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Article

Ion Selective PVC Membrane Electrode for the Determination of Methacycline Hydrochloride in Pharmaceutical Formulation

1
Pharmaceutical Analysis Laboratory Biological and Medical Research Department, MBC-03-65, King Faisal Specialist Hospital & Research Center, P.O. Box 3354, Riyadh 11211, Saudi Arabia
2
Department of Chemical Engineering, Jiangsu Institute of Petrochemical Technology, Changzhou 213016, Peoples Republic of China
3
P.O. Box 1048, Beijing 102205, Peoples Republic of China
*
Author to whom correspondence should be addressed.
Sensors 2002, 2(10), 424-431; https://doi.org/10.3390/s21000424
Submission received: 10 May 2002 / Accepted: 15 May 2002 / Published: 18 October 2002
(This article belongs to the Special Issue Ion Sensors)

Abstract

:
A plastic membrane electrode for the determination of methacycline hydrochloride was fabricated based on the use of methacycline-tetraphenylborate as the electroactive substance, and dioctylphtalate as the plasticizing agent. It was found that the potential responses of the electrode were influenced by pH of the tested solution when pH>3. Under the condition of pH 2.6, the linear response range, slope (25°C) and detection limit obtained were  3.0×10-2~6.0×10-6M, 52.9mv per decade and 3.4×10-6M ,respectively. The response time of the electrodes was <15 seconds. The values of recovery obtained were 99.2~101.2%. The electrode was successfully applied to determination of methacycline hydrochloride in tablet by direct potentiometric method. The result obtained with the electrode was in good agreement with the value obtained by using the official method (high-performance liquid chromatography).

Introduction

Tetracyclines are widely used as broad spectrum antibiotics for high activity against nearly all gram-positive and gram-negative bacteria. Moreover, it is found that tetracyclines could be applied to diagnosis and therapeutics of carcinomas [1]. Therefore, the study of analytical methods for determination of tetracyclines has been a noticeable project in the field of drug analysis [2,3,4,5,6,7].
Methacycline hydrochloride (MC.Cl), 4-(dimethylamino)-1,4,4a,5,5a,6,11,12a-octahydro-3,5,10,12,12a-pentahydroxy-6-methylene-1,11-dioxo-2-naphthacenecarboxamide monohydrochloride, is an intermediate during the synthesis of oxytetracycline, and possesses higher activity against the bacteria in comparison to tetracycline and oxytetracycline. For the determination of methacycline hydrochloride, high performance liquid chromatography [8] and antibiotics-microbial assay [9] were recommended in some pharmacopoeias. Only few studies on the method for determination of methacycline(MC) in pharmaceutical analysis are reported, including high performance liquid chromatography [10], spectrophotometry [11], phosphorimetry [12] and thin-layer chromatography [13,14]. Ion-selective electrodes are playing an important role in pharmaceutical analysis [15,16,17] due to its simplicity, rapidity and accuracy over some other analytical methods. Recently, it is realized to show dramatically improved detection limits, which can only be achieved by using any other electrochemical technologies [18]. To the best of our knowledge, however, no methacycline ion-selective membrane electrode has been reported. In present paper, a methacycline ion-selective PVC membrane electrode is developed based on the use of ion-pair compound of methacycline-tetraphenylbroate (MC-TPB) as the electroactive substance, and dioctylphthalate(DOP) used as plasticizer. The performances of the electrode along with the other related methacycline-selective electrodes which were fabricated by using the respective ion-pair compounds,methacycline-silicotungstate (MC-SiT) and methacycline-phosphotungatate (MC-PT),as the corresponding electroactive substance in the membrane are investigated experimentally, and the proposed electrode was successfully applied for the determination of MC.Cl in the pharmaceutical tablet formulations.

Experimental

Reagents

Sodium tetraphenylborate, phosphotungstic acid, silicotungstic acid were commercially available (Fluka, Buchs, Switzerland). Dioctyl phthalate (DOP), dibutyl phthalate (DBP), poly (vinyl chloride) (PVC) of relatively high molecular weight were used. Methacycline hydrochloride (MC.Cl) was obtained in the pure raw material, which was of Chinese pharmacopoeia grade [8], and the pharmaceutical formulation from a local pharmaceutical company. All the reagents and solvents were of analytical reagent grade. Deionized water was used throughout the study.
Diluted hydrochloride acid (pH 2.6) was prepared which was used as a background solution for preparation of standard solution of MC.Cl or sample solutions.
A 0.1M stock solution of MC.Cl was prepared by dissolving the appropriate, accurate amount of the pure drug in the background solution. A 1.0×10-2~1.0×10-6M solution of MC.Cl were prepared daily by sequential dilution of the appropriate stock solution with the background solution. All solutions of MC.Cl were kept in brown bottles.

Preparation of Ion-pair Compound

Ion-Pair Compound of Methacycline - Tetraphenylborate (MC-TPB): About 20 mL of 0.01 M solution of MC was mixed with 25 mL of 0.01M solution of tetraphenylborate under stirring. The resulting precipitates were filtered off, washed with water, dried at 60°C.The preparation of the ion-pair compound, methacycline-silicotungstate (MC-SiT),was conduced with the similar procedures but using 0.01 M silicotungestic acid.
Ion-Pair compound of Methacycline –Phosphotungstate: The preparation of methacycline-phosphotungstate(MC-PT) was carried out by mixing the two solutions at the ratio of volume,65:20,i.e.,65mL of 0.01M solution of MC was mixed with 20 mL of 0.01M solution of PT. The other procedures are similar to the one state above. The composition of the ion-pair compound, (MC)3PT, was confirmed by elemental analysis data. Hereafter this ion pair compound was still represented as MC-PT.

Preparation of the Electrode

For MC-TPB electrode (electrode A), the mixture of PVC cocktail was prepared by dissolving 0.5mg of MC-TPB,31.5mg of PVC,68.0mg of DOP in 2.5mL of tetrahydrofuran. The sensing membrane was prepared by pouring the mixture onto a glass dish (ca.4cm diameter) and allowed to dry at room temperature. The cocktails and sensing membranes for both MC-SiT electrode (electrode B) and MC-PT electrode (electrode C) were prepared analogously, the compositions of the sensing membrane prepared were 1.0 wt% MC-SiT,57.2 wt% DOP, 41.8 wt% of PVC for the electrode B, and 10.0 wt% of MC-PT,45.0 wt % of DBP, 45.0 wt % of PVC for the electrode C, respectively.
The PVC membrane electrodes were constructed using similar procedures described previously [19]. A membrane (ca.16-mm diameter) was cut out and glued to the polished end of a PVC tube by using a PVC (ca. 5 wt % )- THF solution. The Ag-AgCl electrode and 1.0 ×10-3 M of MC.Cl solution were used as the reference electrode and the internal filling solution of electrode, respectively.
The assembled electrodes were conditioned by soaking into 1.0 ×10-3 M of methacycline hydrochloride solution for 2h before the use of electrodes. When not in use, the electrodes were stored in air.

Measurement of Electromotive Force (emf)

A methacycline-selective PVC electrode and a saturated calomel electrode(SCE) were used as the indicating electrode and the reference electrode, respectively. The emf measurements were carried out at room temperature with a Model pHs-2 precision pH-meter in the following cell:
S.C.E. / test solution / ISE
The test solution were constantly stirred with magnetic stirring.

Analytical Method for Pharmaceutical Formulation

Two methacycline hydrochloride tablets were weighted accurately, crushed and mixed in a mortar, and dissolved in 30mL of the background solution under stirring condition. The solution was transferred into a 50-mL volumetric flask, then completed to the mark with the background solution. 5 mL of this solution was taken and transferred into an another 50-mL volumetric flask, completed to volume with the background solution. The methacycline selective PVC membrane electrode and the reference electrode were immersed into the test solution. The content of MC in the tablets was determined by using the direct potentiometric method.

Results and Discussion

Optimization of the Membrane Composition

In the previous experimental investigations [19,20,21], it is obvious that both kind of plasticizer selected and the membrane composition used can influence the response performances (such as the sensitivity, linear concentration range, the detection limit, the response time etc.) of a PVC membrane ion-selective electrode, if other properties of the electrode, e.g. selectivity or the pH response, are omitted. In this study, three plasticizers, DOP, DBP and DNP, were used to examine the optimization of the membrane with plasticizer entailed the use of plasticizer content (ratio) of 60.0,64.0,68.0 wt %, and the use of PVC contents of 39.0,35.0,and 30.0 wt %. The electroactive compound (MC-TPB) contents of 0.5,1.0,1.5 wt % were used and the sum of percentage for the three components was adjusted to 100 %.The results obtained showed that the response performances of the electrode prepared were rather different depending on the use of plasticizer, the proportion of the plasticizer toward PVC and of the electroactive compound. The typical potential responses of the electrodes constructed with three plasticizers were given in Figure 1. As shown in Fig.1,the DOP-PVC electrodes were superior to DBP- and DNP- PVC electrodes in both the response slope and linear concentration range. So DOP was selected as the plasticizer of liquid membrane electrode. The best membrane composition of the DOP-PVC electrode was 31.5(w/w) % DOP,67.8(w/w) % PVC and 0.7(w/w) % ion-pair which is used in this study.
Figure 1. Optimization of plasticizers. DBP(■)(the PVC membrane composition: DBP 64.0 wt%, PVC 34.5 wt%, MC-TPB 1.5wt%);DOP(●) (DOP 68.0 wt%, PVC 31.5 wt %, MC-TPB 0.5 wt%); DNP(▲) (DNP 60.0 wt%, PVC 39.0 wt%, MC-TPB 1.0 wt%).
Figure 1. Optimization of plasticizers. DBP(■)(the PVC membrane composition: DBP 64.0 wt%, PVC 34.5 wt%, MC-TPB 1.5wt%);DOP(●) (DOP 68.0 wt%, PVC 31.5 wt %, MC-TPB 0.5 wt%); DNP(▲) (DNP 60.0 wt%, PVC 39.0 wt%, MC-TPB 1.0 wt%).
Sensors 02 00424 g001

Response Characteristics of Electrode

The response characteristics of the MC-TPB electrode (electrode A), MC-SiT electrode (electrode B) and MC- PT electrode (electrode C) are summarized in Table 1 and shown in Figure 2. As can be seen, the potential response of the proposed electrode (electrode A) at varying concentration of methacycline hydrochloride displays the widest linear response range toward MC, being in the concentration range of 6.0×10-6 to 3.0×10-2 M with a Nernstian slope of 52.9 ± 0.2mV per decade. The limit of detection was 3.4 ×10-6M. All the electrodes show a very short response time (≤15s) over a MC concentration range of 1.0×10-1 to 1.0×10-4 M. The stability of electrode A was monitored continuously at 1.0×10-3 M of MC solution and evaluated for a period of 6h, the potential drift obtained was ≤ 0.13 mV/h.
Figure 2. Calibration curves of the electrodes. Electrode A(●);Electrode B(□);Electrode C(∆).
Figure 2. Calibration curves of the electrodes. Electrode A(●);Electrode B(□);Electrode C(∆).
Sensors 02 00424 g002
The repeatability of the potential reading for electrode A was examined by subsequent measurements in 1.0×10-3 M of MC solution immediately after measuring the first set of solution at 1.0×10-4 M of MC solution. The standard deviations of measuring emf for 5 replicate measurements obtained are 0.20 mV for the solution of 1.0×10-4 M and 0.11mV for the solution of 1.0×10-3 M. This means that the repeatability of potential response of the electrode is good. The response properties of the proposed electrode did not change obviously after the use of the electrode for two months.
Table 1. Response Characteristics of the Electrodes.
Table 1. Response Characteristics of the Electrodes.
ParameterElectrode AElectrode BElectrode C
Slope (mV per decade)52.950.246.5
Linearity range (M)3.0×10-2~6.0×10-65.0×10-3~1.0×10-56.0×10-3~2.0×10-5
Correlation coefficient0.99980.99950.9874
Detection limit (M)3.4×10-63.4×10-61.0×10-5
Response time a (s)≤10≤15≤15
a The concentration ranges of MC tested were 1.0×10-1~1.0×10-4 M.

Effect of pH

The effects of pH on the responses of the electrodes were examined by measuring the potential variation in the emf over the pH range of 1.0-11.5 and the results were shown in Fig. 3. For the electrode A ,as can be seen, the smaller changes in the potentials occurred in the pH ranges of both 2.0-3.0 and 5.0-6.0, beyond which the change of the potential was considerable. It is known that tetracyclines are unstable due to either forming the isomeric compounds containing inner ether at basic solution or undergo dehydration at acidic solution (pH <2 ) [20] .So a pH range of 2.0-3.0 can be used as the pH working range for the methacycline-selective electrode. To enable a simple measurement protocol and keep the pH value of all the test solutions within the desired range (pH2.0-3.0), as those of methacycline hydrochloride standard solutions, a diluted hydrochloric acid at which a pH value is fixed between 2.0-3.0 was used as the background solution in this study. It is obvious that the advantage of the background solution used eliminate the pH adjustment.
Figure 3. Effect of pH on the potential of the electrode. Electrode A(□); Electrode B(■); Electrode C(○).
Figure 3. Effect of pH on the potential of the electrode. Electrode A(□); Electrode B(■); Electrode C(○).
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Selectivity of the Electrode

The selectivities of electrodes were investigated by the separate solution method (ai= aj=10-3M) and the potentiometric selective coefficients, which were calculated by the similar equation as described previously [21], summarized in Table 2. As be seen from Table 2, the inorganic cations such as K+,Na+,Ca2+,Mg2+ etc. and the organic compounds tested , citric acid and L-glutamic acid do not interfere. Moreover, the excipients, such as corn starch, gelatin, magnesium stearate etc., in the methacycline hydrochloride tablets do not interfere with the determination of methacycline. In addition, it is also seen that the electrode B possesses the better selectivity over the other electrodes (see Table 2). This attributed probably to the large difference in the mobilities and permeabilities of the ions in MC-SiT electrode membrane as compared to the primary ion (MC.Cl).
Table 2. Selectivity Coefficients of Electrodes.
Table 2. Selectivity Coefficients of Electrodes.
Interfering species(j)Log KpotMC,j
Electrode AElectrode BElectrode C
   Na+1.012.021.12
   K+1.112.201.32
   NH+41.112.311.49
   Ca2+2.493.722.60
   Mg2+2.503.802.20
   Al3+2.803.892.72
  Citric acid1.122.321.20
  L-Glutamic acid1.152.321.02

Analytical Application of the Electrode

With the electrode A, accuracy of the proposed method for determination of methacycline hydrochloride was assessed by determining 95~385 μg /mL methacycline hydrochloride solutions using the direct potential method and the data obtained showed in Table 3 which indicates the average recovery and standard deviation to be 99.8% and 0.8%, respectively. The direct potential method was applied to the determination of methacycline hydrochloride in pharmaceutical tablets (ca.100mg methacycline hydrochloride/tablet, Huai Yin Pharmaceutical Works, batch number: 20000113B) and compared with the pharmacopoeia method (High-performance liquid chromatography) [8]. The mean value and the relative standard deviation obtained by using methacycline selective PVC membrane electrode method was 96.1 mg/tablet and 0.5% (n=6) respectively while the mean value obtained with the pharmacopoeia method was 96.4 mg/tablet.
Table 3. Recovery of Metacycline Hydrochloride.
Table 3. Recovery of Metacycline Hydrochloride.
Added a / mgFound b /mgRecovery c / %
4.794.7899.8 ± 0.6
9.589.5499.6 ± 0.8
19.1619.1599.9 ± 1.1
  • a Total volume of the tested solutions was 50.0 mL.
  • b Average of five determinations.
  • c Mean of recoveries ± standard deviation.

Conclusion

A Methacycline-selective PVC membrane electrode based on the ion-pair compound of MC-TPB and DOP as plasticizer was developed . Its linear range, slope and limit of detection were 3.0×10-2~6.0×10-6 M ,52.9mV per decade and 3.4×10-6 M, respectively. The effect of pH on the potential response indicated that larger influence of pH occurred when pH of the solution was in the range of 3~5. The response properties of electrodes based on the ion-pair compounds, MC-PT and MC-SiT, were also investigated experimentally. The linear range of MC concentration for electrode constructed with the ion-pair compound MC-TPB was wider than that of electrodes based on the ion-pair compound MC-PT or MC-SiT. The proposed electrode was successfully applied to the determination of methacycline hydrochloride in pharmaceutical preparation. The analytical method proposed proved to be a simple, rapid and accurate method.

Acknowledgement

One of authors (X.X. Sun) thank the department of education of Jiangsu Province for the financial support of this work. Also the author (H.Y.A.-E) would like to thank the administration of King Faisal Specialist Hospital and Research Centre for its support for the Pharmaceutical Analysis Laboratory research program.

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  • Sample Availability: Available from the authors.

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MDPI and ACS Style

Aboul-Enein, H.Y.; Sun, X.X.; Sun, C.J. Ion Selective PVC Membrane Electrode for the Determination of Methacycline Hydrochloride in Pharmaceutical Formulation. Sensors 2002, 2, 424-431. https://doi.org/10.3390/s21000424

AMA Style

Aboul-Enein HY, Sun XX, Sun CJ. Ion Selective PVC Membrane Electrode for the Determination of Methacycline Hydrochloride in Pharmaceutical Formulation. Sensors. 2002; 2(10):424-431. https://doi.org/10.3390/s21000424

Chicago/Turabian Style

Aboul-Enein, Hassan Y., Xian Xiang Sun, and Cheng Jun Sun. 2002. "Ion Selective PVC Membrane Electrode for the Determination of Methacycline Hydrochloride in Pharmaceutical Formulation" Sensors 2, no. 10: 424-431. https://doi.org/10.3390/s21000424

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