Spectrophotometric Estimation of Nitrazepam in Pure and in Pharmaceutical Preparations

ree simple, sensitive, accurate, and rapid visible spectrophotometric methods (A, B, and C) have been developed for the estimation of nitrazepam in both pure and in pharmaceutical preparations. ey are based on the diazotization of reduced nitrazepam with nitrous acid followed by coupling with acetyl acetone (method A), diphenylamine (method B), and citrazinic acid (method C) to form colored azo-dyes, exhibiting absorption maxima (λλmax) at 400, 550, and 460 nm, for methods A, B, and C, respectively.e produced colored azo-dyes are stable formore than 2 h. Beer’s lawwas obeyed in the concentration range of 0.5–20, 0.3–14 and 0.5–12 μμg/mL for methods A, B, and C, respectively and the corresponding molar absorptivity values are 1.01 × 10, 1.00 × 10, and 1.51 × 10 L molcm. All variables have been optimized and the results were statistically compared with those of a literature method by employing the Student’s t-test and F-test. No interference was observed from common adjuvants normally added to the tablets. e results obtained in the proposed methods are in good agreement with labeled amounts, when marketed pharmaceutical preparations are analyzed, which could be applied in the routine quality control analysis laboratory.


Introduction
Nitrazepam (NTZ), chemically known as 1,3-dihydro-1nitro-2-oxo-5-phenyl-2H-1,4-benzodiazepine-2-one (Figure 1), is a hypnotic agent that belongs to the benzodiazepine class, and it has been used in the treatment of stress related disorders [1].e official method for its determination is nonaqueous titrimetry reported in British Pharmacopoeia [2].Various other methods based on HPLC [3][4][5], complexometry with cadmium-2-methyl-5-nitrobenzenesulphonate [6], polarography [7,8], difference uv-spectrophotometry [9], densitometric TLC [10], gas-chromatography [11], micellar electrokinetic capillary chromatography [12], and derivative UV-spectrophotometry [13] have been reported for the assay of NTZ in pharmaceutical formulations.Different manipulation steps are involved in some of these methods, which are not simple for the routine analysis of pharmaceutical formulations.Spectrophotometric methods are still considered to be a very convenient and cost-effective technique, and hence widely used for the determination of therapeutics in pure as well as in dosage forms.Very few spectrophotometric methods have been reported for estimation of NTZ [14][15][16][17].ese methods were suffering from one or other disadvantages such as lack of selectivity [14][15][16], the use of costly reagent [16], and lower sensitivity [15,16].us, there is a need to develop a simple, selective, cost-effective, and sensitive procedure for the determination of NTZ in pure and in pharmaceutical formulations.
e present paper describes the development and optimization of three visible spectrophotometric methods based on diazo-coupling reaction using acetyl acetone (AA), diphenyl amine (DPA), and citrazinic acid (CZA) as the coupling agents.e developed methods are simple, sensitive, and accurate for the determination of NTZ in pure and in pharmaceutical formulations.

Preparation of Calibration Graph
2.3.1.Method A. Aliquot of nitrazepam ranging from 0-20 g mL −1 was transferred into a series of 10 mL volumetric �asks.To each �ask, 1 mL sodium nitrite (0.1% w/v) and 1 mL of 1 M hydrochloric acid were added.Aer 3 min, 1 mL of sulfamic acid (3% w/v) was added to each �ask.en, 2 mL each of the acetyl acetone (5% w/v) and 4 M sodium hydroxide were added.e contents were made up to the mark with distilled water and mixed well.Aer 5 min, the absorbance of the yellow colored azo-dye was measured at 400 nm against the reagent blank.

Method B.
Different aliquots of nitrazepam ranging from 0-14 g/mL were transferred into a series of 10 mL volumetric �asks.To each �ask, 1 mL each of the sodium nitrite (0.1% w/v) and 1 M hydrochloric acid were added.Aer 5 min, 1 mL of sulfamic acid (3% w/v) and then 2 mL diphenylamine (0.5% w/v) were added.e contents were made up to the mark with 6 M hydrochloric acid and mixed well.e absorbance of the violet colored azo-dye was measured at 550 nm against the reagent blank, aer 5 min.

Method C.
Into a series of volumetric �asks were added aliquots of NTZ ranging from 0-12 g/mL, 1 mL each of the sodium nitrite (0.1% w/v) and 1 M hydrochloric acid.Aer 3 min, 1 mL of sulfamic acid (3% w/v) was added to each �ask.Aer 1 min, 2 mL each of citrazinic acid (0.1% w/v) and 4 M sodium hydroxide were added.e volumes were made up to the mark with distilled water and mixed well.e absorbance of the orange colored azo-dye was measured at 460 nm against the reagent blank �ve minutes later.e amount of nitrazepam present in the sample was computed from calibration curve Figures 2(a), 2(b), and 2(c).

Procedure for Pharmaceutical Preparation.
Twenty tablets were weighed accurately and ground into a �ne powder.Tablets powder equivalent to 10 mg of the NTZ was accurately weighed and transferred into a 100 mL beaker.To this 5 mL 4 N hydrochloric acid and 1 g of zinc dust were added and stirred thoroughly for about 30 min.e contents were diluted with 50 mL distilled water and �ltered using �hatman No. 41 �lter paper.e �ltrate was received into a 100 mL calibrated �ask and it was made up to the mark with water.Appropriate aliquots of the drug solution were taken and the proposed standard procedures were followed for analysis of the drug content.

Results and Discussion
e presence of the aromatic amino group in reduced nitrazepam undergo diazotization with nitrous acid and then coupling the resulting diazonium salt with acetyl acetone (method A), diphenylamine (method B), and citrazinic acid (method C) to form colored azo-dyes and exhibiting absorption maxima ( max ) at 400, 550, and 460 nm, respectively for methods A, B, and C. e reaction pathways of all the methods are shown in Scheme 1.In step (1), reduced NTZ is treated with nitrite solution in hydrochloric acid medium, undergoes diazotization to give diazonium ion.In step (2), the diazonium ion is coupled with the coupling agents acetyl acetone (method A), diphenylamine (method B) and citrazinic acid (method C) to form colored azo-dyes in alkaline medium (methods A and C) and in acid medium (method B), to form colored azo-dyes.Based on the above observations, simple spectrophotometric methods to the determination of NTZ were developed and validated as per the current ICH guidelines.(DPA) for method B, and aqueous citrazinic acid (CZA) for method C for development of maximum color intensity.ese experimental variables were studied with a �xed concentration (5 g/mL) of nitrazepam.Optimization is done by varying one parameter, keeping other constant.e optimum concentrations of AA, DPA, and CZA leading to maximum color intensity were found to be 2 mL each of the above reagents per 10 mL of the reaction mixture in methods A, B, and C, respectively (Figure 2(c)).A volume of 1 mL each of the sodium nitrite (0.1%) (Figure 2(a)) and hydrochloric acid (1 M) (Figure 2(b)) were found to be suitable for getting the diazonium ion.In methods A and C, a volume of 2 mL 4 M sodium hydroxide was required to stabilize the colored azo-dye in a 10 mL reaction mixture.

Optimization of Experimental Parameters
In method B, the violet colored azo-dye was stable in acid medium.Hydrochloric acid, sulphuric acid, and acetic acid were studied as a medium and as diluents.But, the azo-dye was stable in hydrochloric acid medium.us, hydrochloric acid (6 M) was used as a diluent in method B to stabilize the dye.

Effects of Reaction Time and Stability of the Azo-Dye.
e colored azo-dyes developed rapidly aer addition of the reagents and attained maximum intensity aer about 5 min at room temperature in methods A-C.Stability study of the azo-dye was carried out by measuring the absorbance values at time intervals of 10 min and was found to be stable for more than 2 h in all the methods (Figure 3).

Method Validation
3.2.1.Linearity, Detection, and Quantitation Limit.Under the optimized experimental conditions for all the methods A-C, a linear correlation was found between the absorbance at respective wavelengths and concentration of NTZ in the ranges are given in Table 1.e regression analysis using method of least squares was made for the slope (b), intercept (a), and correlation (r) obtained from different concentrations and the results are summarized in Table 1.e optical characteristics such as absorption maxima, Beer's law limit, molar absorptivity and Sandell's sensitivity, the limits of detection and quantitation calculated as per the current ICH [18] guidelines are compiled in Table 1.e calibration curves of the methods A, B, and C are given in Figures 4(a), 4(b), and 4(c), respectively.

Accuracy and Precision.
Intraday precision and accuracy of the proposed methods were evaluated by replicate analysis (  5) of calibration standards at three different concentration levels in the same day.Precision and accuracy of interday were measured by performing the calibration standards at cited three concentrations on �ve consecutive days.Both precision and accuracy were based on the calculated percent relative standard deviation (RSD, %) and percent relative error (RE, %) of found concentration   compared to the theoretical one, respectively (Table 2).e result shows that these methods have reasonable precision Table 2. e proposed methods were successfully applied to the determination of nitrazepam in pharmaceutical dosage forms.

3.2.3.
Recovery.e accuracy and precision of the methods developed were further ascertained by recovery experiments performed on synthetic mixtures of NTZ with several excipients such as talc (30 mg), dextrose (100 mg), sodium alginate (10 mg), starch (20 mg), acacia (15 mg), and magnesium stearate (20 mg) by the proposed methods and recoveries obtained by each method were in the range 99.5 to 101.0% (  ).
In order to check the validity of the proposed methods, we applied the standard addition technique by adding nitrazepam to the previously analyzed tablets.e recovery of each drug was calculated by comparing the concentration obtained from the spiked mixtures with those of pure drugs.e results are summarized in Table 3. 3.2.4.Application to the Tablet Analysis.e proposed methods (A-C) were applied to the determination of NTZ in tablet solutions at three different concentrations.e results were compared with those of the reported method [17].Statistical analysis of the results using the Student's  test and  test revealed no signi�cant difference between the reported method at the 95% con�dence level with respect to accuracy and precision (Table 4).

Conclusions
e developed visible spectrophotometric methods are simple, sensitive, accurate, precise, reproducible, and economical and can be successfully applied to the routine estimation of nitrazepam in bulk and in pharmaceutical dosage forms without the need of extraction or heating the reaction mixture.Diazotization was carried out at room temperature and cooling to 0-5 ∘ C was not necessary.e methods are unaffected by slight variations in the experimental conditions such as basicity, reagent concentrations, and temperature.e value of standard deviation was satisfactorily low and recovery was close to 100% which indicates the reproducibility and accuracy of the three methods.

3. 1 . 1 .S 1 :
Effects of Reagents, Acid, and Alkali.e methods developed were optimized using different parameters such as sodium nitrite, hydrochloric acid, and concentrations of acetyl acetone (AA) for method A, alcoholic diphenylamine Proposed reaction scheme for NTZ (1) diazotization (2) coupling reaction.

F 3 :
Effect of time and stability of the azo-dye.

F 4 :T 4 :
Calibration curves for (a) method A, (b) method B, and (c) method C. Results of determination of NTZ in tablets and statistical comparison with the reference method.
All absorbance measurements were performed using a Systronics Model 166 digital spectrophotometer provided with 1 cm matched quartz cells.2.2.Reagents and Standards.Analytical reagent grade chemicals were used, and double distilled water was used throughout the experiment to prepare all solutions.
2.1.Apparatus.(i)Standard NTZ solution.e pharmaceutical grade NTZ, certi�ed to be ��.��%pure were received from Anglo French Drug & Industries Ltd., Bangalore India, as a gi sample and were used as received.

T 1 :
Optical characteristics and precision.  is the standard deviation of slope.Intraday a Mean value of �ve determinations, b mean value of �ve determinations, c mean value of three determinations, d relative standard deviation (%), e bias%: (found * y = bc + a where c is the concentration of nitrazepam in g/mL and y is the absorbance at the respective  max .  is the standard deviation of intercept, a

T 3 :
Results of recovery by standard-addition method.
*Mean value of three determinations.
Mean value of �ve determinations.Tabulated t and F values at 95% con�dence level are 2.77 and �.39, respectively.