacokinetic study. J Chromatogr B Analyt Technol Biomed Life Sci 2005;819:277-82.
Budavari S. The Merck Index. 12 th
ed. Whitehouse Station, NJ: Merck and Co. Inc.; 1996. p. 404.
Dinçer Z, Basan H, Göger NG. Quantitative determination of ambroxol in tablets by derivative UV spectrophotometric method and HPLC. J Pharm Biomed Anal 2003;31:867-72.
Mathew C, Suman B, Ajitha M, Babu PR. A green analytical method for the simultaneous estimation of Levofloxacin hemihydrate and ambroxol hydrochloride using hydrotropy and first derivative UV spectroscopy. Orient J Chem 2014;30:1385-9.
Perez-Ruiz T, Martínez-Lozano C, Sanz A, Bravo E. Sensitive method for the determination of ambroxol in body fluids by capillary electrophoresis and fluorescence detection. J Chromatogr B Biomed Sci Appl 2000;742:205-10.
Brizzi V, Pasetti U. High-performance liquid chromatographic determination of ambroxol in pharmaceuticals. J Pharm Biomed Anal 1990;8:107-9.
Bazylak G, Nagels LJ. Simultaneous high-throughput determination of clenbuterol, ambroxol and bromhexine in pharmaceutical formulations by HPLC with potentiometric detection. J Pharm Biomed Anal 2003;32:887-903.
Kotkar PR, Shirkhedkar AA, Surana JS. Development and validation of RP-HPLC method for simultaneous estimation of cefpodoxime proxetil and ambroxol hydrochloride in bulk and in tablets. Int J Res Pharm Biomed Sci 2012;3:156-63.
Heinänen M, Barbas C. Validation of an HPLC method for the quantification of ambroxol hydrochloride and benzoic acid in a syrup as pharmaceutical form stress test for stability evaluation. J Pharm Biomed Anal 2001;24:1005-10.
Koundourellis JE, Malliou ET, Broussali TA. High performance liquid chromatographic determination of ambroxol in the presence of different preservatives in pharmaceutical formulations. J Pharm Biomed Anal 2000;23:469-75.
Nobilis M, Pastera J, Svoboda D, Kvêtina J, Macek K. High-performance liquid chromatographic determination of ambroxol in human plasma. J Chromatogr 1992;581:251-5.
Colombo L, Marcucci FM, Marini GM, Pierfederici P, Mussini E. Determination of ambroxol in biological material by gas chromatography with Electron capture detection. J Chromatogr B 1990;530:141-7.
Schmid J. Assay of ambroxol in biological fluids by capillary gas-liquid chromatography. J Chromatogr 1987;414:65-75.
Kim H, Yoo JY, Han SB, Lee HJ, Lee KR. Determination of ambroxol in human plasma using LC-MS/MS. J Pharm Biomed Anal 2003;32:209-16.
36. Mallapur S, Panghal S, Mubeen G, Goli D, Shanbouge R. A novel HPLC-PDA method development and validation for the simultaneous estimation of cefixime and ambroxol HCl in tablets. Int J Pharm Sci 2011;3:1279-87.
[Figure 1], [Figure 2]
[Table 1], [Table 2], [Table 3], [Table 4]