The development of a meaningful dissolution procedure for drug products with limited water solubility has been a challenge to the pharmaceutical industry. Satranidazole (BCS Class II drug) is a new nitroimidazole derivative with potent antiamoebic action. There is no official dissolution medium available in the literature. In the present study, parameters such as saturation solubility in different pH medium, dissolution behavior of formulations, influence of sink conditions, stability, and discriminatory effect of dissolution testing were studied for the selection of a proper dissolution medium. Results of solubility data revealed that solubility of Satranidazole decreases with an increase in pH. Satranidazole showed better sink condition in 0.1 N HCl as compared to other media. The drug and marketed formulations were stable in the dissolution media used. An agitation speed of 75 rpm showed a more discriminating drug release profile than 50 rpm. Using optimized dissolution parameters (paddle at 75 rpm, 900 mL 0.1 N HCl) greater than 80% of the label amount is released over 60 minutes. UV-spectroscopic method used was validated for the specificity, linearity, precision, robustness, and solution stability. The method was successfully applied to granular formulations and also to marketed tablets containing 300 mg Satranidazole.
Satranidazole (STZ) is a new nitroimidazole derivative with potent antiamoebic action. It is used in the treatment of intestinal and hepatic amoebiasis, giardiasis, trichomoniasis, and anaerobic infections. Its dose is 300 mg twice daily for 3–5 days in the treatment of amoebiasis and 600 mg as a single dose in the treatment of giardiasis and trichomoniasis. It is reported that Satranidazole exhibits significantly higher plasma concentrations than metronidazole and has a plasma elimination half-life of 1.01 h which is significantly shorter than the corresponding metronidazole half-life of 3.62 h [
Dissolution study is particularly important for insoluble or low solubility drugs where absorption is dissolution rate limited. The incorporation of adjuvants (e.g., diluents, lubricants, and surfactants) into the formulation of a solid oral dosage form can cause significant effects on the dissolution rate of drugs, especially those that are hydrophobic and poorly soluble [
Satranidazole was obtained as a gift sample from Alkem Laboratories, Mumbai. Eudragit E100 was obtained from Evonik Degussa, Mumbai. Satrogyl tablets (strength: 300 mg) were purchased from market. All the chemicals and reagents used were of analytical grade.
Two different batches of taste masked granules of STZ were formed by melt granulation technique using stearic acid and Eudragit EPO using different ratio of drug to stearic acid. The composition of the compounded formulation is mentioned below.
The assay of the above two products was performed using previously developed and validated HPLC method, and the contents results were used to calculate the percentage release on each time of dissolution profile. These two products were used to study the discriminatory power of developed method.
Dissolution test was performed in an Electrolab dissolution test system (TDT-08L), in accordance with USP Pharmacopoeia general method. A double-beam UV-Vis spectrophotometer (Shimadzu 1800, Japan) with 1.0 cm quartz cells was used for all absorbance measurements. All the absorbances were carried out at a UV wavelength of 320 nm.
The saturation solubility of Satranidazole was determined in pH 1.2 (0.1 N HCl), 2.1 (0.01 N HCl), 4.5 (acetate buffer), 6.8 (phosphate buffer), 7.4 (phosphate buffer), and distilled water at 37°C. Excess STZ was added to 100 mL of dissolution medium in a conical flask and agitated continuously at room temperature for 8 h on a shaker. The solutions were kept aside for 1 h until equilibrium was achieved. The solutions were then filtered through no. 41 Whatman filter paper, and the filtrate was suitably diluted and analyzed spectrophotometrically at 320 nm.
For poorly soluble drugs, medium selection for dissolution tests is an important step in method validation due to the difficulty to achieve
Sink condition was determined using following equation:
Sink = Sink condition factor.
From preselected, 0.1 N HCl media, dissolution testing was performed on granules
The dissolution rate of STZ from granules of product A was assessed at 50 and 75 rpm, the recommended speeds for USP apparatus II. At 75 rpm, product A exhibited a very rapid dissolution without coning.
A calibrated dissolution apparatus (USP II) was used with paddle at 75 rpm and bath temperature maintained at 37 ± 0.5°C. Nine hundred millilitre freshly prepared 0.1 N HCl solution was used as the dissolution medium. Dissolution samples were collected at 10, 15, 30, 45, and 60 min for immediate-release granules (products A and B) and replaced with an equal volume of the fresh medium to maintain a constant total volume. After the end of each test time, samples aliquots were filtered, diluted in dissolution medium, when necessary, and were analyzed by UV at 320 nm. At each time point, a 5 mL sample was removed from each vessel and filtered into labeled glass tubes, diluted and analyzed by UV at 320 nm. The dissolution of marketed formulation was also carried out in same conditions. The % cumulative release of drug was calculated using standard calibration curve of STZ prepared in 0.1 N HCl.
The
UV-spectroscopic method used for estimation of Satranidazole in dissolution samples was validated by determining the specificity, linearity, precision, robustness, and solution stability according to USP and ICH guidelines [
Placebo batch of the granules was prepared in its usual concentration. Dissolution was performed similarly as that of the STZ granules in 900 mL of 0.1 N HCL as dissolution medium using USP apparatus II at 37 ± 0.5°C at 75 rpm for 1 hr. Aliquots of this solution were filtered, diluted appropriately, and analyzed by UV spectrophotometric method.
Stock solution of 1000 ppm was prepared by dissolving 50 mg drug in 50 mL methanol. From this 2nd stock solution of 100 ppm was prepared in 0.1 N HCL. Further dilutions were carried out to give solutions of 2, 4, 6, 8, 10, 15, 25, and 30
A recovery study was carried out by adding granules equivalent to 80, 100, and 120% of drug in the dissolution vessel. The dissolution test was done for 60 min using 900 mL of dissolution 0.1 N HCL, apparatus 2 rotating at 75 rpm. Aliquots of 5 mL were filtered with quantitative filter and analyzed by UV spectrophotometric method at the final concentrations 13.3, 16.6, and 20
It was performed on 6 doses of granules from same batch and samples were analyzed according to the test method and aliquots were taken at the end of 60 minutes [
Intermediate precision was evaluated to determine the effects of random events on the precision of the analytical procedure. This was done by performing the dissolution on same batch of granules on different day by changing the analyst.
Robustness was studied by changing the wavelength of UV spectrophotometer at 320 ± 2 nm and also by changing agitation rate of dissolution apparatus at 75 ± 2 rpm.
To evaluate solution stability, the sample solution was stored at room temperature and was analyzed by UV spectrophotometer for 24 hrs at various time intervals.
For immediate-release formulations, apparatus 1 (baskets) at 100 rpm or apparatus 2 (paddles) at 50 or 75 rpm is most commonly used. Other agitation speeds and apparatus are acceptable with appropriate justification. For dosage forms that exhibit coning (mounding) under the paddle at 50 rpm, the coning can be reduced by increasing the paddle speed to 75 rpm, thus reducing the artifact and improving the data.
Reference compendia and guidelines of Food Drug Administration, United States Pharmacopeia, Federation International Pharmaceutique, World Health Organization, European Pharmacopoeia, and Japanese Pharmacopoeia recommend the use of rotating paddle between 50 and 100 rpm with volume of 500 to 1000 mL along with surfactant to provide sink condition for insoluble drug products [
The most common way to check the discriminatory power of the method is to test formulations with differences resulting forms, changes in the characteristics of the API, drug product composition, product manufacturing process, and stability conditions [
Drug solubility and solution stability are important properties to be considered when selecting the dissolution medium. From the saturation solubility data and established sink conditions (Table
pH dependent solubility of Satranidazole in different buffer solutions.
pH | Solubility (mg/mL)* | Sink condition |
---|---|---|
1.2 (0.1 N HCl) | 1.5125 | 4.5375 |
2.1 (0.01 N HCl) | 1.1985 | 3.5955 |
4.5 (acetate buffer) | 0.9813 | 2.9439 |
6.8 (phosphate buffer) | 0.8251 | 2.4753 |
7.4 (phosphate buffer) | 0.9825 | 2.9475 |
Distilled water | 0.8133 | 2.4399 |
The solution stability data is represented in Table
Stability data in 0.1 N HCL.
Time | Absorbance | Mean | SD | % RSD |
---|---|---|---|---|
30 minutes | 0.757 | — | — | — |
1 hr | 0.758 | 0.7575 | 0.00071 | 0.093 |
2 hrs | 0.752 | 0.75567 | 0.00321 | 0.425 |
4 hrs | 0.759 | 0.7565 | 0.00311 | 0.411 |
8 hrs | 0.745 | 0.7542 | 0.00581 | 0.770 |
16 hrs | 0.734 | 0.75083 | 0.00975 | 1.298 |
24 hrs | 0.745 | 0.75 | 0.00917 | 1.222 |
The stirring speeds of 50 rpm and 75 rpm for product A were tested. The statistical Student
Product A dissolution tests results
Time in minutes | % Cumulative release |
|
| |
---|---|---|---|---|
50 rpm | 75 rpm | |||
0 | 0 | 0 | 4.4858 | 0.0065 |
5 | 5.91 | 8.65 | ||
10 | 17.57 | 33.15 | ||
15 | 39.62 | 45.29 | ||
30 | 45.88 | 66.67 | ||
45 | 60.43 | 76.48 | ||
60 | 71.38 | 87.59 |
On comparison of dissolution of products A and B the
Comparison of dissolution profile of two products (A and B) with different ratio of drug : stearic acid.
Time (minutes) | Product A |
Product B |
---|---|---|
0 | 0 | 0 |
5 | 8.71 ± 0.426 | 8.02 ± 0.512 |
10 | 33.9 ± 0.299 | 52.99 ± 0.69 |
15 | 46.05 ± 0.343 | 62.68 ± 0.489 |
30 | 65.83 ± 0.378 | 73.40 ± 0.397 |
45 | 78.57 ± 0.418 | 81.66 ± 0.434 |
60 | 87.65 ± 0.404 | 90.01 ± 0.546 |
Similarity factor |
46 | |
Difference factor |
17 |
The
UV spectrum of STZ in 0.1 N HCl.
It was found that dissolution of placebo was having no effect on dissolution of Satranidazole granules. Also the excipients used for the formulation of granules were not showing interference with the maximum absorption of drug.
The calibration curve of STZ in 0.1 N HCL was plotted as shown in Figure
Linearity data.
Concentration (in mcg/mL) | Absorbance |
---|---|
2 | 0.0822 |
4 | 0.1433 |
6 | 0.2175 |
8 | 0.2793 |
10 | 0.3398 |
15 | 0.5057 |
20 | 0.6301 |
25 | 0.7518 |
30 | 0.9204 |
Linearity curve of STZ in 0.1 N HCl.
Limit of quantitation (LOQ) is the lowest amount of analyte in a sample that can be determined with acceptable precision and accuracy under stated experimental conditions. The quantitation limit is expressed as the concentration of analyte in the sample. The standard deviation and related standard deviation for the limit of quantitation were well within the desirable limit of no more than 2.0%. The lowest quantifiable concentration was 5.22 mcg/mL and this parameter can be used for predicting the drug release in low dose formulation.
According to USP guidelines, the recovery for a dissolution test must be in the range of 95–105%. The percent recovery was from 97.21% to 100.98%. The accuracy of the method is acceptable from the results seen in Table
Results of accuracy.
Added amount ( |
Recovered amount ( |
Recovery* (%) | Mean (%) | % RSD |
---|---|---|---|---|
13.3 (80%) | 12.93 | 97.21 ± 1.2430 | 99.1133 | 1.90 |
16.6 (100%) | 16.46 | 99.15 ± 1.3256 | ||
20 (120%) | 20.196 | 100.98 ± 1.5234 |
The percent RSD did not exceed 2% for the repeatability and intermediate precision, demonstrating suitable precision. The results are represented in Table
Method precision/repeatability.
Sample number | % cumulative release at 60 min | |
---|---|---|
Day 1 | Day 2 | |
Analyst 1 | Analyst 2 | |
1 | 87.09 | 88.34 |
2 | 86.23 | 89.23 |
3 | 87.24 | 87.89 |
4 | 88.78 | 86.21 |
5 | 87.65 | 87.47 |
6 | 88.94 | 87.01 |
Mean | 87.655 | 87.691 |
Standard deviation (SD) | 1.042 | 1.052 |
Relative standard deviation (% RSD) | 1.189 | 1.199 |
Mean | 87.673 | |
Standard deviation (SD) | 0.999 | |
Relative standard deviation (% RSD) | 1.139 |
The percent RSD values were within the specified limit of 2% indicating the robustness of dissolution method on changing the agitation rate and also of UV method by changing the wavelength. The results are shown in Tables
Change in wavelength.
Time (minutes) | At 318 | At 320 | At 322 |
---|---|---|---|
Average % release ± SD |
|||
0 | 0 | 0 | |
5 | 8.95 ± 0.5456 | 85.12 ± 0.7678 | 83.98 ± 0.6789 |
10 | 34.01 ± 0.4345 | 98.23 ± 0.6678 | 97.31 ± 0.8012 |
15 | 44.25 ± 0.5987 | 99.81 ± 0.8978 | 98.12 ± 0.5612 |
30 | 66.87 ± 0.6745 | 101.29 ± 0.7809 | 99.24 ± 0.6769 |
45 | 77.12 ± 0.7568 | 76.84 ± 0.5982 | 77.46 ± 0.8145 |
60 | 85.93 ± 0.4768 | 87.09 ± 0.3780 | 85.76 ± 0.4568 |
|
|||
Average at 60 min | 86.26 ± 0.6744 | ||
% RSD at 60 min | 0.839 |
Change in agitation rate.
Time (minutes) | At 73 rpm | At 75 rpm | At 77 rpm |
---|---|---|---|
Average % release ± SD |
|||
0 | 0 | 0 | 0 |
5 | 8.98 ± 0.3987 | 8.17 ± 0.5679 | 8.21 ± 0.5012 |
10 | 35.18 ± 0.5671 | 36.93 ± 0.5712 | 33.94 ± 0.6782 |
15 | 44.45 ± 0.6745 | 42.81 ± 0.7986 | 45.24 ± 0.5867 |
30 | 66.23 ± 0.7681 | 69.81 ± 0.6897 | 66.87 ± 0.6139 |
45 | 76.56 ± 0.8142 | 74.26 ± 0.5893 | 78.43 ± 0.7831 |
60 | 87.32 ± 0.4587 | 88.23 ± 0.6897 | 88.42 ± 0.4879 |
|
|||
Average at 60 min | 87.99 ± 0.7633 | ||
% RSD at 60 min | 0.668 |
By using above optimized dissolution conditions, the dissolution of marketed STZ film coated tablet was performed. The satisfactory % drug release was obtained at the end of 60 minutes. The results are shown in Table
Dissolution of marketed tablet.
Time (minutes) | % cumulative release |
---|---|
0 | 0 |
5 | 9.34 ± 0.432 |
10 | 28.87 ± 0.471 |
15 | 39.1 ± 0.572 |
30 | 65.43 ± 0.503 |
45 | 83.66 ± 0.66 |
60 | 88.1 ± 0.55 |
The dissolution test developed and validated for STZ granules was considered satisfactory. The conditions that allowed the dissolution determination were USP apparatus II (paddle) with 0.1 N HCl dissolution medium at 37.0 ± 0.5°C rotating at a speed of 75 rpm. STZ was found to be stable for 24 hrs indicating good stability of the drug in dissolution medium. The validated method was found to be specific, linear, precise, and accurate. The stated analytical method can be successfully used for
The authors declare that there is no conflict of interests regarding the publication of this paper.
Authors are very much thankful to Dr. P. S. Gide, Principal of Hyderabad Sindh National Collegiate Boards (HSNCB), Dr. L. H. Hiranandani College of Pharmacy, Ulhasnagar, for his continuous support, guidance, and encouragement.