Hindawi Publishing Corporation
Chromatography Research International
Volume 2012, Article ID 610427, 8 pages
doi:10.1155/2012/610427

Research Article

Development and Validation of Dissolution Test for Fluconazole
Capsules by HPLC and Derivative UV Spectrophotometry

Josilene Chaves Ruela Corrêa,1 Cristina Duarte Vianna-Soares,2

and Hérida Regina Nunes Salgado1

1 School of Pharmaceutical Sciences, Universidade Estadual Paulista, Rodovia Araraquara-Jaú km 1, 14801-902 Araraquara, SP, Brazil
2 Department of Pharmaceutical Products, Federal University of Minas Gerais, Avenida Antônio Carlos 6627,
31270-901 Belo Horizonte, MG, Brazil

Correspondence should be addressed to Josilene Chaves Ruela Corrêa, josilenechavescorrea@gmail.com

Received 7 December 2011; Revised 26 January 2012; Accepted 27 January 2012

Academic Editor: Bengi Uslu

Copyright © 2012 Josilene Chaves Ruela Corrêa et al. This is an open access article distributed under the Creative Commons
Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is
properly cited.

The purpose of this study is to develop and validate a dissolution test for fluconazole, an antifungal used for the treatment of
superficial, cutaneous, and cutaneomucous infections caused by Candida species, in capsules dosage form. Techniques by HPLC
and UV first derivative spectrophotometry (UV-FDS) were selected for quantitative evaluation. In the development of release
profile, several conditions were evaluated. Dissolution test parameters were considered appropriate when a most discriminative
release profile for fluconazole capsules was yielded. Dissolution test conditions for fluconazole capsules were 900 mL of HCl 0.1 M,
37± 0.5 ◦C using baskets with 50 rpm for 30 min of test. The developed HPLC and UV-FDS methods for the antifungal evaluation
were selective and met requirements for an appropriate and validated method, according to ICH and USP requirements. Both
methods can be useful in the registration process of new drugs or their renewal. For routine analysis application cost, simplicity,
equipment, solvents, speed, and application to large or small workloads should be observed.

1. Introduction

The dissolution can be defined in a narrow sense as the
process by which a solid substance is incorporated into
the solvent to form a solution. However, in a broad sense,
it is more than a simple measurement of solubility rate
and can be better described as physical test to predict the
drug release from a dosage form, for a given area for some
precise time. Fundamentally, this process is controlled by
the affinity between the solvent and the solid substance
and the way by which the pharmaceutical system releases
the drug [1, 2]. According to Mehta and coworkers [3]
dissolution test provides an indication of bioavailability of
a drug and, thus, pharmaceutical equivalence from batch
to batch. The dissolution test is an important tool in
quality control of drugs and it becomes more important for
drugs with relatively low water solubility, including broad
spectrum antifungal fluconazole. Some characteristics of this

drug are not well defined, for instance, its classification
as high or low soluble in water or its classification in the
biopharmaceutical classification system [4–6]. Well-defined
drug features, together with the dissolution studies, can be an
important tool to justify the use of in vitro methods instead
of in vivo methods when they are requested. The aim of
this dissolution study is to contribute to define fluconazole
dissolution conditions, what can be the focus for further
studies.

A dissolution method should be discriminatory, and it
should allow evaluating the performance of the product and
possible changes it may suffer from during the stability study.
According to Marcolongo [7], many variables can influence
the results of a dissolution test. Among these variables we
can find solubility, chemical nature of the drug, the dosage
form, excipients and manufacturing technology employed,
the apparatus used, the stirring speed, the use of devices
for floating dosage forms (sinkers), the volume of media



2 Chromatography Research International

used, pH and temperature of the media, the filtration, and
analytical method employed.

To develop a dissolution method the characteristics of
the drug and its behavior in the chosen test media should be
taken in account. Moreover, the dissolution conditions must
follow the sink conditions (final concentration equivalent to
10% of saturation concentration) [7], and the quantitation
method should be sensitive, selective, accurate, and precise.

Although there are many published analytical meth-
ods for fluconazole, there are few dissolution studies for
fluconazole, as it has been well compiled in a review by
Corrêa and Salgado [8]. Fluconazole dissolution has not been
recommended in any pharmacopeia until December 2010
when it has been incorporated in the capsule monograph in
the Brazilian Pharmacopeia, 5th edition [9]. However, FDA
[10] has recommended dissolution methods since 2004 for
fluconazole suspension and since 2006 for tablets; the FDA-
recommended method for tablets was tested in this study
without good results. In the Brazilian Pharmacopeia [9], the
dissolution method recommended for fluconazole capsule
uses 900 mL of 0.1 M HCl at 37◦C and baskets with 100 rpm
for 30 min with quantitation by spectrophotometry at λ =
261 nm.

The aim of this work is to develop and validate a
discriminative dissolution method for fluconazole capsules
employing two analytical methods to determine fluconazole
by high-performance liquid chromatography (HPLC) and by
first-order derivative UV spectrophotometry (FDS). Prob-
lems encountered by the UV spectrophotometric method,
recommended by the Brazilian Pharmacopeia 5th edition [9]
are discussed.

2. Experimental

2.1. Material and Equipment. Fluconazole chemical refer-
ence (assigned purity 100%) was purchased from Sigma
Aldrich. Bulk drug was kindly donated (EMS, Hortolândia,
SP, Brazil) and was standardized against fluconazole chemical
reference. Capsules were purchased from local market with
150 mg drug label claim. A Hanson SR 8 Plus dissolution
system containing six vessels was used for dissolution tests.

LC grade methanol was purchased from Tedia (Fairfield,
USA). Purified water was prepared in-house by using Direct-
Q water system (Millipore, Billerica, MA, USA). Prior to use,
mobile phase solvents were degassed in an ultrasonic bath for
30 min. Purified water (>18 MOhm cm) was used to prepare
the mobile phase. Solvents were filtered through a 0.45 μm
membrane filter.

An HP 8453 UV-Visible spectrophotometer (Agilent
Technologies, Inc., Santa Clara, CA, USA) with photodiode
array (PDA) and HP ChemStation software with automatic
differentiation was used. A liquid chromatograph (Waters
Corporation, Milford, MA, USA) equipped with a Waters
1525 binary pump, a Rheodyne Breeze 7725i manual injec-
tor, and a Waters 2487 UV-VIS wavelength detector was
used. HPLC analysis was conducted in an RP C18 column
(Symmetry, 5 μm, 4.6 mm × 250 mm, Waters, Milford, MA,
USA).

2.2. Preparation of Standard and Sample Solutions

2.2.1. Dissolution Performance. Fluconazole 150 mg capsules
were dissolved in 900 mL of HCl 0.1 M at 37◦C for 30 min,
using baskets. The collected samples were filtered through
quantitative filter paper, when evaluated by FDS, or through
0.45 μm regenerated cellulose membranes, when evaluated
by HPLC.

2.2.2. LC and UV Determination Method. A stock solution
was prepared by dissolving 50.0 mg of fluconazole in a
100 mL volumetric flask using HCl 0.1 M with 30 min
sonication. Five standard solutions were prepared from stock
solution in different concentrations (135, 150, 165, 180, and
195 μg/mL) by dilution with the same solvent. The range of
concentrations chosen has the used concentration (150 mg
of fluconazole in 900 mL of dissolution media) as the central
concentration. The samples were filtered using quantitative
filter paper, when they were evaluated by FDS, and using
membranes of regenerated cellulose, 0.45 μm, when they
were evaluated by HPLC. Sample, standard, and placebo-
enriched solutions were prepared in the selected central
concentration in the same way.

3. Results and Discussion

3.1. Analytical Development

3.1.1. UV Determination Method. The selectivity of the
Brazilian-Pharmacopoeia-recommended method was evalu-
ated using the compounding fluconazole and its excipients
(capsules and placebo). The calculations of interference were
performed in accordance with the recommendations of USP
32 [11], since the Brazilian Pharmacopoeia does not cite this
calculation, using the following equation. The interference
must not exceed 2%:

100C ×
(

Ap
As

)
×
(
V

L

)
, (1)

where C is the concentration (mg/mL) of standard solution,
Ap and As are the absorbances of placebo and standard
solutions, respectively, V is the volume of medium (mL), and
L is the dosage of the product (mg).

Spectrum results showed a strong interference, caused
by both capsule shells and placebo in the analytical result.
Using the analytical method recommended by the Brazilian
Pharmacopoeia the mean percentage of dissolution for six
fluconazole capsules was 115.21% and the mean percentage
of response for placebo and capsule was 3.94% and 10.70%,
respectively, a total of 14.64%. These results are in accordance
with those obtained by Oliveira and coworkers [12], who
reported fluconazole capsules dissolution. They have shown
a huge interference of the excipients in fluconazole determi-
nation by UV.

In order to eliminate the interference of the excipients
(placebo and capsule) UV-FDS was tested. In general,
the spectral derivation provides simultaneous drugs deter-
minations in association, as well as, increased selectivity.
In addition, there are often an increased sensitivity and



Chromatography Research International 3

220 230 240 250 260 270 280

Wavelength (nm)

Standard and sample solutions

0.06

0.04

0.02

0

−0.02

−0.04

−0.06

−0.08

d1
 (

A
bs

or
ba

n
ce

)

Placebo and capsule solutions

(a)

2.5

2

1.5

1

0.5

0

200 220 240 260 280 300 320 340 360

Wavelength (nm)

38
3

39
0

39
2

21
6

A
bs

or
ba

n
ce

 (
a.

u
.)

Capsule solution

Standard solution

Sample solutionPlacebo solution

(b)

Figure 1: (a) First-order derivative spectra overlay of fluconazole standard, dissolution sample, and placebo and capsule shells solutions. (b)
Zero-order derivative spectra overlay of standard solution, dissolution of fluconazole sample, and capsule shells and placebo solutions.

improved detection limits. The increased sensitivity observed
in the derivative spectroscopy is based on the observation
that the amplitude of the absorbance derivative relative to
the wavelength is inversely proportional to the bandwidth of
the ordinary spectrum. The order of the derivative must be
carefully selected since there is usually an increase in noise
level with increasing order of differentiation [13, 14].

Figure 1 shows the first-order derivative of absorbance
of fluconazole that has an intense and well-defined valley at
268 nm. It was the wavelength chosen. Fluconazole capsule
samples were tested according to the method recommended
by the Brazilian Pharmacopeia [9]. The same samples were
employed to evaluate the derivative spectrophotometric
method. The average interference from placebo and capsules
was again calculated in the same way but using the derivative
spectrophotometric method. The interference was equal to
0.1% due to placebo and 1.98% due to capsules shells. These
values have low analytical significance and are satisfactorily
acceptable. Thus, the interference of excipients (placebo and
capsule) was considerably reduced by using the differentia-
tion.

3.1.2. HPLC Determination. HPLC is a widely used method
of separation with high precision and accuracy. It allows
the separation between the drug and excipients, as well
as degradation products, which is useful as an indicative
stability method.

The analytical development must be developed to obtain
a simple and optimal method. Good results were obtained
using reversed phase C18 (250× 4.6 mm, 5 mm) Water Sym-
metry endcapped column, 1.0 mL/min, water, and methanol
(60 : 40, v/v), injection of 20 μL monitored at λ = 261 nm.

The samples used to test the method recommended
by the Brazilian Pharmacopeia [9] were now employed to
evaluate the HPLC method. The results showed that the
HPLC method is selective, and it was able to separate the
drug from the placebo and capsule (Figure 2).

Figure 2 shows that capsule shells and placebo absorb
energy in UV region (peaks at 5.15 min); however, they
could be well separated from fluconazole (peak at 3.65 min).
The capsule peak was observed in capsule shells and sample
solutions. The peak at 2.45 min, present in all samples, refers
to the dissolution media (HCl 0.1 M), including the blank
solvent.

3.1.3. Dissolution Performance. Fluconazole three different
pKa [15] values, 11.01 ± 0.29, 2.94 ± 0.10, and 2.56 ± 0.12,
correspond to the groups alcohol (proton donor) and two
nitrogens (proton acceptors), respectively. Thus, the aqueous
solubility of fluconazole is greater in solutions with extreme
pH values (above 11.01 and below 2.94), situations in which
the drug would be fully ionized.

However, dissolution of fluconazole capsules was evalu-
ated in deionized water, as recommended by FDA [10], and



4 Chromatography Research International

0.02

0.015

0.01

0.005

0

1 1.5 2 2.5 3 3.5 4 4.5 5 5.5 6

(minutes)963 minutes, 0.01969 a.u.

(a
.u

.) Blank

Blank

Fluconazole standard and sample

Capsule
Placebo

Figure 2: Chromatograms overlay of fluconazole dissolution samples, placebo and capsule shells, at λ = 261 nm.

in HCl 0.1 M at 37◦C. Both baskets and paddles (with and
without sinkers) apparatuses were used in a total medium
volume of 900 mL in all tests to evaluate dissolution profile.
The dissolution media were degassed by sonication for
30 min at 37◦C before initiating the dissolution test. The
final concentration of fluconazole in 900 mL was nearly
165 mg/mL as capsule products contained 150 mg of the
drug. This is in agreement with required sink conditions,
desirable to prevent saturation. Thus, the concentration
165 mg/mL was included to be the central point of the range
used to validate the method.

In the dissolution profile, samples were collected after
5, 10, 15, 20, 30, 45, 60, and 65 min, filtered through
quantitative filter paper, and fluconazole was quantified by
UV-FDS. The dissolution medium was used as blank. The
replacement of media was performed after each collection
using the dissolution media at 37◦C. Both mass withdrawn
and the dilution made for each replacement of media were
taken into account in the calculations for the construction of
the dissolution profiles.

Rotation speeds 75 and 100 rpm were used in each test
with baskets and 50 and 75 rpm with paddles. During the last
5 min, the speed of rotation was changed to 150 rpm in all
tests. The speed can be increased at this point to verify if the
drug contained in the capsule was entirely released during
the test. The results of dissolution profiles using the described
conditions are shown in Table 1 and Figure 3.

Water was used as dissolution medium in Tests 1 and 2, as
recommended by FDA [10]. It shows not to be an appropriate
medium for fluconazole capsules even after 65 min test at the
highest speed because the drug percentage release was below
57%. The HCl 0.1 M dissolution media tested showed better
results.

The paddle apparatus was tested at 50 and 75 rpm, with
and without sinker. The use of sinker made the dissolution
slower, and it is shown comparing Tests 4 and 6 to Tests 3
and 5. Tests 3 and 4, when 75 rpm was employed, showed fast
dissolution in the beginning and low discriminatory power.
Tests 5 and 6 showed slow dissolution in the beginning;
however, at the end the drug was not released from the
dosage form to the dissolution media. It could be realized
after employing 150 rpm for 5 minutes in the end of test that
the concentration of drug increased rapidly.

Baskets were employed in Tests 7 and 8 using HCl 0.1 M
as dissolution media and 100 and 75 rpm, respectively. Test

D
is

so
lu

ti
on

 (
%

)

0

30

60

90

0 30 60

Time (min)

Test 1
Test 5

Test 6
Test 2

Test 3

Test 4
Test 7

Test 8

Figure 3: Dissolution profile obtained for testing fluconazole
150 mg capsules by UV-FDS. Conditions: as in tests 1–8 specified
in Table 1.

0

30

60

90

0 30 60

Time (min)

D
is

so
lu

ti
on

 (
%

)

Figure 4: Dissolution profile for fluconazole capsules. Samples
analyzed using 0.1 M HCl at 37◦C as dissolution media, basket, and
75 rpm. UV method was employed.

7 has shown fast initial dissolution with more than 90% of
drug release after 5 min and therefore a low discriminatory
power. In Test 8, there were small release increases in
fluconazole amount along the test, which has shown a
discriminative profile (Figure 4).

Therefore, basket apparatus, 75 rpm, 900 mL of 0.1 M
HCl at 37◦C as dissolution media, and 30 min of testing



Chromatography Research International 5

Table 1: Dissolution profiles for fluconazole determination: tested parameters and results.

Test Time (min) Medium Medium volume (mL) Apparatus Rotation (rpm)
Average %
dissolution

% R.S.D.

5 39.05 10.58

10 52.79 3.26

15 55.73 3.14

1 20 water 900 Basket 100 56.73 1.16

30 56.65 0.38

45 56.82 0.31

60 56.74 0.60

65 150 56.69 1.11

5 32.29 0.07

10 48.09 4.78

15 50.31 3.21

2 20 water 900 Paddle 75 51.01 2.02

30 51.77 1.57

45 52.48 1.25

60 53.52 1.26

65 150 56.99 0.89

5 86.79 6.23

10 94.14 3.47

15 95.89 2.72

3 20 0.1 M HCl 900 Paddle 75 97.32 3.43

30 98.64 2.40

45 99.19 1.58

60 98.24 1.68

65 150 100.24 2.37

5 85.45 9.69

10 93.92 1.13

15 95.70 0.26

4 20 0.1 M HCl 900 Paddle + sinker 75 96.63 0.73

30 96.34 1.31

45 97.06 1.71

60 97.57 1.37

65 150 100.00 1.43

5 76.67 5.84

10 86.41 1.35

15 88.70 2.58

5 20 0.1 M HCl 900 Paddle 50 89.78 3.47

30 90.44 3.65

45 91.79 2.94

60 92.36 3.81

65 150 101.24 2.77

5 58.10 4.62

10 68.09 6.98

15 71.54 7.02

6 20 0.1 M HCl 900 Paddle + sinker 50 73.34 5.75

30 76.28 4.53

45 78.76 4.70

60 80.19 4.78

65 150 99.05 4.55



6 Chromatography Research International

Table 1: Continued.

Test Time (min) Medium Medium volume (mL) Apparatus Rotation (rpm)
Average %
dissolution

% R.S.D.

5 92.96 6.34

10 98.96 0.32

15 100.07 0.20

7 20 0.1 M HCl 900 Basket 100 100.56 0.39

30 100.47 0.38

45 98.09 0.15

60 98.66 0.23

65 150 98.92 0.87

5 59.50 15.07

10 82.07 4.45

15 93.61 2.19

8 20 0.1 M HCl 900 Basket 75 97.00 1.93

30 97.64 1.36

45 96.43 1.35

60 96.38 1.23

were the conditions chosen for the dissolution of fluconazole
capsules. This method was validated by FDS and HPLC.

3.2. Method Validation. The quantitative methods were vali-
dated according to the ICH [16] and USP [11] guidelines for
development and validation of dissolution methods. Because
nonuniform drug distribution may affect the dissolution test
in the single-dose units, fluconazole capsule samples were
evaluated regarding uniformity content (UC). All fluconazol
capsules UC results obtained by HPLC (between 91.42–
100.2% of labeled value) were within accepted specifications.

The calibration curves were obtained at five fluconazole
concentration levels from 135 to 195 μg/mL for HPLC (λ =
261 nm) and UV-FDS (λ = 268 nm). Lambert-Beer law was
observed at this concentration range. Linearity was evaluated
by the least square method with determinations in triplicate
at each concentration level. Both methods were linear with
this model. Regression equations were y = 2.5×106X−1.1×
104 (r2 = 0.996) for HPLC and y = 0.51439X − 2.9 × 10−3,
(r2 = 0.998) for UV-FDS. The standard deviations of the
regression were 0.83% for HPLC and 0.62% for UV-FDS.
The validity of the assay was verified by means of ANOVA.
According to ANOVA there is a statistically significant linear
regression (Fcalculated > Fcritical; P = 0.05) and there is no
deviation from linearity (Fcalculated < Fcritical; P = 0.05) for
both methods.

The precision of the methods was determined by repeata-
bility (intraday) and intermediate precision (interday). For
repeatability test three curves were constructed with the
established five concentration levels using standard solutions
in the same day; for intermediate precision three curves
were constructed with three concentration levels (high,
intermediate, and low) using standard solutions in a different
day. An interval of two days between repeatability and inter-
mediate precision was observed. The results were expressed
as percentage of relative standard deviation (R.S.D.). The

intraday precision tests showed R.S.D. of 0.81%, HPLC and
0.75%, FDS and interday precision tests showed R.S.D. of
2.29%, HPLC and 2.55%, FDS. These results indicate good
precision.

The accuracy was performed in triplicate using the stan-
dard addition method (enriched placebo). Known amounts
of standard of fluconazole were added to placebo in order
to reach five established concentration levels. The mean
percentage recovery of fluconazole standard found was
98.56 ± 0.82% for HPLC and 98.35 ± 0.88% for UV-FDS
(Table 2). These results indicate an agreement between the
true values and found values.

This paper compares the methods to determine flu-
conazole after dissolution test regarding their precision
accuracy, and repeatability (Table 3). Both methods showed
to be specific, precise, accurate, and linear in the range of
concentration tested.

3.2.1. Dissolution Performance Validation. After several con-
ditions tested for the dissolution test development, appro-
priate parameters were considered optimized whether pro-
vided most discriminatory dissolution profile for fluconazole
capsules. That means test conditions must be able to show
differences in drug release from batch to batch products, as
well as to distinguish possible changes that may occur during
stability studies or shelf-life of the product. The optimal
parameters for fluconazole capsules dissolution are 900 mL
of HCl 0.1 M, 37 ± 0.5◦C using baskets with 50 rpm during
30 min.

Validation of dissolution performance was carried out
by the two methods of quantification, HPLC and FDS.
The concentration of 150 mg of fluconazole in 900 mL of
dissolution media is nearly equal to the central concentration
(165 mg/mL) at the range established.

The precision was determined by repeatability (intra-
day) and intermediate precision (interday). The repeatability



Chromatography Research International 7

Table 2: Recovery data for fluconazole standard solutions added to
the placebo by using the proposed HPLC and UV-FDS.

Method
Added amount

(μg/mL)
Founda amount

(μg/mL)
Bias
(%)

Recoverya

(%) ± R.S.D.

HPLC

135 133.92 0.80 99.20± 0.77

150 148.00 1.33 98.67± 1.36

165 161.28 2.25 97.75± 0.30

180 177.30 1.50 98.50± 0.20

195 192.41 1.33 98.67± 0.65

FDS

135 134.54 0.34 99.66± 1.02

150 147.51 1.66 98.34± 0.17

165 161.93 1.86 98.14± 0.08

180 175.68 2.40 97.60± 0.22

195 190.96 2.07 97.93± 0.15
a
Average of three replicates.

Table 3: Validation parameters for different analytical methods,
UV-FDS and HPLC, to determine fluconazole in capsules.

Parameters FDS HPLC

Analytical curve 0.51439X−2.9 × 10−3 2.5 × 106X −1.1 × 104

Intercept values −2.9 × 10−3 −1.1 × 104

Standard error of
slope

8.8346 × 10−7 19.63

Correlation
coefficient (r2)

0.998 0.996

R.S.D. of
repeatability (%)

0.75 0.81

R.S.D.
intermediate (%)

2.55 2.29

Accuracy (%) 98.35 98.56

R.S.D. of
accuracy (%)

0.88 0.82

LOQ 4.9 × 10−3 1.28 × 10−8

LOD 1.4 × 10−3 3.84 × 10−9

was tested by dissolution of five fluconazole capsules con-
taining 150 mg of drug in duplicate, in the same day; and
intermediate test was evaluated by the same way in a different
day. An interval of two days between repeatability and
intermediate test was observed. The results were expressed
as percentage of dissolution and the R.S.D. The repeatability
results were 97.96% ± 2.01% for FDS and 97.10% ± 2.44%
for HPLC, and the interday results were 96.94%± 2.48% for
FDS and 95.02% ± 2.80% for HPLC. These results indicate
good precision.

The accuracy of the dissolution performance was deter-
mined using enriched placebos. Known amounts of flucona-
zole standard were added to placebos in order to obtain three
concentrations (high, intermediate, and low) of the range
established. The accuracy test was performed in triplicate.
The mean recovery was found to be 98.04% ± 0.89% for
HPLC and 98.86% ± 1.20% for FDS (Table 4) indicating an
agreement between the true values and the values found.

Table 4: Recovery data of dissolution performance obtained by
HPLC and UV-FDS methods.

Method
Added amount

(μg/mL)
Founda amount

(μg/mL)
Bias
(%)

Recoverya

(%) ± R.S.D.

HPLC
135 133.55 1.07 98.93± 0.23

165 160.33 2.83 97.17± 0.55

195 191.14 1.98 98.02± 0.63

FDS
135 135.11 0.08 100.08± 0.42

165 163.40 0.97 99.03± 0.32

195 190.05 2.54 97.46± 0.34
a
Average of three replicates.

4. Conclusions

A discriminative dissolution test for fluconazole capsules
determination was presented in this study. Selective, sen-
sitive, precise, and accurate analytical methods were used
for quantitation. The results showed that the determination
of fluconazole capsules using direct UV spectrophotometry,
recommended in the Brazilian Pharmacopeia, is not enough
selective; however, the developed first-order UV derivative
spectrophotometry and the HPLC showed to be selective
and meet requirements for an appropriate validated method.
Both methods are useful for the registration of new drugs or
their renewal. The application of each method, as a routine
analysis, should be observed considering cost, simplicity,
equipment, solvents, speed, and application to large or small
workloads.

Acknowledgments

The authors wish to thank the EMS Pharmaceutical Com-
pany (Hortolândia, Brazil) for the kind supply of the raw
material and thank the Fapesp, CNPq, FUNDUNESP, and
PADC-UNESP for financial support.

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