Improved Quality Control Method for Prescriptions of Polygonum capitatum through Simultaneous Determination of Nine Major Constituents by HPLC Coupled with Triple Quadruple Mass Spectrometry
1
Institute of Chinese Materia Medica, China Academy of Chinese Medical Sciences, Beijing 100700, China
2
Jiangxi University of Traditional Chinese Medicine, Nanchang 330006, China
3
Hunan University of Chinese Medicine, Changsha 410208, China
*
Author to whom correspondence should be addressed.
†
These authors contributed equally to this work.
Molecules 2013, 18(10), 11824-11835; https://doi.org/10.3390/molecules181011824
Submission received: 13 June 2013
/
Revised: 28 August 2013
/
Accepted: 4 September 2013
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Published: 25 September 2013
Abstract
:As a traditional Miao-nationality medicinal plant, Polygonum capitatum has been used in clinical practice for several thousand years. Its prescriptions, including three dosage forms: granules, capsule and tablet are known by the brand name Relinqing® and have played an indispensable role in the treatment of urinary system infection, pyelonephritis and kidney stones. However, no study about the comprehensive quality evaluation of Relinqing® has been reported. In the present paper, a method for the simultaneous determination of nine major compounds in three dosage forms of Relinqing® using HPLC coupled with triple quadrupole mass spectrometry (HPLC-QQQ MS) was established to comprehensively evaluate their quality. The nine compounds, including four phenolic acids, four flavonoids and a lignin, were analyzed with acceptable linear regression relationship (r2, 0.9923–0.9992), precision (RSD, 1.25%–2.78%), repeatability (RSD, 2.05%%–3.47%), stability (RSD, 1.84%–3.72%) and recovery (93.60%–108.54%, RSD ≤ 3.67%). The present study fills the gap in the multivariate quality control of Relinqing® and provides a valuable reference for quality standards and dosage reforming of this traditional Chinese medicine.
1. Introduction
Traditional Chinese Medicine (TCM) has been used in clinical practice for several thousand years. TCM has played an indispensable role in the prevention and treatment of diseases, especially the complicated and chronic ones. In recent years, TCM has been attracting more and more attention because of its complementary therapeutic effects to Western medicines, and its capability to deal with many essential problems that have not been solved by conventional medicinal practices. However, the extreme complexity and uncontrolled quality of TCM preparations become the most important problems for the application and development of TCM. Conventional quality control mode is the simply quantitative analysis of one or only a few components, which cannot represent the real quality of herb medicine [1,2,3]. Quantitative analysis of multiple active components is becoming the most direct and indispensable method to move forward the development of TCM [4,5,6].
Relinqing® which has been approved by the Chinese Food and Drug Administration, is commonly used with considerable therapeutic efficacy in the treatment of urinary tract infection, pyelonephritis, cystitis urinary calculi and other diseases [7,8,9]. The Relinqing® capsule and tablets based on Relinqing® granules are prepared proportionally from the TCM Polygonum capitatum Buch-Ham. ex D. As the main active ingredient of Relinqing® and a traditional Miao-nationality medicinal plant, Polygonum capitatum is widely distributed in the minority districts in southwest China. Previous pharmacological studies have demonstrated that aqueous or ethanolic extracts of P. capitatum possessed antibacterial, analgesic, anti-inflammatory, hypothermia, diuretic, and anti-oxidative activities [10,11,12], while chemical investigations showed the presence of flavonoids, phenolic acids, lignans, triterpenoids, steroids, as well as other fatty acid esters in this plants [13,14,15].
Therefore, the active constituents of Relinqing® include flavonoids, phenolic acids and schizandriside. Flavonoids, including catechin, quercetin, quercetin and kampferol are the main biologically active constituents in P. capitatum [16,17,18], which to some extent might explain the mechanisms of the clinical effects of this drug. Phenolic acids are simple non-flavonoid compounds constituting a large group of phenolic compounds which play an important role in the antibacterial activity and anti-inflammatory activity of Relinqing®. Besides, abundant and bioactive schizandriside has been found in Relinqing® [19]. Therefore, flavonoids, phenolic acids and schizandriside contents can be an important index in the quality evaluation of Relinqing® on account of their various pharmacological activities. Unfortunately, few studies on the quantitative determination of chemical constituents in Relinqing® have been reported so far. In previous papers, some flavonoids and phenolic acids were determined by HPLC [20,21,22], but the results could not reflect the drug’s quality exactly and rapidly. In addition, these methods suffered from low resolution and sensitivity. Along with the development of analysis technology, triple quadrupole mass spectrometry (QQQ MS) provides a sensitive and accurate quantification method of multiple low-concentration compounds in the complex system by multiple-reaction monitoring (MRM) mode [23,24]. A rapid resolution liquid chromatography-QQQ MS method was much more suitable for the determination of components in Relinqing® with short analysis time, wide linearity range and low LOD and LOQ.
In present study, nine major compounds including: (1) gallic acid; (2) protocatechuic acid; (3) vanillic acid; (4) syringic acid; (5) catechin; (6) schizandriside; (7) quercitrin; (8) quercetin and (9) kaempferol in 12 batches of Relinqing® from three dosage forms were analyzed by HPLC-QQQ MS. A sensitive and accurate quantification method was established by multiple-reaction monitor (MRM) mode. Linear regression relationship (r2, 0.9923–0.9992), precision (RSD, 1.25%–2.78%), repeatability (RSD, 2.05%–3.47%), stability (RSD, 1.84%–3.72%) and recovery (93.60%–108.54%, RSD ≤ 3.67%), were presented. To the best of our knowledge, this is the first time that HPLC-QQQ MS was used to the simultaneous determination of flavonols, phenolic acids and lignans in Relinqing®. The results have indicated that this advanced method is fast, sensitive and convenient to show the real quality of the formula, which should benefit the quality control and clinical usage of Relinqing®.
2. Results and Discussion
2.1. Optimization of LC-MS/MS Conditions
Mobile phases such as methanol-water, acetonitrile-water, and aqueous acetonitrile-acid solvents were examined to achieve a suitable chromatographic behavior and a satisfactory MS response. The acetonitrile-water solvent provided better chromatographic resolution and MS ionization. Both positive and negative ionization modes were investigated. In the negative mode, the quasi-molecular and production ions were stable and reproducible [25], therefore, the negative ionization mode was chosen for subsequent experiments. In order to get more stable product ions and higher responses, Frag (fragmentor) and CE (collision energy) were optimized because of their important roles in ionization. The retention time (RT), MS information of the quantitative analytes and the HPLC-MS/MS chromatographic spectra of nine markers are listed in Table 1. The HPLC-MS/MS chromatographic spectra of the nine markers are shown in Figure 1.
2.2. Method Validation
2.2.1. Linearity and Detection Limit
The calibration curves, plotted with a series of concentrations of standard solutions, were constructed from the peak-area ratios of each standard to internal standard versus concentrations of each analyte. Nine marker curves were all made at nine levels. Acceptable linear correlation and high sensitivity at these conditions were confirmed by correlation coefficients (r2, 0.9937–0.9992). The limits of detection (LODs) and quantification (LOQs) were calculated as 3- and 10-fold of the ratio of signal-to-noise (S/N); they were 1.0–5.0 ng·mL−1 and 5.0–10 ng·mL−1 for (1) gallic acid; (2) protocatechuic acid; (3) vanillic acid; (4) syringic acid; (5) catechin; (6) schizandriside; (7) quercitrin; (8) quercetin; (9) kaempferol. Detailed information regarding calibration curves, linear ranges, LODs and LOQs is summarized in Table 2.
Table 1.
Characterization of 11 markers on the LC-MS and the optimized MRM parameters for quantification.
| Compounds | Characterization of 11 markers | MRM parameters | ||||
|---|---|---|---|---|---|---|
| RT (min) | M-H/M (m/z) | Lost ions | Quantification transition (m/z) | Frag (V) | CE (V) | |
| Gallic acid | 0.774 | 169 | 125[M-COOH]-; 79[M-COOH-3OH+3H]- | 169→125 | 80 | 10 |
| Protocatechuic acid | 0.793 | 153 | 109[M-COOH-H]-; 91[M-COOH-H20]- | 153→109 | 80 | 10 |
| Vanillic acid | 0.837 | 167 | 152[M-CH3]-; 123[M-COOH]- | 167→152 | 80 | 10 |
| Syringic acid | 0.846 | 197 | 182[M-CH3]-; 153[M-COOH]- | 197→182 | 80 | 20 |
| Catechin | 6.184 | 289 | 245[M-CH3CHO]-; 109[M-2OH-C6H5-CH3CHO-CH3]- | 289→109 | 150 | 20 |
| Schizandriside | 7.634 | 491 | 359[M-xylose]-; 344[M-xylose-CH3]- | 491→359 | 200 | 20 |
| Quercitrin | 8.129 | 447 | 301[M-rhamnose]-; 255[M-rhamnose-COOH]- | 447→301 | 180 | 20 |
| Quercetin | 8.677 | 301 | 179[M-2OH-C6H4-CH2]-; 151[M-2OH-C6H4-CH3CHO] | 301→151 | 150 | 15 |
| Kaempferol | 9.046 | 285 | 117[M-2OH-C6H6-CH2O-2H2O]-; 93[C6H5+OH] | 285→ 93 | 150 | 25 |
| Internal standard1 | 3.021 | 151 | 107[M-COOH]-; 92[M-COOH-CH3]- | 151→107 | 80 | 5 |
| Internal standard2 | 7.749 | 579 | 459[M-glucose+CH3COOH]-; 271[M-glucose-rhamnose]- | 579→271 | 200 | 30 |
| Compounds | Calibration curves | Linear ranges (ng·mL−1) | Correlation coefficient | LOD (ng·mL−1) | LOQ (ng·mL−1) |
|---|---|---|---|---|---|
| Gallic acid | Y = 0.7624X − 1.8747 | 100–10,000 | 0.9937 | 5.0 | 10 |
| Protocatechuic acid | Y = 0.9881X − 0.0169 | 5–500 | 0.9974 | 1.0 | 5.0 |
| Vanillic acid | Y = 0.6889X − 0.6085 | 100–10,000 | 0.9982 | 1.0 | 5.0 |
| Syringic acid | Y = 11.5119X + 68.0960 | 5–1,000 | 0.9992 | 1.0 | 5.0 |
| Catechin | Y = 72.2795X + 637.9497 | 5–1,000 | 0.9965 | 1.0 | 5.0 |
| Schizandriside | Y = 0.0019X − 0.0032 | 50–10,000 | 0.9971 | 5.0 | 10 |
| Quercitrin | Y = 9.6795X − 0.8127 | 5–10,000 | 0.9989 | 1.0 | 5.0 |
| Quercetin | Y = 0.7283X − 0.0865 | 50–10,000 | 0.9991 | 1.0 | 5.0 |
| Kaempferol | Y = 0.3322X − 0.0300 | 10–5,000 | 0.9987 | 1.0 | 5.0 |
Figure 1.
The RRLC-MS/MS analysis MRM chromatograms of the 9 markers.
2.2.2. Precision, Repeatability and Stability
The intra- and inter-day precisions were investigated to evaluate the precision of this method by measuring a mix standard solution consisting of eleven markers under the optimized conditions. Their relative standard deviations (RSD) were less than 2.36% and 2.78%, respectively. Six independent samples of Relinqing® (G1, was randomly selected) were analyzed in parallel by the above-established method for the evaluation of repeatability. The RSD of nine standards were within the range of 2.05%–3.47%. The storage stability (RSD, n = 6) of the measurements for sample (G1, C1 and T1) solution was 1.84%–3.72% within 24 h in the room temperature. These results are displayed in Table 3.
2.2.3. Recovery
Known amounts of each standard solution at high, middle and low concentration levels were mixed with known amounts of Relinqing® samples (G1, C1 and T1). Then the samples were extracted and analyzed by the above-established method, and triplicate experiments were repeated at each level. As shown in Table 4, the recovery rate of nine standards varied from 93.60%–108.54% (RSD ≤ 3.67%), revealing the acceptable recovery and accuracy of this method.
| Compounds | Precision (RSD, n = 6) % | Repeatability (RSD, n = 6) % | Stability (RSD, n = 6) % | |||
|---|---|---|---|---|---|---|
| Intra-day | Inter-day | G1 C1 T1 | ||||
| Gallic acid | 1.68 | 2.11 | 2.75 | 2.27 | 2.35 | 3.16 |
| Protocatechuic acid | 1.59 | 2.35 | 2.17 | 2.38 | 2.67 | 2.78 |
| Vanillic acid | 2.36 | 2.47 | 3.03 | 2.79 | 2.08 | 2.91 |
| Syringic acid | 2.07 | 2.58 | 2.69 | 2.67 | 3.24 | 3.56 |
| Catechin | 1.73 | 2.72 | 2.78 | 3.29 | 2.49 | 2.44 |
| Schizandriside | 2.32 | 2.78 | 3.47 | 2.88 | 2.37 | 3.72 |
| Quercitrin | 1.25 | 1.47 | 2.05 | 1.84 | 2.16 | 2.38 |
| Quercetin | 1.54 | 1.87 | 2.19 | 2.17 | 3.24 | 2.27 |
| Kaempferol | 1.68 | 2.31 | 2.57 | 2.74 | 2.35 | 3.04 |
| Compounds | Granules | Capsule | Tablet | |||
|---|---|---|---|---|---|---|
| Recovery (%) | RSD (%) | Recovery (%) | RSD (%) | Recovery (%) | RSD (%) | |
| Gallic acid | 98.61% | 2.18 | 99.50% | 3.03 | 101.38% | 2.13 |
| 100.65% | 2.33 | 96.91% | 2.45 | 99.76% | 2.65 | |
| 95.68% | 2.46 | 101.05% | 2.19 | 101.33% | 2.29 | |
| Protocatechuic acid | 97.34% | 2.98 | 96.57% | 3.17 | 96.57% | 3.15 |
| 98.29% | 3.10 | 101.47% | 2.27 | 102.25% | 3.27 | |
| 102.51% | 2.78 | 95.00% | 3.66 | 97.70% | 3.26 | |
| Vanillic acid | 98.91% | 2.59 | 104.50% | 2.49 | 101.38% | 3.55 |
| 101.70% | 2.84 | 97.70% | 2.85 | 98.05% | 2.64 | |
| 103.12% | 3.14 | 108.54% | 3.14 | 103.82% | 2.74 | |
| Syringic acid | 102.07% | 3.19 | 102.72% | 2.19 | 101.84% | 2.15 |
| 102.43% | 3.28 | 98.13% | 3.28 | 97.40% | 3.28 | |
| 95.58% | 2.97 | 95.29% | 2.87 | 95.14% | 2.97 | |
| Catechin | 98.68% | 2.46 | 103.88% | 3.26 | 101.85% | 2.46 |
| 107.80% | 2.79 | 95.79% | 2.89 | 102.40% | 2.79 | |
| 98.23% | 3.13 | 95.93% | 3.13 | 97.63% | 3.03 | |
| Schizandriside | 101.36% | 3.28 | 101.98% | 3.08 | 101.20% | 3.48 |
| 101.53% | 3.24 | 95.01% | 3.24 | 100.57% | 2.14 | |
| 98.30% | 2.85 | 97.94% | 2.85 | 97.59% | 2.15 | |
| Quercitrin | 100.97% | 3.77 | 101.22% | 3.27 | 101.83% | 3.67 |
| 102.73% | 3.54 | 101.53% | 3.54 | 104.04% | 3.34 | |
| 99.53% | 3.42 | 98.27% | 3.62 | 98.27% | 2.62 | |
| Quercetin | 97.13% | 2.79 | 95.26% | 2.79 | 101.89% | 2.79 |
| 104.62% | 2.57 | 95.81% | 2.57 | 97.74% | 2.57 | |
| 97.62% | 2.84 | 104.03% | 2.84 | 96.30% | 2.53 | |
| Kaempferol | 93.60% | 2.13 | 95.25% | 2.23 | 97.15% | 2.13 |
| 105.60% | 2.15 | 104.64% | 2.15 | 102.32% | 2.42 | |
| 95.07% | 3.08 | 96.03% | 2.38 | 97.43% | 3.18 | |
2.3. Sample Determination
The developed analytical method has been applied for the identification and quantification of nine target compounds in 12 batches of Relinqing® samples. The contents of nine compounds, based on their respective calibration curves, were summarized in Table 5.
| Samples | Contents of each compound in different relinqing samples | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | |
| G1 | 21,751.04 | 568.31 | 463.72 | 68.92 | 56.31 | 852.04 | 699.64 | 84.32 | 46.95 |
| G2 | 19,667.32 | 587.64 | 457.58 | 70.25 | 58.67 | 657.38 | 687.81 | 80.77 | 45.57 |
| G3 | 20,996.64 | 495.94 | 471.46 | 69.67 | 53.71 | 789.68 | 696.79 | 93.94 | 44.82 |
| G4 | 19,589.24 | 488.73 | 482.88 | 75.39 | 59.86 | 856.41 | 663.84 | 95.63 | 46,78 |
| 20,501.06 | 535.15 | 468.91 | 71.05 | 57.14 | 788.87 | 687.02 | 88.66 | 45.78 | |
| RSD | 5.14% | 9.37% | 2.32% | 4.13% | 4.76% | 11.76% | 2.36% | 8.17% | 2.36% |
| C1 | 17,855.36 | 359.67 | 134.37 | 58.98 | 138.68 | 679.78 | 609.64 | 185.37 | 47.81 |
| C2 | 17,015.81 | 468,95 | 147.63 | 72.74 | 156.42 | 516.89 | 626.79 | 168,98 | 46.03 |
| C3 | 19,389.43 | 443.64 | 159.83 | 65.81 | 140.17 | 591.57 | 614.46 | 174.46 | 44.42 |
| C4 | 18,544.16 | 369,97 | 138.52 | 73.57 | 163.59 | 714,62 | 621.69 | 151.63 | 47.83 |
| C | 18,201.19 | 401.65 | 145.08 | 67.77 | 149.71 | 596.08 | 618.14 | 170.48 | 46.52 |
| RSD | 5.54% | 14.78% | 7.76% | 10.05% | 8.18% | 13.67% | 1.23% | 10.09% | 3.51% |
| T1 | 9,439.76 | 277.79 | 426.14 | 59.42 | 51.37 | 839.17 | 403.48 | 220.17 | 48.96 |
| T2 | 12,920.56 | 321.46 | 437.27 | 66.89 | 59.47 | 765.04 | 409.79 | 160.79 | 42.37 |
| T3 | 15,145.27 | 258.42 | 419.49 | 72.47 | 62.89 | 323.66 | 302.42 | 345.53 | 54.89 |
| T4 | 11,075.44 | 306.54 | 403.72 | 58.81 | 60.34 | 691.74 | 423.54 | 193.41 | 46.54 |
| T | 12,145.26 | 291.05 | 421.65 | 64.39 | 58.51 | 654.9 | 564.50 | 229.97 | 48.19 |
| RSD | 20.21% | 9.72% | 3.32% | 10.11% | 8.51% | 34.94% | 14.43% | 35.12% | 10.85% |
| total | 16,919.17 | 409.28 | 345.21 | 67.73 | 88.45 | 679.95 | 395.07 | 163.03 | 46.83 |
2.4. Discussion
In this paper, the HPLC method coupled with triple quadrupole mass spectrometry was proven to be a reliable and powerful technique for simultaneous determination of nine active components including four phenolic acids, four flavonoids and a lignan in three dosage forms of Relinqing®. The MRM mode of QQQ MS enabled identification of target compounds with high selectivity, even at very low concentrations by comparison with standards. In consideration of the different minor ingredients in different dosage forms of Relinqing® which could cause the diversity of storage stability and recovery, storage stability and recovery were detected in three dosage forms respectively during the methodological study. Owing to the significant structural differences between flavonoids and phenolic acids, two internal standards were used to validate these two kinds of compounds, in order to improve the accuracy and rationality of the experiment. The samples of gallic acids were diluted 10-fold for their high content to make detection value satisfy the linear range.
The gallic acid content should not be less than 23 mg in per Relinqing® particles according to the Chinese Pharmacopeia (2010 Edition). Our experimental results showed that all the three dosage forms of Relinqing® meet the national standard when measured under same dosage conditions. Apart from (1) gallic acid; (2) the contents of protocatechuic acid; (3) vanillic acid; (4) syringic acid; (5) catechin; (6) schizandriside; (7) quercitrin; (8) quercetin; (9) kaempferol, were analysed by MATLAB.According to the average content of target markers in three dosage forms (Figure 2) we suggest it’s more reasonable to use contents of (1) gallic acid; (2) protocatechuic acid; (6) schizandriside and (7) quercitrin together to control the quality of Relinqing® because of their higher and stable amounts in different dosage forms. According to the comparison between different batches in the same dosage form (Figure 3), granules showed better stability than capsules and tablets, a forceful reference to optimizing the dosage of Relinqing®.
Figure 2.
The average content of target markers except gallic acid in three dosage forms.
Figure 3.
The RSD of the 9 markers in different batches of three dosage forms.
3. Experimental
3.1. Materials and Reagents
HPLC grade methanol (Fisher Scientific, Waltham, MA, USA), acetonitrile (Fisher Scientific) and deionized water obtained from a Milli-Q water system (Millipore Corp., Bedford, MA, USA) were used for preparation of mobile phases. All solvents were degassed by ultrasound and an on-line degassing system.
Twelve batches of Relinqing® including four batches of granules G1-G4 (batch No.: from 120202 to 120406), four batches of capsules C1-C4 (batch No.: from 20120710 to 20121102), and four batches of tableta T1-T4 (batch No.: from 20120514 to 20120801) were respectively collected from Guizhou province and Beijing in China.
Standards of: (1) gallic acid; (2) protocatechuic acid; (3) vanillic acid; (4) syringic acid; (5) catechin; (6) schizandriside; (7) quercitrin; (8) quercetin and (9) kaempferol were isolated from Polygonum capitatum and identified by our laboratory. p-Methoxybenzoic acid (internal standard 1) and naringin (internal standard 2) were purchased from Beijing Bailingwei Technology Ltd. (Beijing, China). The purity of all compounds was more than 98% (as determined by HPLC).
3.2. Preparation of Sample Solutions
Twelve batches of Relinqing® samples were pulverized and screened through 250 μm sieves. The obtained fine powder (granules 1.00 g, capsule 0.30 g and tablet 0.50 g, equivalent to 3.33 g of the original medicine, respectively) was accurately weighed and placed in a 100 mL volumetric conical flask with stopper after adding 50 mL of 50% (v/v) methanol to the conical flask, the mixture was extracted with the aid of ultrasound (250 W, 40 kHz) for 60 min according to the Chinese Pharmacopeia (2010 Edition) [25]. A certain amount of 50% (v/v) methanol was then added to the mixture until the original weight was achieved. An appropriate amount of extracting solution was diluted 10-fold. The final solution was filtered through a syringe filter (0.22 μm). The filtrate was stored as sample solution until analysis.
3.3. Preparation of Standard Solutions
The standard stock solutions of: (1) gallic acid; (2) protocatechuic acid; (3) vanillic acid; (4) syringic acid; (5) catechin; (6) schizandriside; (7) quercitrin; (8) quercetin; (9) kaempferol, p-methoxybenzoic acid (internal standard 1) and naringin (internal standard 2) were prepared in 50% (v/v) methanol to the final concentrations of 1 mg·mL−1. Then these analytes were appropriately diluted with 50% (v/v) methanol to provide at nine different concentrations from 10 μg·mL−1 to 1 ng·mL−1, which were used to establish the calibration curves.
3.4. Chromatographic and Mass Spectrometric Conditions
RRLC was performed on an Agilent 1200 system equipped with an Agilent 6410 Triple Quadruple with an electrospray ion source (ESI). A gradient elution system consisting of (A) water and (B) acetonitrile was used. The gradient was started at 5% B and maintained for 2 min at a flow rate of 0.3 mL·min−1, followed by a linear increase to 90% B at the same flow rate from 2 min to 8 min, then maintained for 2 min at 90% B. Chromatographic separation was performed on an Agilent XDB C18 column (2.1 mm × 100 mm, 3.5 μm). The mass spectrometer was operated in the negative multiple reaction monitoring (MRM) mode. The MS analysis conditions were set as follows: nitrogen used as a drying gas at a flow rate of 10 L·min−1 with a temperature of 35 °C, a nebulizer pressure of 30 psi, and an electrospray capillary voltage of 4,000 V. High-purity helium was used as the collision gas.
4. Conclusions
In this paper, the RRLC method coupled with triple quadrupole mass spectrometry was proven to be a reliable and powerful technique for simultaneous determination of nine active components, including four phenolic acids, four flavonoids and a lignin, in three dosage forms of Relinqing®. The MRM mode of QQQ MS enabled identification of the target compounds with high selectivity even at very low concentration by comparison with standards. The rapid analysis performed facilitated the efficient identification and quantification of the target components in Relinqing®. The developed method was demonstrated to be simple, sensitive and efficient, which is significant and comprehensive for quality control of Relinqing®. The established methodology may apply to or widely adapted to other sources to speed up the internationalization of Chinese medicine.
Acknowledgments
All the authors express their sincere thanks for the financial support from the Major Project of Chinese National Programs for Fundamental Research and Development (973 Program) (2010CB530600).
Conflicts of Interest
The authors declare no conflict of interest.
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- Sample Availability: Samples of the compounds—(1) gallic acid; (2) protocatechuic acid; (3) vanillic acid; (4) syringic acid; (5) catechin; (6) schizandriside; (7) quercitrin; (8) quercetin; (9) kaempferol—are available from the authors.
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MDPI and ACS Style
Zhang, K.-X.; Wang, Y.-S.; Jing, W.-G.; Zhang, J.; Liu, A. Improved Quality Control Method for Prescriptions of Polygonum capitatum through Simultaneous Determination of Nine Major Constituents by HPLC Coupled with Triple Quadruple Mass Spectrometry. Molecules 2013, 18, 11824-11835. https://doi.org/10.3390/molecules181011824
AMA Style
Zhang K-X, Wang Y-S, Jing W-G, Zhang J, Liu A. Improved Quality Control Method for Prescriptions of Polygonum capitatum through Simultaneous Determination of Nine Major Constituents by HPLC Coupled with Triple Quadruple Mass Spectrometry. Molecules. 2013; 18(10):11824-11835. https://doi.org/10.3390/molecules181011824
Chicago/Turabian StyleZhang, Kai-Xia, Yue-Sheng Wang, Wen-Guang Jing, Jun Zhang, and An Liu. 2013. "Improved Quality Control Method for Prescriptions of Polygonum capitatum through Simultaneous Determination of Nine Major Constituents by HPLC Coupled with Triple Quadruple Mass Spectrometry" Molecules 18, no. 10: 11824-11835. https://doi.org/10.3390/molecules181011824
