Nano-level detection
of certain beta-blockers based on surface plasmon
resonance band of silver nanoparticles; Application
to content uniformity test
Sayed M Derayea1*,
Mahmoud A Omar 1, Mohamed Aboel-Kasem Abdel-Lateef2
1Department of Analytical Chemistry, Faculty
of Pharmacy, Minia University, Minia
61519, Egypt
2Department of Pharmaceutical Analytical
Chemistry, Faculty of Pharmacy, Al-Azhar University, Assiut branch, Assiut 71524,
Egypt
*Corresponding Author
E-mail: sayed.derayea@gmail.com
ABSTRACT:
A
simple, sensitive and cost effective method was developed and validated for the
determination of some β-adrenergic blocking agents namely; carvedilol, labetalol
hydrochloride, nebivolol hydrochloride and sotalol hydrochloride. The method was based on the ability
of the cited drugs to induce the formation of silver nanoparticles
(Ag-NPs) in the presence of polyvinyl pyrrolidone as
a stabilizer. The intense surface plasmon resonance
of the formed nanoparticles appeared at 420 nm, was
utilized for the quantitative spectrophotometric determination of the
beta-blockers. The linear concentration ranges were 0.05 – 1.6, 0.16 – 3.0, 0.2
– 2.5 and 0.10 – 2.0 μg mL-1 for carvedilol, labetalol
hydrochloride, nebivolol hydrochloride and sotalol hydrochloride respectively with limits of detection
of 30, 53, 62 and 34 ng mL-1,
respectively. The commercial dosage forms containing the studied drugs were analyzed
by the proposed method and the results were compared statistically with those
obtained by the reported methods. The comparison revealed high precision and
accuracy of the suggested method. Moreover, the method was extended to the
content uniformity testing of commercial tablets dosage forms.
KEYWORDS:
Surface plasmon resonance; b-adrenergic blockers; Silver nanoparticles; content uniformity test; Spectrophotometry.
1. INTRODUCTION:
β-adrenergic
antagonists (also called β-Blockers) are widely used in the managements of
several cardiovascular disorders such as; cardiac arrhythmias, arterial
hypertension in addition to angina pectoris. Some members of these group are
prescribed for the treatment of glaucoma or anxiety [1]. These drugs can exert their
therapeutic effects through blocking the beta-adrenergic receptors, preventing
the endogenous agonists noradrenaline and adrenaline
from accessing this receptors. It also was reported that an extent of the
beneficial cardiovascular effect of some β-adrenergic drugs was due to
their antioxidant properties. In this work, the following β-adrenergic
blockers were investigated; carvedilol (CRV), labetalol hydrochloride (LBT), nebivolol
hydrochloride (NBV) and sotalol hydrochloride (SOT) [2-5]. The chemical structures of
the investigated drugs are shown in Fig. 1.
Fig. 1: Chemical structures of the studied
ß-adrenergic blockers.
Several
methods for determination of the investigated β- blockers have been
reported. Among these methods are spectrophotometry [6-14], spectrofluorimetry
[15-21] liquid chromatography (HPLC) [4, 5, 22-27], gas chromatography (GC) [28-30], electrochemical [31-35] and capillary electrophoresis
[36-38] methods.
Spectrophotometric
methods based on colorimetric assay still one of the most commonly used
analytical techniques due to their convenience of visual observation, high
reproducibility and inherent simplicity. Recently several metal nanomaterials were applied for the colorimetric
determination of different analytes. Gold nanoparticles (AuNPs) and silver nanoparticles (AgNPs) were
commonly used for this purpose because of their unique optical and electric
properties [39-42]. Both of them have strong
localized surface plasmon resonance absorption with
extremely high extinction coefficients. There are different approaches in using
metal nanoparticles in colorimetric analysis. One of
the most common and simple way is that based on the formation of metal nanoparticles through reduction of the metal ions under the
effect of the analvtes. In case of the reduction of
gold/silver ions to AuNPs/AgNPs,
solutions, the process is associated with the appearance of distinctive colors and surface plasmon
resonance bands of metal nanoparticles located in the
visible region dependent on the size, shape and composition of the formed a nanoparticles [43]. It should be noted that, the
reduction of silver ions is weaker than gold ions which will limits the
compounds that can reduce silver ions to AgNPs.
Therefore, AgNPs have higher selectivity than that of
gold ions. Another advantage of silver nanomaterials
are their cost-effectiveness. The AgNPs-based sensor
has been applied to determine many substances such as metal ions[44, 45], pharmaceutical compounds [46-49], pesticide[50, 51], small molecules[52], and proteins[53, 54].
In
this work, silver nanoparticles were applied for the
development and validation of of a simple, sensitive,
effective and validated procedure for the determination the cited drugs. The
suggested method was applied for the analysis of these drugs either in bulk
powders or in their pharmaceutical dosage forms..
2.
EXPERIMENTAL:
2.1.
Instrumentation
All
absorbance measurements were carried out using Shimadzu UV and visible
recording spectrophotometer (UV 260) with matched 10 mm. quartz cell.
2.2.
Materials and reagents
All
chemicals used were of analytical reagent grade. Carvedilol
(99.0%) was kindly provided by Sigma Pharmaceutical Industries, Cairo, Egypt. Labetalol hydrochloride of (99.8%), was kindly provided by
DBK Pharmaceutical Company, El Obour City, Cairo,
Egypt. Nebivolol hydrochloride, of (99.6), was kindly
provided by Marcyrl Pharmaceutical Industries, El Obour City, Cairo, Egypt.Sotalol
hydrochloride (99.5) was kindly provided by Amoun
Pharmaceutical Company S.A.E, El Obour City, Cairo,
Egypt.
Silver
nitrate (Sigma–Aldrich, Steinheim, Germany) was
prepared as 15 mM aqueous solution. Polyvinylpyrrolidone with an average molecular weight
of10,000 (Acros, Geel,
Belgium), was prepared as 0.2% aqueous solution, Sodium hydroxide (El Nasr. Co.
Egypt) was prepared as 2.5 mM aqueous solution.
Distilled
water was prepared by water distiller (Tyumen-Midi-A0-25 MO, Russia).
2.3.
Pharmaceutical formulations:
Betacor® tablets (Amoun
Pharmaceutical Company S.A.E., Cairo, Egypt.) labelled to contain 80 mg sotalol hydrochloride per tablet. Karvex®
tablets (Sigma Pharmaceutical industries, Cairo, Egypt) labelled to contain
6.25 mg carvedilol per tablet. Labetalol®
tablets (Debaky Pharmaceutical Company, El Obour City, Cairo, Egypt) labelled to contain 200 mg labetalol hydrochloride per tablet. Nevilob®
tablets (Marcyrl Pharmaceutical Industries, El Obour City, Cairo, Egypt) labelled to contain 2.5 mg nebivolol hydrochloride per tablet.
2.4.
Preparation of standard drug solutions
Stock
solutions of labetalol hydrochloride and sotalol hydrochloride were prepared by dissolving 100.0 mg
of each drug in distilled water. Carvedilol stock
solution was prepared by dissolving 100.0 mg of carvedilol
powder in methanol. Nebivolol hydrochloride was
prepared by dissolving 100.0 mg of nebivolol
hydrochloride powder in 30 ml methanol and further diluted distilled water.
Working standard solutions having the required concentrations of the cited
drugs were prepared by further dilution of the stock solutions with distilled
water. The standard solutions were stable for 7 days when kept in refrigerator.
2.5.
General Analytical Procedure:
In
stopper test tube, appropriate amounts of silver nitrate, PVP, different
concentrations of the cited drugs and appropriate amounts of NaOH were added, 4 ml of double distilled water were added,
heated in the water bath at 80°C for appropriate times, quantitatively transfer
the contents to 10 ml volumetric flask and then completed to 10 ml with double
distilled water. The absorbance of the formed nanoparticles
was measured at the wavelength mentioned in Table 1, against reagent blank
treated similarly.
Table 1: Optimum conditions for the development of
parameters for determination of the studied ß-adrenergic blockers through
silver nanoparticles formation.
|
Parameter |
Carvedilol |
Labetalol HCl |
Nebivolol HCl |
Sotalol HCl |
|
Volume of Silver nitrate (0.015M) |
1.0 ml |
0.8 ml |
1.0 ml |
0.6 ml |
|
Volume of PVP (0.2%) |
0.8 ml |
0.6 ml |
0.6 ml |
0.8 ml |
|
Volume of NaOH (2.5 mM) |
0.8 ml |
0.6 ml |
0.8 ml |
0.8 ml |
|
Temperature |
80oC |
80oC |
80oC |
80oC |
|
Time of reaction |
25 min. |
35 min. |
30 min. |
35 min. |
2.6.
Procedure for analysis of tablets:
Twenty
tablets from the local market were weighed, finely powder. An amount of the
powder equivalent to 50.0 mg of drugs as hydrochloric salts was transferred
into a 100-mL separating funnel. The powder shacked with about 20 mL distilled water. The free base of the drug was librated by the drop wise addition of 33% w/v aqueous
ammonia and extracted with three successive potions of 20 mL
methylene chloride.
The combined methylene chloride extracts were
filtered through anhydrous sodium sulfate. The
organic solvent was evaporated to dryness under reduced pressure. The residue
was dissolved in 0.01 M hydrochloride, quantitatively transferred into 100 ml
volumetric flask and completed to volume with double distilled water. Further
dilution of the resultant solution was performed to obtain solution containing
10 μg mL-1 of the drug. The general
analytical procedure was applied on aliquot volume of the final solution and
the drug content was obtained by using the corresponding regression equation.
2.7.
Procedure for content uniformity testing for studied drugs:
Tablets
contents uniformity was carried out by following the official USP guidelines [55] (Chapter 905: Uniformity of
Dosage Units). The drug contents of ten individual tablets were estimated by
applying the same procedure for the analysis of tablets.
3.
RESULTS AND DISCUSSION:
In
this study, the system for the production of silver nanoparticle includes an
aqueous solution of silver nitrate in the presence of an alkaline medium and polyvinylpyrrolidone (PVP) as stabilizing agent. The presence
of secondary amino and secondary alcoholic groups in the studied beta-blockers
(carvedilol, labetalol
hydrochloride, nebivolol hydrochloride and sotalol hydrochloride) make these drugs as effective
reducing agents which promote the transformation of silver ions into Ag NPs in
a seedless process. It should be found that, no absorption band appeared in the
visible region (380 – 700 nm) in the absence of cited drugs, However, the
addition of b-blockers to the reaction
mixture, silver nanoparticles were formed and their
surface plasmon resonance bands were detected as
shown in Fig 2.
Fig. 2: Absorption spectra of
the formed silver nanoparticles using 1.0
µg mL-1 of the studied drugs except labetalol
(2.0 µg mL-1).
3.1.
Optimization of experimental factors
3.1.1.
Effect of the type and concentration of the stabilizer
The
presence of surfactant is essential for the formation of nanoparticles
since it prevent their aggregation. PVP and SDS were examined for their
stabilizing effect during the preparation of Ag-NPs. It was found that the use
of PVP as stabilizer is more preferable since it gave the highest sensitivity
and wider linear range compared to SDS. The explanation of this observation can
be as follow; the reaction of analytes with silver
nitrate results in the formation of protons, as a result, the removal of these
protons can enhance the formation of Ag-NPs. PVP can stabilize the formed
Ag-NPs by removal of the produced protons through the formation of H(PVP)+.
In the same time, PVP can also stabilize silver ions by formation of Ag(PVP)+
complexes. Removal pf protons will enhance the
formation of Ag-NPs while, the stabilization of silver ions reduces its rate of
formation. However, the protons removal through formation of H(PVP)+
is stronger than the other one consequently the reaction is moved to the
forward direction [56]. It was found that, maximum
reading were observed when using 0.4 ml of 0.2 % PVP solutions in case of labetalol hydrochloride and nebivolol
hydrochloride, while 0.6 ml of the reagent in case of carvedilol,
and sotalol hydrochloride. Higher reagent volumes did not any change if
the absorbance. Therefore, 0.6 and 0.8 ml of 0.2 % PVP solutions for the two
set of drugs respectively (Fig. 3).
Fig. 3: Effect of the volume of
0.2 % PVP solution on silver nanoparticles formation
with 1.0 µg mL-1 of the studied drugs
3.1.2.
Effect of sodium hydroxide concentration
It
was explained previously that, the removal of protons can enhance the formation
of Ag-NPs. For that reason, it was important to examine the effect of the
alkalinity of the reaction solution by changing the volumes of added 2.5 mM NaOH solution (Fig. 4). By
increasing the amount of NaOH, the absorbance
increased up to a certain concentration of NaOH.
Higher concentration decreased the absorbance with the formation of black
precipitate due to the formation of Ag2O. Thus, 0.8, 0.6, 0.8 and
0.8 ml of 25 mM NaOH was
selected as the optimum NaOH volume for carvedilol, labetalol
hydrochloride nebivolol hydrochloride and sotalol hydrochloride, respectively.
Fig. 4: Effect of the volume of
2.5 mM NaOH solution on
silver nanoparticles formation in the presence of the
studied drugs (1.0 µg mL-1).
3.1.3.
Effect of Silver nitrate concentration
It
was found that the absorbance of formed Ag-NPs increased by increasing the
volume of 15 mM silver nitrate solution. Maximum
absorbance values were obtained using 0.8, 0.6, 0.8 and 0.4 ml for carvedilol, labetalol
hydrochloride, nebivolol hydrochloride and sotalol hydrochloride respectively (Fig. 5). Further
increase in the reagent volume did not produce any significant change in the
absorbance. Therefore, the optimum volumes of 15 mM
silver nitrate were 1.0, 0.8, 1.0 and 0.6 ml for the studied drugs
respectively.
Fig. 5: Effect of the volume of
15 mM Silver nitrate
solution on silver nanoparticles formation with the studied drugs (1.0 µg mL-1).
3.1.4.
Effect of temperature and time of heating
Heating
of the reaction vessel was important to accelerate the rate of formation of the
Ag NPs. It was observed that the highest results were obtained upon heating the
solution in water bath at 80 °C for 20, 30, 25 and 30 min for carvedilol, labetalol
hydrochloride, nebivolol hydrochloride and sotalol hydrochloride respectively (Fig. 6). The absorbance
values were remained unchanged upon heating for longer times. Consequently, 25,
35, 30 and 35 min were the sufficient heating times for the investigated drugs
respectively to produce maximum absorption intensities.
Fig. 6: Effect of the reaction
time on the formation of the silver nanoparticles
with the studied drugs (1.0 µg mL-1).
3.2.
Method validation
3.2.1.
Linearity and range
Under
the optimum experimental conditions, calibration curves were constructed for carvedilol, labetalol
hydrochloride, nebivolol hydrochloride and sotalol hydrochloride by plotting the absorbance versus the
corresponding drug concentration in μg mL-1.
The data were statistical evaluated and the linear regression equations were
estimated. The linear concentration range, correlation coefficient, intercept
and slope for the calibration curve of each drug were calculated. In addition, the standard deviations of the
residuals (Sy/x), intercept (Sa)
and slope (Sb) were also calculated (Table
2). The proposed method has a good linearity as indicated by the high
correlation coefficient which was in the range of 0.9992 - 0.9998.(Table 2).
Table 2: Summary of quantitative parameters and
statistical data for the determination of the studied drugs with the proposed
method.
|
Parameter |
Carvedilol |
Labetalol HCl |
Nebivolol HCl |
Sotalol HCl |
|
linear range (μg/ml) |
0.05 - 1.6 |
0.16 - 3.0 |
0.2 - 2.5 |
0.10 - 2.0 |
|
Slope |
0.4468 |
0.2689 |
0.4277 |
0.4568 |
|
SD of slope (Sb) |
0.0045 |
0.0023 |
0.0057 |
0.0038 |
|
Intercept |
0.0323 |
0.0137 |
-0.0073 |
0.0197 |
|
SD of intercept (Sa) |
0.0041 |
0.0043 |
0.0080 |
0.0047 |
|
r2 a |
0.9992 |
0.9996 |
0.9984 |
0.9994 |
|
r a |
0.9996 |
0.9998 |
0.9992 |
0.9997 |
|
S y,x b |
0.0075 |
0.0046 |
0.0121 |
0.0069 |
|
LOD (μg/ml) |
0.030 |
0.053 |
0.062 |
0.034 |
|
LOQ (μg/ml) |
0.092 |
0.161 |
0.187 |
0.103 |
a r2 and r are
the correlation and determination coefficients, respectively and number of
determinations is eight.
b Sx,y
is the standard deviation of residual.
3.2.2.
Limits of detection (LOD) and quantitation (LOQ)
The
sensitivity of the method was examined by calculating LOD and LOQ using the
formulas; LOD=3.3 σ/S and LOQ=10 σ/S, where σ is the standard
deviation of intercept and S is the slope of the calibration curve. The
calculated LOD and LOQ were in the ranges of 0.030-0.062 and 0.092-0.187 μg mL-1 respectively. These low values give
an indication of the enhanced sensitivity of the suggested method.
3.2.3.
Accuracy and precision
Accuracy
of the method was assessed by analyzing six replicate of the cited drugs at
three concentration levels within the recommended range. The percent recovery
and standard deviation was calculated at each concentration and the results
were summarized in table 3. The high accuracy of the proposed method was proved
by the closeness of the obtained percentage recovery to 100 %.. The accuracy
was further examined by analysing the pure powders of the drugs using both the
proposed and reported methods. Statistical comparison of the results of both
methods showed the absence of any significant difference between them as the
calculated values of t- and F-tests did not exceed the tabulated ones. This
proves the high accuracy and precision of the proposed method (Table 4).
Replicate
analysis of three concentrations of the drugs within the recommended
range was carried out within the same day to check the repeatability (intra-day
precision) of the method. In the same manner the intermediate (inter-day)
precision was examined by repeated analysis but at successive days. The results
are presented in Table 5. The % RSD indicate did not exceed 2 % which indicate
high precision of the proposed method.
Table 3:
Evaluation of accuracy of the investigated analytical procedure at three
concentration levels within the specified range.
|
Drug |
% Recovery * ± SD |
||
|
|
0.5 μg mL-1 |
1 μg mL-1 |
1.5 μg mL-1 |
|
Carvedilol |
100.82 ± 1.43 |
99.63 ±
0.74 |
100.02 ±
1.37 |
|
Labetalol HCl |
99.22 ±
1.35 |
100.24 ±
0.67 |
100.73 ±
1.17 |
|
Nebivolol HCl |
99.57 ±
1.10 |
1.37 ±
1.34 |
99.94 ±
1.21 |
|
Sotalol HCl |
100.89 ±
1.25 |
100.14 ±
0.93 |
100.79 ±
1.24 |
* The value is the mean
of six replicates.
Table 4: Analysis of the bulk powders of the
studied drugs with the reported [11-14] methods and the proposed silver nanoparticles method.
|
Drug |
% Recovery a ± SD |
t- value b |
F- Value b |
|
|
|
Proposed method |
Reported method |
|
|
|
Carvedilol |
99.75 ± 0.76 |
100.34 ± 0.98 |
1.317 |
1.638 |
|
Labetalol HCl |
100.07 ±
0.89 |
101.16 ±
1.32 |
1.522 |
2.222 |
|
Nebivolol HCl |
99.54 ±
1.13 |
99.81 ±
0.95 |
0.4033 |
1.402 |
|
Sotalol HCl |
99.93 ± 1.61 |
98.5 ± 0.83 |
1.774 |
3.758 |
a The value is the mean of five determinations for both the reported and
proposed methods.
b Tabulated value at 95%
confidence limit; F=6.338 and t =2.306.
Table 5: Intra- and Inter-day precisions the
determination of the studied drugs with proposed method.
|
Conce. Level |
% Recovery ±S.D a |
|||
|
|
Carvedilol |
Labetalol HCl |
Nebivolol HCl |
Sotalol HCl |
|
Intra-day precision |
||||
|
0.5 (μg/mL) |
99.83 ± 1.15 |
98.91 ± 1.50 |
99.57 ± 1.28 |
100.24 ± 1.57 |
|
1.0 (μg/mL) |
99.48 ± 0.82 |
100.48 ± 0.99 |
100.25 ± 1.69 |
100.47 ± 1.76 |
|
1.5 (μg/mL) |
100.07 ± 1.38 |
101.69 ± 1.86 |
99.03 ± 1.31 |
100.93 ± 1.51 |
|
Mean ±S.D |
99.79 ± 0.30 |
100.36 ± 1.39 |
99.62 ± 0.61 |
100.55 ± 0.35 |
|
Inter-day precision |
||||
|
0.5 (μg/mL) |
101.81 ± 0.95 |
98.79 ± 1.31 |
99.89 ± 1.95 |
100.96 ± 1.53 |
|
1.0 (μg/mL) |
99.78 ± 0.80 |
99.08 ± 1.12 |
101.21 ± 1.37 |
99.24 ± 1.36 |
|
1.5 (μg/mL) |
99.96 ± 1.67 |
101.35 ± 0.79 |
99.41 ± 0.89 |
99.97 ± 1.45 |
|
Mean ±S.D |
100.52 ± 1.12 |
99.74 ± 1.40 |
100.17 ± 0.93 |
100.06 ± 0.86 |
a The
value is the mean of three determinations.
Table 6: Analysis of the investigated drugs in
their pharmaceutical dosage forms using the proposed spectrophotometric and
reported methods.
|
Dosage forms |
% Recovery a ± SD |
t- value b |
F- Value b |
|
|
|
Proposed method |
Reported method |
|
|
|
Karvex® tablets |
99.07 ± 0.74 |
100.28 ± 1.57 |
1.557 |
4.437 |
|
Labetalol® tablets |
100.00 ± 1.5 |
98.84 ± 0.84 |
1.505 |
3.172 |
|
Nevilob® tablets |
99.01 ± 0.75 |
100.00 ± 1.30 |
1.471 |
3.007 |
|
Betacor® tablets |
100.15 ± 1.10 |
99.05 ± 0.54 |
1.997 |
4.143 |
a The value is the mean of five determinations for
both the reported and proposed methods.
b Tabulated value at 95%
confidence limit; F=6.338 and t =2.306.
Table 7: Results of content uniformity testing of the studied β- blockers tablets using the proposed
method.
|
Dosage form |
% of the label claim |
% RSD * |
% error |
AV # |
|
Karvex® 6.25 mg tablets |
99.75 |
1.57 |
0.50 |
3.77 |
|
Nevilob® 2.5 mg tablets |
100.14 |
1.46 |
0.46 |
3.51 |
* RSD is the relative
standard deviation
# AV is the acceptance
value
3.3.
Application to pharmaceutical dosage forms
Commercial
pharmaceutical dosage forms of the investigated beta blockers drugs were
analysed using the proposed method. Results in Table 6, shows that the mean
recovery percentage were in the range 99.01– 100.15 with a relative standard
deviations of 0.74 – 1.5 %, To examine the accuracy and precision of the method
the results of proposed method were statistically compared with those of
reported methods [11-14]. The t- student's and F-tests
values were calculated and were found not exceeding the tabulated values at 95%
confidence level. This indicated that the proposed method has a good level of
precision and accuracy.
3.4.
Content Uniformity Test:
The
content uniformity test was applied for dosage forms containing for carvedilol or nebivolol
hydrochloride according to USP [55] guidelines. The proposed
method has high sensitivity and has the ability to measure of the drug content
in a single tablet with suitable accuracy and precision. Therefore, the method
is highly suitable for this purpose. The drug content for each single tablet
was determined by applying the proposed procedure and the acceptance value (AV)
was calculated. It was found that the acceptance value was less than the
maximum allowed acceptance value (L1) which confirmed the excellent drug
uniformity of the studied dosage forms (Table 7).
4.
CONCLUSION:
In
this work, silver nanoparticles were applied as chromogenic agent for the quantitative determination of
some beta-blockers based on their promotion effect on Ag-NPs formation. The
suggested method is characterized by its simplicity, sensitivity, and low cost
of the analysis. The analytical procedure could be a useful method for optical
determination and monitoring of beta-blockers in pure and pharmaceutical dosage
forms. Moreover, the proposed method was applied successfully in the content
uniformity testing.
5. REFERENCES:
[21] E.R.
Garrett, K. Schnelle, Separation and spectrofluorometric assay of the β‐adrenergic blocker sotalol from blood and urine, Journal of
pharmaceutical sciences, 60 (1971) 833-839.
[39] X. Xu, J.
Wang, F. Yang, K. Jiao, X. Yang, Label‐Free
Colorimetric Detection of Small Molecules Utilizing DNA Oligonucleotides and
Silver Nanoparticles, Small, 5 (2009) 2669-2672.
Received on 10.09.2016 Accepted on 22.10.2016
© Asian Pharma
Press All Right Reserved
Asian J. Pharm.
Ana. 2016; 6(4): 193-200.
DOI: 10.5958/2231-5675.2016.00029.6