Microsoft Word - 226-238 226 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Spectrophotometric Determination of Carbamazepine Via Oxidative Coupling Reaction with 2,4-dinitrophenyl hydrazine Sahar R. Fadhel Dept. of Chemistry / College of Science/ University of Diyala. Najwa I. Abdulla Intidhar D. Sulaiman Dept. of Chemistry/College of Education for Pure Science (Ibn Al-Haitham) /University of Baghdad Received in:16/December/2015,Accepted in:7/January/2016 Abstract An accurate and sensitive spectrophotometric method has been developed for the determination of carbamazepine (CRN.) in pure and dosage forms. The method is based on the oxidation of 2,4-dinitrophenylhydrazine (2,4-DNPHz) by potassium periodate than coupling with carbamazepine (CRN.) in alkaline medium to form a stable yellowish brown colored water-soluble dye with a maximum absorption at 485 nm. The variables that affect the completion of reaction have been carefully optimized. Beer’s law is obeyed over the concentration range of (4-50 μg.mL-1) with molar absorptivity of (6.7335×103 L.mol-1.cm- 1). The limit of detection was (0.1052 μg.mL-1) and Sandell’s sensitivity value was 0.0350 μg.cm-2.The proposed method has been applied successfully to the determination of carbamazepine in pharmaceutical preparation. Keywords: Spectrophotometric, Carbamazepine, 2,4-dinitrophenyl hydrazine ,Dosage forms, oxidative Coupling. 227 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Introduction Carbamazepine (CRN.) has the IUPAC name 5H-dibenzo[b,f]azepine-5-carboxamid (Scheme 1) of molar mass 236.269 g.mol-1 and molecular formula C15H12N2O.  It is a highly lipophilic neutral tricyclic compound with a white to off white color almost odorless crystalline powder. It is slightly soluble in water but soluble in alcohol and acetonitrile.[1,2] Carbamazepine is an anticonvulsant and mood stabilizing drug used mainly in the treatment of epilepsy and bipolar disorder, it may be used in schizophrenia along with other medications. [3] In 1953 carbamazepine was discovered by Swiss chemist Walter Schindler. It is currently available as a generic medication and is not very expensive.[4] Several methods have been reported for the determination of carbamazepine in various matrices using spectrophotometry,[5-7] (HPLC) [8,9], flow Injection Analysis,[10,11] electro-analytical method,[12,13] and capillary electrophoresis.[14,15] The aim of the present work is to suggest a simple and sensitive spectrophotometry procedure for the determination of carbamazepine in pure dosage forms. The method is based on an oxidation of 2,4-dintrophenyhydrazin by potassium periodate and reaction with carbamazepine in alkaline medium to form a colored product. In addition, the reaction conditions were studied one-factor-a time to provide an optimized analytical response. Experimental Instruments A PG instrument, UV-visible spectrophotometer model T80 (U.K) with 1cm matched quartz cells was used for the absorbance measurements. Sartorius BL 210 S electronic balance was used for weighing the samples. Materials and Methods All chemicals used were of analytical reagent grade and were obtained from BDH and Panreac. Carbamazepine standard powder was kindly provided by the State Company for Drug Industries and Medical Appliances, Samara-Iraq(SDI). Carbamazepine Stock Solution (1000 µg.mL-1) The stock solution of (CRN.) was prepared by dissolving an accurately weighed 0.1000 g of pure drug in 10ml of ethanol and the volume was made up to the mark in 100mL volumetric flask with ethanol. The stock solution was protected from light and stored at 5ºC. Carbamazepine working solution (200 μg.mL-1): prepared by diluting 20mL of the stock solution to 100mL in a volumetric flask with ethanol. 2,4-dinitrophenyl hydrazine solution (2,4-DNPHz) (2×10-3M): prepared by dissolving 0.0396g of 2,4-DNPHz in 3mL of concentrated sulfuric acid and the volume was made up to the mark in 100mL volumetric flask with distilled water. Potassium periodate solution (6×10-3M): prepared by dissolving 0.1380g of KIO4 in a suitable volume of distilled water and the volume was made up to the mark in 100mL volumetric flask. 228 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Sodium hydroxide solution (~4M): prepared by dissolving 16.000g of NaOH in a suitable volume of distilled water and the volume was made up to the mark in 100mL volumetric flask. Carbamazepine tablets solution (1000µg.ml-1) The content of 10 tablets was accurately weighed and grinded into fine powder then mixed well and an average weight was calculated. An amount of the powder equivalent to 0.0842g and 0.0839g (containing 0.05g of the drug carbamazepine) of Carbasam-200mg and Tegretol-200mg respectively was accurately and separately weighed, dissolved in 10ml ethanol and stirred for 10 min to ensure complete dissolution of the drug, then transferred into 50 mL volumetric flask and diluted to the mark with ethanol to get 1000µg.mL-1 (CRN.). The solution was filtered by using Whatman filter paper No.41 to avoid any suspended or un- dissolved material before use. Working solution (200µg.mL-1) was freshly prepared and analyzed by the recommended procedure. General recommended procedure for calibration In a series of 10mL volumetric flasks, 1mL of 2×10-3M 2,4-DNPHz and 1mL of 6×10-3M potassium periodate were added to each flask. The resulting oxidized product was coupled with (CRN.) by adding 1mL aliquots of the standard solution containing (40 - 500) µg followed by 1mL of 4M sodium hydroxide to each flask with shaking. After 10min, the solutions were making up to the mark with distilled water, mixed well and left to stand for 10min. The absorbance of yellowish brown colored chromogen was measured at 485nm against the reagent blank. Results and Discussion Absorption spectra for primary test The primary test for the present method involved oxidation of 2,4-dintrophenyhydrazin with potassium periodate and reaction with (CRN.) in alkaline medium to form a colored product. The test was done by adding 1ml of 200µg.ml-1 (CRN.), 1mL of 1×10-3M 2,4-DNPHz, 1mL of 5×10-3M potassium periodate, and then 1mL of 1M sodium hydroxide in 10mL volumetric flask with shaking. The contents were diluted to the mark with distilled water. The absorbance and λmax of the colored product was measured against the reagent blank. Figure (1) shows that the maximum absorption was obtained at a wavelength of 485nm. Optimization of reaction variables The various parameters related to the colored product formation have been studied by varying the parameters one at a time and controlling all others fixed and optimum conditions have been selected. 1. Effect of 2,4-DNPHz concentration The influence of the concentration of 2,4-DNPHz on the absorbance of the colored product was investigated in the range between (9×10-4 - 4×10-3)M figure (2). It was found that the maximum absorbance of the yellowish brown color was achieved with 2×10-3M of the reagent. Above this value a decrease in absorbance was observed. Therefore, 1mL of 2×10-3M was used during the subsequent work. 2. Effect of potassium periodate concentration The study of potassium periodate concentration revealed that the reaction was depending on KIO4 as an oxidizing agent. The highest absorbance was attained when the concentration of 229 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 KIO4 was 6×10-3M. Above this value a decrease in the absorbance reading occurred figure (3). Therefore, 1mL of 6×10-3M was used during the subsequent work. 3- Effect of different bases The effect of different alkaline solutions with concentration of 1M on the absorption intensity of the colored dye formed was investigated. Four types of bases namely; sodium hydroxide, potassium hydroxide, sodium carbonate and ammonium hydroxide were tested and the results were listed in table (1). As can be seen it was found that sodium hydroxide shows the maximum absorption intensity of the colored product, therefore it was selected for subsequent work. 4. Effect of sodium hydroxide concentration The effect of sodium hydroxide concentration on the measured absorbance of the formed colored product was investigated by using 1mL of different concentrations of NaOH solution ranged between (0.5-6.0)M. The results are presented in figure (4), which reveals that the addition of 1mL of 4M NaOH exhibited a better absorbance. Above this concentration the absorbance value decreased. Therefore, 1mL of 4M NaOH was used in all subsequent experiments. 5. Effect of coupling reaction time The optimum time for the reaction between (CRN.) and 2,4-DNPHz was studied at a fixed concentration of (CRN.). 20µg.mL-1 reacted with 2,4-DNPHz and potassium periodate in alkaline medium. Absorbance values were recorded at different intervals ranging from immediate measurement to a waiting period of 25min. The oxidative coupling reaction is completed in 10min as shown in table (2). 6. Effect of reagents mixing order Effect of different orders of components addition on chromogen formation was investigated by changing the order of addition of reactants four times as shown in table (3). From the results shown, it is obvious that mixing order number one was recommended as it resulted in obtaining a maximum absorbance and hence was followed in the subsequent experiments. 7. The stability Stability study of the colored product formed upon reaction of drug solution with 2,4-DNPHz was carried out by measuring its absorbance at different time intervals. 10min was selected as optimum time in the general recommended procedure. The color of the solution was nearly stable for at least 60min as shown in figure (5). Final absorption spectra The absorption spectrum of the yellowish brown product formed from the treatment of (CRN.) 20µg.mL-1 with 2,4-DNPHz in the presence of potassium periodate in alkaline medium under the optimum conditions was recorded and showed a maximum absorption at 485nm against the reagent blank as shown in figure (6). Calibration curve and analytical data Employing the optimum experimental condition, the measured absorbance values at 485 nm versus different standard concentrations of (CRN.) were plotted to construct a calibration curve. The linearity of the obtained plot of the (CRN.) was in the concentration range of (4 - 50) µg.mL-1 as shown in figure (7). The statistical treatments of the analytical data are summarized in table (4). 230 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Structure of the product Job's method [16] and mole ratio method [17] have been used in the determination of the stoichiometry of the reaction between (CRN.) and 2,4-DNPHz. The obtained results figures (8) & (9) showed that 1:1 carbamazepine to 2,4-DNPHz ratio is obtained. The proposed mechanism of the reaction between (CRN.) and 2,4- DNPHz can be represented in scheme (2). Comparison of the methods Table (5), shows a comparison between the proposed method and that of another literature spectrophotometric methods throughout some measured analytical parameters. Precision and accuracy The precision and accuracy of the proposed method was tested by analyzing three replicate samples of (CRN.) in three different concentration levels (within Beerʼs law range). The results listed in table (6) indicate an acceptable accuracy and precision of the method. Interference study The extent of interfering by some excipients which often accompanied pharmaceutical preparations was studies by measuring the absorbance of solution containing 20 µg.mL-1 of (CRN.) and 1000µg.mL-1 of excipient. The results in table (7) show that the studied excipients do not interfere in the determination of (CRN.) in its dosage forms. Application in pharmaceutical preparation In order to demonstrate the applicability of the proposed method for the determination of (CRN.), the method was applied to two types of pharmaceutical formulations (tablets) from different manufacturing sources containing (CRN.). The results of the application were satisfactory as shown in table (8). Conclusions The reagents utilized in the proposed method are readily available, cheap and the procedures do not involve any critical reaction conditions. Moreover, the method is free from interference by excipients. The wide applicability of the new procedure for routine quality control was well established by the assay of carbamazepine in pure form and in pharmaceutical preparations. References 1. "British Pharmacopoeia" (2013), CD-ROM Her Majesty ̓s Stationary office, London. 2. Alagarsamy, V. (2010) "Text book of Medical Chemistry" 1st, Elsevier, 199-220. 3. Bradley, M. K.; Rene, H.; Levy, R. R.; Matson, R.; Meldrum, B.; Penry, J. K. and Dreifuss, F.E. (1989) Carbamazepine and carbamazepine epoxide,Antiepileptic Drugs, Third Edition, Raven Press,Ltd., New York, 505-517. 4. Mcillin, A. G.; Juenke, M. J.; Tso, G. and Dasgupta, A. (2010) ʺEstimation of Carbamazepine and Carbamazepine-10, 11-Epoxide Concentrations in Plasma Using Mathematical Equations Generated With Two Carbamazepine Immunoassays; J. American Society for Clinical Pathologyʺ 133, 728-736. 231 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 5. Jayanna, B. K; Devaraj, T.D. and Ninge, G. (2014) ʺA Facile spectrophotometric method for the determination of carbamazepine in tabletsʺ Indian Journal of Drugs, 2(3), 132-135. 6. Eman, Y.Z. F.; Zayed, M.A.; Omar, M.M.; Sally, E. A. E. and Gehad, G. M. (2012) ʺSpectrophotometric determination of carbamazepine and mosapride citrate in pure and pharmaceutical preparationsʺ Arabian Journal of Chemistry ,5, 375–3827. 7. Fadhil, M. N. and Muhammad, S. M. (2014) ʺ Four spectrophotometric method for simultaneous determination of carbamazepine and lamotrigine in binary mixtures and urine samplesʺ The Malaysian Journal of Analytical Sciences, 18(3), 491 – 506. 8. Thejaswini, J. C. and Bannimath, G. (2014) ʺRP-HPLC method development and validation for simultaneous determination of amitriptyline ,carbamazepine and flunarizine in human plasma using mirtazapine as internal standardʺ Indo American Journal of Pharmaceutical Research, 4(8), 3597-3602 9. Hammam, A. M.; Fars, K. A. and Gamal, M. E. (2012) ʺ Development and validation of an HPLC–UV method for the quantification of carbamazepine in rabbit plasmaʺ Saudi Pharmaceutical Journal, 20, 29–34. 10. Çomoğlua, T.; Gönüla, N.; Şenerb, E.; Dalb, A. G. and Tunçelb, M. (2006) ʺDetermination of Carbamazapine by Flow‐Injection Analysis: Its Application to Tablet Analysis and Dissolution Studiesʺ Journal of Liquid Chromatography & Related Technologies, 29(18), 2677-2690 . 11. Zhi‐Qi, Z.; Guo‐Xi, L.; Jian, M.; Ying, L. and Yue‐Mei, L. (2006) ʺA Sensitive Flow Injection Fluorimetry for the Determination of Carbamazepine in Human Plasmaʺ Analytical Letters, 39(12), 2417-2428. 12. Liu-Li, H.; Duan, C. and Gao, Z. (2012) ʺElectrochemical behaviors and electrochemical determination of carbamazepine at ionic liquid modified carbon paste electrode in the presence of sodium dodecyl sulfateʺ Journal of Serbian Chemical Society,77(4), 483-496. 13. Atkins, S.; Sevilla, J. M.; Blazquez, M.; Pineda, T. and Gonalez-Rodriguez, J. (2010) ʺElectrochemical Behaviour of Carbamazepine in Acetonitrile and Dimethylformamide Using Glassy Carbon Electrodes and Microelectrodesʺ Electroanalysis, 22(24), 2961- 2966. 14. Yan-Yu, L.; Chun-Chi, W.; Yu-Hsiang, H.; Cheng-Sheng, C. and Shou-Mei, W. (2013) ʺAnalysis of carbamazepine and its five metabolites in serum by large-volume sample stacking–sweeping capillary electrophoresisʺ Analytical and Bioanalytical Chemistry, 405(1), 259-266. 15. Gibbons, S.; Wang, C. and Ma, Y. (2011) ʺDetermination of pharmaceutical and personal care products in wastewater by capillary electrophoresis with UV detectionʺ J.Talanta, 84(4), 1163-1170. 16. Job, P. (1971) "Spectrochemical Methods of Analysis" Wiley, New York, 346. 17. Christian, G. D. (1994) "Analytical Chemistry" fifth ed., Wiley, New York, 385–386. 18. Tahseen, A. Z. and Taghreed, S. S. (2012) ʺ Developing spectrophotometric method for Carbamazepine (antiepileptic drug) determination through preparation and Characterization of Fe(III) Complex With Mixed Ligand Containing Carbamazepine and Salicylaldehydeʺ Iraqi National Journal of Chemistry, 46, 199-214. 232 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Table (1): The effect of different bases on coupling reaction. Base (1M) Absorbance NaOH 0.185 KOH 0.162 Na2CO3 0.064 NH4OH 0.103 Table (2): The effect of coupling reaction time. Time (min) Absorbance 0 0.347 5 0.371 10 0.395 15 0.341 20 0.302 25 0.298 Table (3): Variation of absorbance with change of reactants addition order in the determination of 20 µg.mL-1 (CRN.). No Sequence Absorbance 1. R+O+D+B 0.421 2. D+R+O+B 0.395 3. R+D+O+B 0.116 4. D+B+R+O 0.048 R: reagent O: oxidizing agent D: drug B: base Table (4): Optical characteristics and statistical data for the determination of (CRN.). Parameter Value λmax (nm) 485 Color Yellowish brown Regression equation Y= 0.0274[CRN.] – 0.0756 Linearity range (µg.mL-1) 4 - 50 Calibration sensitivity (mL.µg-1) 0.0285 Correlation coefficient (r) 0.9996 Correlation of linearity (R2) 0.9995 Molar absorptivity (L.mol-1.cm-1) 6.7335×103 Sandellʼs sensitivity (µg.cm-2) 0.0350 L.O.D. (µg.mL-1) 0.1052 L.O.Q. (µg.mL-1) 0.3508 233 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Table (5): Analytical parameters for the analysis of carbamazepine by the proposed method comparing to other methods. Methods Linear range μg.mL-1 (ε) L.mol-1.cm-1 Correlation Coefficient ( R) C.V% range Ref. Proposed method 4.0 - 50.0 6.7335x103 0.9996 0.017-0.462 … Spectrophotometric 0.2 - 10.0 2.1450x 104 0.9831 0.15-0.25 6 Spectrophotometric 10.0-350.0 1.90 x 103 0.9998 0.63–2.17 7 Spectrophotometric 1.0 - 25.0 1.30x109 0.9996 2.12-0.59 18 RP-HPLC … … 0.9902 0.22 0.42 8 HPLC–UV 0.5 - 40.0 … 0.9999 0.53–2.75 9 Table (6): Evaluation of the accuracy and precision of the proposed method for the determination of (CRN.). Conc. of (CRN.) μg.mL-1 Er% C.V% Taken Found* 10.000 9.945 -0.550 0.462 25.000 25.013 0.052 0.031 35.000 35.017 0.048 0.017 *Average of three measurements. Table (7): Recovery values for 20 µg.mL-1 of (CRN.) in the presence of 1000 µg.mL-1 of different excipients. Excipients Carbamazepine Conc. Recovery (%) Name Conc. (µg.mL-1 ) Taken (µg.mL-1) Found (µg.mL-1 ) Lactose 1000 20.000 19.877 99.385 Glucose 19.921 99.605 Sucrose 19.756 98.780 Starch 20.074 100.370 Magnesium Stearate 19.752 98.760 Table (7): Determination of carbamazepine in pharmaceutical formulations (tablets) by the proposed method. Sample Weight Found* (mg) Concentration (µg.mL-1) Recovery % C.V % Taken Found* Carbasam - 200 mg S.D.I.-Iraq 195.920 10.000 9.796 97.960 1.216 201.296 25.000 25.162 100.648 0.607 Tegretol - 200mg Novartis-Switzerland 202.020 10.000 10.101 101.140 0.143 205.344 25.000 25.668 102.675 1.352 *Average of three measurements. 234 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Figure (1): Absorption spectra of: (a) 20 µg.mL-1 (CRN.) against reagent blank, (b) blank solution against solvent under the primary test conditions. Figure (2): The effect of the concentration of 2,4-DNPHz on the color development in the determination of 20 µg.mL-1 (CRN.). Figure (3): The effect of potassium periodate concentration on the color development in the determination of 20 µg.mL-1(CRN.). 0.04 0.08 0.12 0.16 0.2 0 0.001 0.002 0.003 0.004 0.005 A b so rb a n ce Concentration of 2,4-DNPHz [M] 0 0.04 0.08 0.12 0.16 0.2 0 0.002 0.004 0.006 0.008 0.01 A b so rb a n ce Concentration of KIO4[M] 235 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Figure (4): The effect of sodium hydroxide concentration on the color development in the determination of 20 µg.mL-1(CRN.). Figure (5): The stability of the colored product with time. Figure (6): Absorption spectra of: (a) 20 µg.mL-1(CRN.) against reagent blank, (b) blank solution against solvent under the optimum conditions. 0 0.1 0.2 0.3 0.4 0 2 4 6 8 A b so rb a n ce Concentration of NaOH[M] 0 0.2 0.4 0.6 0.8 0 10 20 30 40 50 60 A b so rb a n ce Time (min) 236 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Figure (7): Calibration curve for the determination of (CRN.) under optimum conditions. Figure (8): Continuous variation method for the reaction of (CRN.) with 2,4-DNPHz. Figure (9): Mole ratio method for the reaction of (CRN.) with 2,4-DNPHz. 0 0.2 0.4 0.6 0.8 1 1.2 1.4 0 10 20 30 40 50 60 A b so rb a n ce Conc. of carbamazepine (μg.mL-1) 0 0.04 0.08 0.12 0.16 0.2 0 0.2 0.4 0.6 0.8 1 A b so rb a n ce VDrug/[VDrug+VReagent] 0.07 0.08 0.09 0.1 0.11 0.12 0.13 0 0.5 1 1.5 2 2.5 3 3.5 A b so rb a n ce [2,4-DNPHz]/[Carbamazepine] 237 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 Scheme (1): The structural formula of carbamazepine. NO2 O2N NO2 N N KIO4 (I) NN NO2 NO2 OH HSO4 2,4-DNPHz Diazonium salt Azo dye NHNH2 H2SO4 (I) + O2N (CRN.) N NH2O N NH2O Scheme (2): The suggested reaction mechanism between (CRN.) and 2,4-DNPHz. 238 | Chemistry 2016) عام 1العدد ( 29مجلة إبن الهيثم للعلوم الصرفة و التطبيقية المجلد Ibn Al-Haitham Jour. for Pure & Appl. Sci. Vol. 29 (1) 2016 ثنائي-4,2 مع التأكسدي االزدواج تفاعل بوساطة للكاربامازيبين الطيفي التقدير هيدرازين فنيل نايترو سحر ريحان فاضل جامعة ديالى /كلية العلوم /قسم الكيمياء نجوى اسحاق عبد هللا انتظار داّود سليمان جامعة بغداد /الهيثم) ابن( ألصرفة للعلوم التربية كلية /الكيمياء قسم 2016/كانون األول/7 :فيقبل ،2015 /كانون األول/12استلم في: الخالصة تعتمد. الصيدالنية المستحضرات في و النقية بصورته لتقدير الكاربامازيبين وحساسة دقيقة طيفية طريقة تطوير تم الكاربامازيبين مع مفاعلته ثم البوتاسيوم بيرايودات بوجود هيدرازين فنيل نايترو ثنائي-4,2 الكاشف اكسدة على الطريقة الموجي الطول عند امتصاص اعظم تعطي الماء في ذائبه مصفر بني لون ذات مستقرة صبغه لتكوين قاعدي في وسط قانون. المثلى للتفاعل الظروف على للحصول بدقة التفاعل اكتمال في تؤثر التي العوامل من العديد درست. ʺانانومتر 485 وبحد .1-سم.1-مول.لتر 6.7345×310الموالرية واالمتصاصيه 1- مل.مكغم)50-4(التراكيز من مدى ضمن ينطبق بير في بنجاح ترحةقالم الطريقة تطبيق تم .2- سم.مكغم 0.0350 تساوي ساندل داللة و 1-مل.مكغم 0.1052كشف المستحضرات الصيدالنية. في الكاربامازيبين تقدير الصيدالنية، المستحضرات هيدرازين، نيتروفنيل ثنائي - 4,2 الكاربامازيبين، الطيفي، التقدير الكلمات المفتاحية: التأكسدي. االقتران