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HPLC/DAD Method Validation of 6-Hydroxyluteolin 7-O-Glucoside Analysis from Salvia plebeia

곰보배추에 함유된 6-Hydroxyluteolin 7-O-Glucoside 분석을 위한 HPLC/DAD 분석법 밸리데이션

  • Lee, Hak-Dong (Department of Plant Science and Technology, Chung-Ang University) ;
  • Paje, Leo Adrianne (Department of Plant Science and Technology, Chung-Ang University) ;
  • Choi, Jungwon (Department of Plant Science and Technology, Chung-Ang University) ;
  • Kim, Juree (Department of Plant Science and Technology, Chung-Ang University) ;
  • Yu, A Ram (Department of Plant Science and Technology, Chung-Ang University) ;
  • Bae, Min-Jung (Technical Assistance Department, The Food Industry Promotional Agency of Korea) ;
  • Lee, Sanghyun (Department of Plant Science and Technology, Chung-Ang University)
  • 이학동 (중앙대학교 식물생명공학과) ;
  • 바헤 (중앙대학교 식물생명공학과) ;
  • 최중원 (중앙대학교 식물생명공학과) ;
  • 김주리 (중앙대학교 식물생명공학과) ;
  • 유아람 (중앙대학교 식물생명공학과) ;
  • 배민정 (한국식품산업클러스터진흥원) ;
  • 이상현 (중앙대학교 식물생명공학과)
  • Received : 2021.07.01
  • Accepted : 2021.08.03
  • Published : 2021.09.30

Abstract

We developed a method to identify and quantify 6-hydroxyluteolin 7-O-glucoside in the powder of Salvia plebeia (PS) using high-performance liquid chromatography coupled with diode array detector (HPLC/DAD) and equipped with reverse-phase INNO C18 column. The analytical method was optimized and validated using novel parameters. The obtained values for the limits of detection and quantification were 3.60 and 10.90 ㎍/mL, respectively. Calibration curve showed good linearity in the concentration range tested (0.00625-0.1 mg/mL, r2 = 1.0000), high accuracy (96.2-101.4%), and precision values (RSD ≤ 0.27%). Our analysis support the use of our method for accurately identifying and quantifying 6-hydroxyluteolin 7-O-glucoside from PS in routine analyses and large-scale extraction processes for content determination.

Keywords

Salvia plebeia belongs to the family Lamiaceae. It is a biannual grass widely distributed in many countries such as Korea, China, and Japan. S. plebeia has been used as a medicinal plant for a long time in Asia to treat inflammatory diseases like common cold, cough, flu, hepatitis, hemorrhoid.1) Many studies have shown that S. plebeia possess various bio-activities such as anti-oxidants,2) anti-cancer,3) anti-inflam-matory,4) hepatoprotective,5) cytotoxic, and anti-microbial6) effects. It is also good for atopy2) and asthma.7) Besides, the plants in the genus Salvia are known to be a rich source of plant secondary metabolites. These include flavonoids,8,9) diter-penoids,10) lignans,11,12) caffeic acid derivatives,1) sesquit-erpenoids13) and essential oils.14)

Currently, people’s interest in health and longevity is rapidly increasing. As a result, interest in natural product-based various foods, medicines, and supplements are also increasing. S. plebeia could be used as a good candidate in developing health functional food and supplements because of its various effects and abundant ingredients. Therefore, it is necessary to develop a marker compound analysis method of S. plebeia and verify if the established analytical method is reproducible and reliable. To the best of our knowledge, there have been many studies reported on the physiological activities of S. plebeia extracts. However, little has been conducted on the analysis of 6-hydroxyluteolin 7-O-glucoside (6-HLG) and validation of its analytical method. Our recent study was able to isolate and identify 15 different materials from S. plebeia including 6-HLG.15) In order to utilize a plant derived material as a functional ingredient, at least one marker compound needs to be standardized, developed, and verified. Analytical method validation is a set of procedures for establishing whether an analytical method is reproducible and provides reliable results when used for the intended purpose.16) These validation procedures have gained wide acceptance as a criterion for determining the validity of analytical methods used for the quality control of health-related functional foods and phar-maceuticals.17)

In this study, we aim to establish a rapid and convenient HPLC analytical method for quantifying the marker compound in the powder of S. plebeia extract (PS). This study validated the established analytical method of functional marker compoound 6-HLG of PS using HPLC/DAD, prior to developing a high value-added functional product using PS.

Materials and Methods

Plant materials and preparation of PS−The raw plant materials were provided by FromBio, Suwon, Korea. Voucher specimen (FIE-SP) was deposited at FromBio, Suwon, Korea. All of the preparation of PS were conducted by The Food Industry Promotional Agency of Korea in December 2020. The dried leaves of S. plebeia were cultivated in Gyeongbuk- do, Korea. Grinded S. plebeia leaves (85 kg) were extracted with water (85°C, 8 h), filtered, and dried using a spray dryer. The extraction yield was approximately 34%.

Instruments and reagents−Chromatographic analysis was performed using an HPLC system (Agilent 1260 Infinity II Quat Pump, CA, USA) equipped with a pump, auto-sam- pler, and diode array detector (DAD WR detector, CA, USA). HPLC-grade solvents, including water, methanol (MeOH), and acetonitrile (ACN), were purchased from J. T. Baker (Phil- lipsburg, PA, USA). Acetic acid (99.7%) was purchased from Samchun Pure Chemicals (Pyeongtaek, Korea). 6-HLG was isolated and identified from S. plebeia in a previous paper (Fig. 1).15) 6-HLG was obtained from Natural Product Institute of Science and Technology (www.nist.re.kr), Anseong, Korea.

HKSOBF_2021_v52n3_186_f0001.png 이미지

Fig. 1. Chemical structure of 6-HLG (6-hydroxyluteolin 7-O- glucoside).

Preparation of sample and standard solutions for HPLC−PS was dissolved in MeOH (70 mg/mL) and filtered through a syringe filter (0.45-μm) to prepare the sample stock solutions. Standard stock solution of 6-HLG was also prepared by dissolving 1 mg of 6-HLG in 1 mL MeOH. To prepare the 6-HLG calibration curve, working solutions were prepared by diluting the stock solution to the desired con- centrations.

HPLC/DAD conditions−HPLC analysis was conducted using reverse-phase HPLC system with an INNO C18 column (25 cm × 4.6 mm, 5 μm). The injection volume was 10 μL and was monitored at 345 nm. It was conducted at room temperature and the flow rate was set at 1.0 mL/min. A gradient elution system was used for analysis. The mobile phase was composed of 0.5% acetic acid in water (A) and ACN (B). The elutions were conducted as follows: 95% A at 0 min, followed by 75% A from 0 to 20 min, then 50% A from 20 to 45 min, 10% A from 45 to 55 min, and 95% A from 55 to 65min, then maintained until 70 min.

Method validation−The specificity, accuracy, precision, linearity, limit of detection (LOD), and limit of quantification (LOQ) of the new HPLC method were validated. The HPLC method was validated following the guidelines provided by the International Council for Harmonisation of Technical Requirements for Pharmaceuticals for Human Use (ICH).18)

The specificity of the method was tested to see whether there was any interference between the retention times and UV spectra of the standards and PS, and if the peaks indicated the presence of the same compounds. HPLC method accuracy was measured by conducting recovery tests in which sample extracts were spiked with four different standard mixtures at various concentrations and calculating the % recovery of the compound in the extract. To validate precision, three different concentrations of sample extracts were used for intraday (repeatability) analysis, and only one concentration for the inter-day (intermediate precision) analysis which was repeated five times. Intra and inter-day precision were examined by calculating the percent of relative standard deviation (% RSD) of the standard on the same day and on three different days, respectively. Linearity was assessed by using five concentration levels of standard solution (0.00625-0.1 mg/mL) with three injections. Using the peak areas measured at 345 nm on the chromatogram, a calibration curve was plotted against the known concentrations of the standard solutions. Linear least-squares regression was used to analyze the standard curve of 6-HLG, and the correlation coefficient (r2 ) of the regression formula were used to validate the linearity. The calibration curve of standard compound was obtained by fitting, and the standard deviation values of the intercept (σ) and the slope (S) were used to calculate the LOD and LOQ. The LOD is the lowest amount or concentration of analyte that can be reliably distinguished from the base line and the LOQ is the lowest amount of analyte that can be quantified with acceptable repeatability and accuracy. The standard deviation of the response and the slope of calibration were used to obtain the LOD and LOQ values. The LOD and LOQ were derived using the following formulas: LOD=3.3 (σ/S) and LOQ=10 (σ/S).

Calibration curve−A calibration curve was prepared by plotting the concentrations of the standard solution with their respective peak areas. The linearity of the calibration curve was determined based on the correlation coefficient (r2), and the 6-HLG concentrations in the samples were then calculated from the calibration curve. The calibration functions were determined based on the peak area (Y), concentration (X, μg/mL), and mean±standard deviation (n=3).

Results and Discussion

An HPLC analytical method used to quantify 6-HLG was developed and validated. 6-HLG was analyzed using HPLC/ DAD, and the results are shown in Fig. 2. Good separation was achieved using our HPLC method with the retention time at 20.8 min. A wavelength of 345 nm was the most effective wavelength for quantifying the main compound 6- HLG and all impurities in a single run. There was no interference in detecting the retention time showing a fine peak resolution of 6-HLG, suggesting that the validated method has high level of accuracy. The chromatograms in Fig. 2 shows absolute separation and the UV spectra showed good detection of 6-HLG. Thus, we can find that 6-HLG is present in PS from their corresponding retention time and UV spectra in Fig. 2. Our findings suggest a good validation of the HPLC approach as it achieved the specificity of the 6-HLG study found in the PS. The quantification parameters for 6-HLG were tested under the HPLC conditions described above. A calibration curve for the isolated compound was constructed by mapping the peak areas of the prepared concentrations, and linear regression was used to assess the linearity. For the evaluation of linearity, five solutions were used with a concentration range of 0.00625-0.1 mg/mL (n=3). The regression equation was calculated by plotting the peak area (y) versus the 6-HLG concentration (x) expressed in mg/mL. The correlation coefficient (r2 = 1.0000) obtained for the regression line indicated a strong linear relationship between the peak area (Table I) and 6-HLG concentration.

HKSOBF_2021_v52n3_186_f0002.png 이미지

Fig. 2. HPLC chromatograms and specificity of 6-HLG (A) and PS (B).

Table I. Linearity, LOD and LOQ of 6-HLG

HKSOBF_2021_v52n3_186_t0001.png 이미지

aY = peak area, X = concentration of standards (mg/mL).

br2 = correlation coefficient for five data points in the calibration (n = 3).

The LOD of 6-HLG is the minimum concentration of the compound that can be detected, and it can be determined using an analytical method and the HPLC instrument. Conversely, the LOQ is the minimum concentration of the analyzed compound that can be quantified with fine precision and accuracy using the instrument and the analytical method. The LOD value obtained in our study was 3.60 μg/mL, whereas the LOQ value was 10.90 μg/mL, indicating that the analytical method used to calculate 6-HLG derived from PS achieved high sensitivity to quantifying 6-HLG (Table I).

The PS (50 mg/mL) was spiked with four concentrations of 6-HLG and the recovery was evaluated to check the accuracy of the analytical method developed. Quadruplet analyses were conducted using four injections. As shown in Table II, recovery rates for 6-HLG ranged from 96.2-101.4%. Acceptable recovery values have been obtained indicating that the analytical method we used to calculate 6-HLG has achieved high accuracy.

Table II. Accuracy for the determination of 6-HLG

HKSOBF_2021_v52n3_186_t0002.png 이미지

Precision was confirmed by measuring the intra-day and inter-day precision levels of the analytical method used for 6-HLG. The results of the analysis are summarized in Table III and IV. The coefficient of variance of the precision values for 6-HLG ranged from 0.19 to 0.41% for intra-day precision experiments and 0.19 to 0.28% for inter-day precision exper- iments. The values obtained were lower than 2%, which meets the criteria recommended by the ICH guidelines. The results indicated that the analytical method to quantify 6-HLG derived from PS showed great reliability. Furthermore, when comparing the intra- and inter-day RSD mean values, a minor difference was observed between the two, but the latter values were slightly lower. It indicates that these compounds are relatively stable after being dissolved over time.

Table III. Intra-day precision for the determination of 6-HLG content

HKSOBF_2021_v52n3_186_t0003.png 이미지

Table IV. Inter-day precision for the determination of 6-HLG content

HKSOBF_2021_v52n3_186_t0004.png 이미지

There have been many studies about flavonoids. Flavonoids are major classes of plant secondary metabolites having huge diversity in their structures, making them valuable. Flavonoids can play many roles in the human body such as skin protection from ultraviolet A/B radiations, anti-photoaging,19) anti-inflammatory, anti-aging,20) anti-allergic, hepatoprotec-tive, neuroprotective, anti-obesity, osteogenic activity, anti-diabetic, anti-viral, anti-diarrheal, anti-fungal, anti-microbial activities, etc.21-24) Glycosidic flavonoids synthesized in plants are used in response to certain abiotic stresses, like drought, high and low temperatures25) and ultraviolet radiations.26)

6-HLG, a type of glycosidic flavonoid, is a luteolin derivative. Luteolin belongs to the family of flavonoids existing in large amounts in fruits and vegetables,27) and also has good bioactivities in response to inflammatory disorders, and epi-lepsy.28) Optimized analytical method for quantifying the glycosidic flavonoid 6-HLG, was validated as a marker compound from PS. 6-HLG was successfully quantified from PS using HPLC/DAD.

In this study, we validated the HPLC analytical method for quantifying 6-HLG as marker compound for PS. To the best of our knowledge, this is the first study to establish an analytical method that utilizes HPLC/DAD to quantify these compound in PS. The objective of our validation study was to establish a method for quantifying the compound of interest. As described in the results section, our HPLC/DAD method proved to be an efficient and effective analytical technique that had satisfactory accuracy and precision to be used as a routine analytical method. Moreover, our previous works were mainly focused on validating various marker compounds present in medicinal plant extracts.29-31)

The consumption of bioactive compounds from plant derived foods is a promising strategy for strengthening immunity and preventing minor/serious illnesses. Glycosidic flavonoid, such as 6-HLG, have many health benefits as mentioned above. These bioactivities suggest that these compounds have great potential for treating an array of problems in the human body. The validation parameters employed in our analytical methodology showed excellent results in terms of the spec- ificity, precision, accuracy. The findings of our analysis support the use of our method for accurately identifying and quantifying 6-HLG from PS in routine analyses and large scale extraction processes for content determination. More- over, our study can provide the first steps in developing health functional products that could contribute in the pharmaceutical industrialization of PS.

Acknowledgments

This research was financially supported by the Ministry of Trade, Industry and Energy (MOTIE) and Korea Institute for Advancement of Technology (KIAT) through the National Innovation Cluster R&D program (P0006892 Crop Growth Information Quantification System and Commercialization of Big Data Services), Korea.

References

  1. Lu, Y. and Foo, L. Y. (2002) Polyphenolics of Salvia - a review. Phytochemistry 59: 117-140. https://doi.org/10.1016/S0031-9422(01)00415-0
  2. Choi, B. K., Lee, S. H., Kim, N. S., Cho, S. Y., Jang, H. H., Kim, J. B., Lee, Y. M., Yoon, S. and Lee, S. H. (2014) Antioxidative and anti-allergic effects of Salvia plebeia R. ethanol extracts. Kor. J. Pharmacogn. 45: 332-337.
  3. Bae, M. J., Ye, E. J., Kim, S. J., Kim, J. M., Yee, S. T. and Park, E. M. (2007) The effects of Plebeiae Herba (Salvia plebeia R. Br.) on the anticancer (in vitro) and activation of immune cells. J. Korean Soc. Food Sci. Nutr. 36: 377-382. https://doi.org/10.3746/jkfn.2007.36.4.377
  4. Jang, H. H., Cho, S. Y., Kim, M. J., Kim, J. B., Lee, S. H., Lee, M. Y. and Lee, Y. M. (2016) Anti-inflammatory effects of Salvia plebeia R. Br extract in vitro and in ovalbumininduced mouse model. Biol. Res. 49: 41-51. https://doi.org/10.1186/s40659-016-0102-7
  5. Jin, X. F., Qian, J. and Lu, Y. H. (2011) The role of hepatoprotective effect of a flavonoid rich extract of Salvia plebeia R. Br. on carbon tetrachloride-induced acute hepatic injury in mice. J. Med. Plants Res. 5: 1558-1563.
  6. Shin, M. K., Kim, S. K., Lee, S. K., Yang, E. Y., Lee, H. O. and Baek, S. H. (2001) Cytotoxicity and antimicrobial effect of the extract of Salvia plebeia. Kor. J. Pharmacogn. 32: 55-60.
  7. Shin, H. J., Gwak, H. M., Lee, M. Y., Kyung, J. S., Jang, K. H., Han, C. K., Yang, W. K. and Kim, S. H. (2019) Enhancement of respiratory protective and therapeutic effect of Salvia plebeia R. Br. extracts in combination with Korean red ginseng. Korean J. Med Crop Sci. 27: 218-231. https://doi.org/10.7783/KJMCS.2019.27.3.218
  8. Gupta, H. C., Ayengar, K. N. N. and Rangaswami, S. (1975) Structure and synthesis of salvitin, a new flavone isolated from Salvia plebeia. Indian J. Chem. 13: 215-217.
  9. Gu, L. and Weng, X. (2001) Antioxidant activity and components of Salvia plebeia R.Br.-a Chinese herb. Food Chem. 73: 299-305. https://doi.org/10.1016/S0308-8146(00)00300-9
  10. Garcia-Alvarez, M. C., Hasan, M., Michavila, A., Fernandez-Gadea, F. and Rodriguez, B. (1986) Epoxysalviacoccin, a neo-clerodane diterpenoid from Salvia plebeia. Phytochemistry 25: 272-274. https://doi.org/10.1016/S0031-9422(00)94549-7
  11. Powell, R. G. and Plattner, R. D. (1976) Structure of a secoisolariciresinol diester from Salvia plebeia seed. Phytochemistry 15: 1963-1965. https://doi.org/10.1016/S0031-9422(00)88856-1
  12. Plattner, R. D. and Powell, R. G. (1978) A secoisolariciresinol branched fatty diester from Salvia plebeia seed. Phytochemistry 17: 149-150. https://doi.org/10.1016/S0031-9422(00)89701-0
  13. Cao, S. Y., Ke, Z. L. and Xi, L. M. (2013) A new sesquiterpene lactone from Salvia plebeia. J. Asian Nat. Prod. Res. 15: 404-407. https://doi.org/10.1080/10286020.2013.769966
  14. Lu, R. M., Pan, L. N., Zhu, X. Y. and Zhong, Z. G. (2008) Analysis of the chemical constituents of essential oils from Salvia plebeian. Lishizhen Med. Mater. Med. Res. 19:164-165. https://doi.org/10.3969/j.issn.1008-0805.2008.01.090
  15. Paje, L. A. (2021) Phytochemical constituents from Salvia plebeia and chemical profiling of three Salvia species. Dissertation, Chung-Ang University, Seoul.
  16. Green, J. M. (1996) Peer reviewed: a practical guide to analytical method validation. Anal. Chem. 68: 305A-309A. https://doi.org/10.1021/ac961912f
  17. Shabir, G. A. (2003) Validation of high-performance liquid chromatography methods for pharmaceutical analysis: Understanding the differences and similarities between validation requirements of the US Food and Drug Administration, the US Pharmacopeia and the International Conference on Harmonization. J. Chromatogr. A 987: 57-66. https://doi.org/10.1016/S0021-9673(02)01536-4
  18. Guideline, IHT. (2005) Validation of analytical procedures: text and methodology. Q2 (R1) 1(20): 05.
  19. Semwal, D., Semwal, R., Combrinck, S. and Viljoen, A. (2016) Myricetin: a dietary molecule with diverse biological activities. Nutrients 8: 90. https://doi.org/10.3390/nu8020090
  20. Wang, T. Y., Li, Q. and Bi, K. S. (2018) Bioactive flavonoids in medicinal plants: structure, activity and biological fate. Asian J. Pharm. Sci. 13: 12-23. https://doi.org/10.1016/j.ajps.2017.08.004
  21. Cirmi, S., Ferlazzo, N., Lombardo, G., Ventura-Spagnolo, E., Gangemi, S., Calapai, G. and Navarra, M. (2016) Neurodegenerative diseases: Might Citrus flavonoids play a protective role? Molecules 21: 1312. https://doi.org/10.3390/molecules21101312
  22. Jiang, H., Xia, Q., Wang, X., Song, J. and Bruce, I. (2005) Luteolin induces vasorelaxion in rat thoracic aorta via calcium and potassium channels. Pharmazie 60: 444-447.
  23. Proestos, C. and Komaitis, M. (2006) Ultrasonically assisted extraction of phenolic compounds from aromatic plants: comparison with conventional extraction technics. J. Food Qual. 29: 567-582. https://doi.org/10.1111/j.1745-4557.2006.00096.x
  24. Shirley, B. W. (1996) Flavonoid biosynthesis: 'new' functions for an 'old' pathway. Trends Plant Sci. 1: 377-382.
  25. Popova, A. V. and Hincha, D. K. (2016) Effects of flavonol glycosides on liposome stability during freezing and drying. Biochim Biophys Acta: Biomembr. 1858: 3050-3060. https://doi.org/10.1016/j.bbamem.2016.09.020
  26. Bussler, S., Herppich, W. B., Neugart, S., Schreiner, M., Ehlbeck, J., Rohn, S. and Schluter, O. (2015) Impact of cold atmospheric pressure plasma on physiology and flavonol glycoside profile of peas (Pisum sativum 'Salamanca'). Food Res. Int. 76: 132-141. https://doi.org/10.1016/j.foodres.2015.03.045
  27. Harnly, J. M., Doherty, R. F., Beecher, G. R., Holden, J. M., Haytowitz, D. B., Bhagwat, S. and Gebhardt, S. (2006) Flavonoid content of U.S. fruits, vegetables, and nuts. J. Agric. Food Chem. 54: 9966-9977. https://doi.org/10.1021/jf061478a
  28. Lodhi, S., Jain, A., Jain, A. P., Pawar, R. S. and Singhai, A. K. (2016) Effects of flavonoids from Martynia annua and Tephrosia purpurea on cutaneous wound healing. Avicenna J. Phytomedicine 6: 578-591.
  29. Lee, J. S., Paje, L. A., Rodriguez, J. P., Kang, K. S., Hahm, D. H., Shim, J. S., Choi, Y. J. and Lee, S. (2020) Validation of an HPLC/UV analysis method for cirsimaritin in Cirsium japonicum var. maackii. Kor. J. Pharmacogn. 51: 217-221. https://doi.org/10.22889/KJP.2020.51.3.217
  30. Lee, J. S., Paje, L. A., Choi, W. H., Cho, E. J., Kim, H. Y., Jacinto, S. D. and Lee, S. (2020) Validation of an optimized HPLC/UV method for the quantification of flavonoids in lotus. Appl. Biol. Chem. 63: 1-6. https://doi.org/10.1186/s13765-019-0484-7
  31. Lee, J. S., Quilantang, N. G., Hahm, D. H., Kang, K. S., Jacinto, S. D., Choi, Y. J., Lee, S. C. and Lee, S. (2020) Optimization of extraction conditions of continentalic and kaurenoic acids from Aralia continentalis by HPLC/UV and their validation. J. Chromatogr. Sci. 58: 672-677. https://doi.org/10.1093/chromsci/bmaa019