Monitoring the hydrolyzation of aspirin during the dissolution testing for aspirin delayed-release tablets with a fiber-optic dissolution system

Yn Wng, Ping-Ping Xu, Xin-Xi Li,*, Kun Nie, Ming-Fu Tuo,Bin Kong, Jin Chen

aDepartment of Pharmacy, Xinjiang Medical University, Urumqi 830054, China

bXinjiang FOCS Bio-Tech Co., Ltd., Urumqi 830011, China

1. Introduction

Aspirin is widely used as an anti-rheumatic, antipyretic and anti-thrombosis drug[1,2]. The main adverse effects produced by aspirin are gastrointestinal [3], tinnitus [4], Reye's syndrome [5] and so on. These adverse effects of aspirin result almost all from the salicylic acid.

The hydrolyzation of aspirin belongs to second order reaction [6], but with the pH value kept constant, the hydrolyzation was presumed to be pseudo-first order reaction.In recent years, some articles have reported this reaction, but there is no article reporting the effect of hydrolyzation on dissolution testing.

Salicylic acid produced by aspirin in the process of manufacturing or hydrolysis will affect the dissolution testing and assaying. Therefore, it is important to check out the limit of free salicylic acid in aspirin delayed-release tablets and other preparations.In USP30-NF-25,the limit of free salicylic acid in aspirin delayed-release tablets is not more than 4.0%of the labeled amount.

In this study we researched the hydrolyzation of aspirin during the process of dissolution test for aspirin delayed-release tablets.

Figure 1 UV absorbance spectra of salicylic acids and aspirin.

Table 1 Calibration curve equations of aspirin in six channels.

Figure 2 Release profiles of aspirin delayed-release tablets.

2. Materials and method

2.1. Instrument

A fiber-optic drug dissolution in-situ test system (FODT)was developed by Professor JIan Chen's group of Xinjiang Medical University and Xinjiang FOCS Bio-Tech Development Co., Ltd. A UV-visible spectrophotometer (Cintra 40,GBC Scientific Equipment Pty. Ltd., Australia) was utilized for the off-line control of UV determination.

2.2. Reagents and drugs

Aspirin (Lot no. 100113-200302) and salicylic acid (Lot no.100405-100560) reference substances were obtained from the National Institute for the Control of Pharmaceutical and Biological Products of China; aspirin enteric-coated tablets(0.1 g)were supplied by Bayer Vital GmbH(Lot no.BTA6WK5);and all other reagents were of A.R. grade; purified water was prepared in the laboratory and degassed before use.

2.3. Preparation of pH 6.8 phosphate buffer

A mixture of 0.1 M hydrochloric acid and 0.2 M tribasic sodium phosphate (3:1) was prepared; if necessary, it was adjusted with 2 M hydrochloric acid or 2 M sodium hydroxide to pH of 6.8±0.05.

2.4. Preparation of calibration solutions

Calibration solutions of aspirin and salicylic acid were prepared with pH 6.8 phosphate buffer. The aspirin calibration solutions were prepared at concentrations from 20.0 to 120.0 μg/mL. The molarity of salicylic acid solution equaled that of the labeled amount of 100 mg of aspirin delayedrelease tablets diluted in 1000 mL dissolution media, the salicylic acid calibration solutions were prepared at concentrations from 15.4 to 92.4 μg/mL.

2.5. UV spectral characteristics of aspirin

Acetylsalicylic acid is stable in dry air,but gradually hydrolyzes in contact with moisture containing acetic and salicylic acids.Solutions of aspirin and salicylic acid reference substance were prepared with phosphate buffer (pH 6.8) and scanned by UV.

2.6. Linearity

A series of different concentrations of aspirin substance at 20.0%, 40.0%, 60.0%, 80.0%, 100.0% and 120.0% wereprepared. The linearity of each set of standard solutions was performed to test each individual probe.

Table 2 Comparison of the accumulative dissolution rate (%) for aspirin delayed-release tablets by FODT and UV.

2.7. Release test

Release testing was performed with Ch.P Apparatus I, in 750 mL of pH 1.2 dissolution medium for first 2 h, and 250 mL of pH 6.8 phosphate buffer was added for the next 45 min, using probes with 5 mm path lengths. The stirring speed was 100 rpm. The detection and reference wavelengths were set at 280 nm in the acid stage and about 265 nm in the buffer stage, respectively. The real-time drug release data and profiles were obtained by FODT.

For the UV control analysis, dissolution samples were withdrawn at the end of the dissolution test and filtered using 0.80 μm filter membrane. Then we determined the amount of aspirin dissolved by UV at a large wavelength of aspirin and salicylic acid.

3. Results and discussion

3.1. UV spectral characteristics of aspirin

The absorption spectra of aspirin and salicylic acid in phosphate buffer(pH 6.8)are shown in Fig.1.The absorption peaks were at 233 nm and 296 nm. At the wavelength of 265 nm, aspirin and salicylic acid had a different absorbance,so it affected the determination of dissolution rate. According to the UV analysis method in USP, the aspirin enteric-coated tablets were determined at 265 nm, and at the same time the absorbance of salicylic acid was observed at 265 nm as the same absorption point as that of aspirin to deduct the interference by salicylic acid.

Figure 3 UV absorbance spectra of aspirin at different time points.

3.2. Linearity

The series of standard solutions can obtain a proper absorbance range by using a probe of 5 mm path length.The calibration curve equations of aspirin are shown in Table 1.

3.3. Release test

Due to the use of two dissolution media (one is the pH 1.2 medium and the other is the pH 6.8 medium), FODT had to recalibrate for the second medium [7]. Fortunately the software was compiled for delayed-release dosage form with the technique of differential spectra, and we were able to acquire a complete profile for the entire release process.So the difficulty was solved by scanning the blank twice. The dissolution profiles by the FODT are shown in Fig.2.Table 2 shows the cumulative percentages of drug dissolved from the tablets determined by FODT and UV. There was no significant difference between the methods of FODT and UV(P＞0.05).

Drug dissolution-release profiles were obtained in-situ by FODT; the data acquisition interval for FODT was preset at 15 min. The absorption spectra of aspirin displayed differences. At 296 nm, absorptive changes are shown in Fig.3. It shows that the amount of salicylic acid increased when aspirin was dissolved out constantly from the tablets.

At the end of testing, we detected the absorbance of dissolution samples at 296 nm by UV and calculated the percentage of salicylic acid. The results are listed in Table 3.The hydrolyzation of aspirin made the percentage of salicylic acid exceed the limit of free salicylic acid (4.0). We can conclude that the hydrolyzation may affect the detection quality of aspirin delayed-release tablets.

Determination of the release rate of active ingredients from drug formulations is an important procedure in pharmaceutical laboratories. Traditionally, it is analyzed by UV and HPLC. When detecting the dissolution rate of drugs which are capable of hydrolysis with traditional methods, one should quickly remove, filter and dilute samples, and then immediately detect the accumulative dissolution rate (%).Otherwise, it will affect the results of dissolution. It is time consuming and can give only little information on the dissolution behavior of drugs. FODT was proven to be useful for pharmaceutical solid formulation, productive, time savingand can acquire more information than conventional methods.It not only gives the dissolution profiles of drugs, but also gives information on absorption spectra at any time during dissolution tests, enabling us to find all changes during the tests.

Table 3 Percentage of salicylic acid in the dissolution test for aspirin delayed-release tablets.

We would like to acknowledge Xinjiang FOCS Bio-Tech Co.,Ltd.,China,for its contributions to this work.This research was supported by the Xinjiang Medical University Scientific Innovation Fund (No. XJC201129) and Xinjiang Uygur Autonomous Region Natural Science Fund (No. 2011211A041).

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