Determination of Tea Saponin in Camellia Seed Oil with UV and HPLC Analysis

Abstract

A simple procedure is described for the HPLC and UV determination of tea saponin in tea seed oil. Determinate was accomplished with UV wavelength detection 550 nm for saponification sample, and HPLC was done under conditions: C18 analytical column of TC-C18, 4. 6 × 250 mm, column temperature at room temperature, injected sample volume was 10 μL, mobile phase’s methanol, flow-rate 0.8 ml/min and detection wavelength 280 nm.

Share and Cite:

Ahmed, H. and Wang, C. (2015) Determination of Tea Saponin in Camellia Seed Oil with UV and HPLC Analysis. World Journal of Engineering and Technology, 3, 30-37. doi: 10.4236/wjet.2015.34C004.

1. Introduction

Tea seed oil from Camellia is edible oil with a characteristic of sweet fragrance. Cold pressed from Camellia oleifera and Camellia sinensis has an extensive use in China as cooking oil [1]. It is mainly produced in Hunan and Jiangxi provinces of China. It has been used in herbal medicine because it is considered as a high nutritionary dietary supplement that benefits the digestive system, reduces bad cholesterol, lowers blood pressure, regulates the nervous system and strengthens the immune system. Tea seed oil is recommended by the Food and Agriculture Organization of the United Nation (FAO) as a high quality, healthy vegetable oil because of its nutritional value, which is comparable to olive oil in terms of high oleic acid content, low saturated fat, high antioxidants, and excellent storage qualities. This oil should be considered to tea tree oil, which is entirely separate oil [2]-[4]. Saponin has many biologically active roles, such as hemolysis and fish toxicity. Tea saponin in seed shell of oil-tea camellia is about 5% - 8%, which increases substantially the secondary value of the oil-tea camellia [5] [6]. HPLC detectors were used to estimate tocopherols including ultraviolet, fluorescence and anisometric [7]-[9]. Reversed-phase HPLC currently is the most popular and reliable technique for the analysis of phenolic compounds. The technique has been used mainly with UV detection [10] [11]. Fluorescence detection is more sensitive and selective than UV detection but can’t utilize fluorescence in samples-free alcohol [12]. A saponification step is thus required in order to convert oil esters to their uncontrolled alcohol. Reports on simultaneous analysis of phenolic substances and oil by HPLC [13] [14] dealt with synthetic phenolic antioxidants either in standard mixtures or directly in oil samples with no prior extraction or clean up. With direct injection, most compounds of lower concentrations and extinction coefficients cannot be detected. No reference was found in the literature on the simultaneous determination of natural phenolic compounds after their co-extraction from vegetable oils. The aim of this study was to improve a simple method for the determination of tea saponin in tea seed oil by HPLC and UV detection.

2. Material and Methods

2.1. Main Materials and Instruments

The main materials and instrument used in this study: tea seed oil, tea saponin, distilled water, concentrated sulfuric acid, 77% sulfuric acid, 8% vanillin, sodium hydroxide (NaOH), ethanol and methanol; UV-2008 (UV- visible spectrophotometer scanning) and HPLC as equipment instruments. The materials and the instruments used in this experiment were from the laboratory of the Academy of Cereals, Oil and Vegetable Protein Engineering, College of Food Science and Technology in Huazhong Agricultural University, Wuhan, China.

2.2. UV-Analysis

Preparation of Samples

1) Saponification solution

6 ml of tea oil was weighed in 100 ml flask; 30 ml 1 mol/L NaOH solution was added and heated for 1 h at 95˚C. Remove the ethanol by used decompression of distilled at normal temperature, collect the solution and completed the volume to 100 ml distilled water [15].

2) Standard curve for tea saponin:

a) Preparation of standard tea saponin solution and method of measurement

The standard tea saponin solution (0.95 mg/ml) was prepared in the following steps: 0.1 g standard tea saponin powder (containing 95% tea saponin) was weighted precisely put into a 100 ml volumetric flask. The saponin powder was dissolved in 50% ethanol solution, and then additional ethanol was added to volume, spinal solution 0.95 mg/ml. The standard solution (0.5 ml) was measured and into 10 ml test tubes with a stopper, then put in an ice-water bath, and then 0.5 ml of 8% vanillin solution and 5 ml of 77% sulfuric acid was added. After shaking, the test tube was transferred to an intermittent warm water bath (60C) for 20 min, then for color development cooled in an ice-water bath for 10 min. The sample was allowed to reach room temperature before detecting the absorbance of the solution was used 1cm cuvette at the wavelength of maximum absorption 550 nm in the UV-visible (V-2008 UV-visible spectrophotometer scanning). The blank solution 1:8 (volume ratio) mixtures of vanillin solution and sulfuric acid were prepared as above [16].

3) Standard curve determination:

Series of the standard solution (0 ml, 0.1 ml, 0.2 ml, 0.3 ml, 0.4 ml and 0.5 ml) were taken and the mixed solutions were prepared by the method described as above for measuring absorbance values. The resulting standard curve was assessed with Microsoft excel [5].

2.3 HPLC-Analysis

Preparation and Measurement Method of a Standard Solution

Standard tea saponin (0.4350 g) was dissolved in 80% ethanol in a 50 ml volumetric flask. For a final concentration of 8.7 g/L. Different weights (0.02, 0.1, 0.2, 0.8, 1 g) was taken placed in 50 ml volumetric flasks, ethanol (80%) was added to the line, shaken, filtered through a 0.45 μm micro porous membrane filter, then placed in cooled storage [17]. Conditions of HPLC equipment are as below: C18 analytical column of TC-C18, 4.6 × 250 mm; column temperature at room temperature; injected sample volume 10 μL; mobile phases 10% - 100% methanol; flow-rate 0.8 ml/min; detection wavelength 280 nm [18].

1) Sample preparation

Saponification solution (1 g) was evaluated and diluted to the mark in 50 ml volumetric flasks with 80% ethanol under sanction 5 min, then filtered using micro membrane and stored under refrigerator at 6˚C - 8˚C, before analysis by HPLC [17].

3. Results and Discussion

3.1. Determination of the Formula

According to the absorbance of the standard tea saponin solution and the standard curve (see Figure 1 & Table 1)

Figure 1. Standard curve.

Table 1. Standard curve (UV).

with vanillin sulfuric acid colorimetric method [20], which is obtained at the maximum absorption wavelength of 550 nm at different concentration of tea saponin, the regression equation is as follows:

Then combined with the standard curve, tea saponin content is calculated with equation:

where:

A: absorbance of oil sample, V: volume of tube solution, N: dilution, W: weight of sample (mg)

3.2. Single Factor Experiment

Figure 2 & Table 2 explained the chromognic single factor (vanillin and sulfuric acid) in difference volumes 3.5 - 5.5 ml, but the best results at 5 ml for each one.

3.3. Influence of Color Temperature

Figure 3 & Table 3 shown the absorption of tea saponin increased when the temperature rises from 40˚C to 80 ˚C. However, the good absorption began to decline when the temperature higher than 40˚C. Optimum color temperature is 40˚C - 60˚C.

3.4. Influence of Time

In order to find out the optimum time, several different time tests were conducted. The results (Figure 4 & Table 4) showed that the tea saponin absorption rate increased over time, suggesting balance point of the absorption could reach at that time, which could also be the optimum time is15 - 25 min.

3.5. Optimization of Tea Saponin Conditions and Selection of the Optimum Level

Orthogonal analysis (Table 5) showed that the main determinants order is A > B > C > D. The higher temperature showed greatest complete reaction of the tea saponin. From the results of orthogonal experiment, the best

Figure 2. Chromogenic single factor experiment.

Figure 3. Color temperature single factor.

Figure 4. Chromogenic time single factor.

Table 2. Univariate analysis.

Table 3. Influence of color temperature.

Table 4. The color of time.

Table 5. An experimental program.

condition for tea saponin is A3B3C2D3, at temperature is 60˚C, ratio of chromogenic reagent 0.75:3.75, 4.5, and time is 20 minutes.

3.6. Formula Calculation

Mobile phases (water, methanol) were checked at various compositions in an attempt to resolve with standard tea saponin and saponification sample by HPLC. Figure 5 & Table 6 illustrates the universal curve of stock tea saponin by HPLC. Then combined with the standard curve, tea saponin content is calculated with equation:

where:

Y: an area of standard tea saponin, x: different concentration mg/ml

3.7. Standard Tea Saponin

Figure 6 as showed the standard tea saponin, measured at a wavelength 280 nm, a retention time was 45 min; it can be observed that: chromatography peak shape is high; few impurity peaks before the tall peak, higher peak at 21 min.

3.8. Saponification Oil Sample

Figure 7 showed, separation and analysis time is brief, measured at 280 nm wavelengths and in retention time 45 minimums. They are few impurity peaks before the sample peak, the taller peak at 19.637 min; within the time of higher peak of tea saponin. No impurity peaks out after a sample peak. Standard peak time it’s long (21 min), Compared with previous studies; time peaks at (4. 295 min, 14.8 min and 16.3 min) [18] [19] in difference

Figure 5. Standard curve of Standard tea saponin.

Figure 6. Chromatography of Standard tea saponin.

Figure 7. Chromatography of saponification oil sample.

Table 6. Standard curve (HPLC).

conditions. However, these compounds have a complex phenolic nature and correspond to a hydroxymethyl derivative [20].

4. Conclusion

We use the two based linear regression equations to calculate the oil tea saponin, and the tea saponin quality scores are 1.5%, 1.6%; the results are basically the same. Tests to prove: Determination of tea saponin in camellia oil methods (UV and HPLC) is simple and the effect is great. Using methanol as a solvent with slow flow rate, the consumption has become less, and it’s easy to operate, high recoveries and relative standard deviation are small, precise and accurate.

NOTES

*Corresponding author.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1] Carpenter Jr., A.P. (1979) Determination of Tocopherols in Vegetable Oils. Journal of the American Oil Chemists Society, 5, 668-671. http://dx.doi.org/10.1007/BF02660070
[2] Kelvin, O.G., Thomas, K.W., Okong’o, K.M. and Francis, W. (2013) Extraction and Analysis of Tea (Camellia sinensis) Seed Oil from Different Clones in Kenya. African Journal of Biotechnology.
[3] Peter, J.L. and Di Gioia, J. (2009) Characterization of Tea Seed Oil for Quality Control and Authentication. Waters Journal.
[4] Ma, L., Zhong, H. and Chen, Y. (2012) Study on Tea Saponin Extraction from Shell of Oil-Tea Camellia Seeds. International Conference on Mechanical Engineering and Material Science.
[5] Yan, Y., Wu, Z.L., Zhao, Y.L. and Jiang, C.S. (2011) Separation of Tea Saponin by Two-Stage Foam Fractionation. Separation and Purification Technology.
[6] Jie, L.H., Shao, P., Dan, F.H., Chang, L. and Ming, Y.X. (2012) Extraction of Saponin from Camellia oleifera Cake and Evaluation of Its Antioxidant Activity. International Journal of Food Science and Technology.
[7] Dionisi, F., Prodolliet, J. and Tagliaferri, E. (1995) Assessment of Olive Oil Adulteration by Reversed-Phase High- Performance Liquid Chromatography/Amperometric Determination of Tocopherols and Tocotrienols. Journal of the American Oil Chemists Society, 72, 1505-1511. http://dx.doi.org/10.1007/BF02577844
[8] IUPAC (1987) Standard Methods for The analysis of Oils, Fats and De-rivatives. Method 2.411 (7th Edition). International Union of Pure and Applied Chemistry, Blackwell Scientific Publi-cation, London.
[9] Montedoro, G., Servili, M., Baldioli, M. and Miniati, E. (1992) Simple and Hydrolyzable Phenolic Compounds in Virgin Olive Oil. 1. Their Extraction, Separation, and Quantitative and Semiquantitative Evaluation by HPLC. Journal of Agriculture and Food Chemistry, 40, 1571-1576. http://dx.doi.org/10.1021/jf00021a019
[10] Pirisi, F.M., Angioni, A., Cabras, P., Garau, V.L., Di Teulada, M.T.S., dos Santos, M.K. and Bandino, G. (1997) Phenolic Compounds in Virgin Olive Oils. 1. Low-Wavelength Quantitative Determination of Complex Phenols by High- Performance Liquid Chromatography under Isocratic Elution. Journal of Chromatography A, 768, 207-213. http://dx.doi.org/10.1016/S0021-9673(96)01034-5
[11] Hoehler, D., Frohlich, A.A., Marquardt, R.R. and Stelsovsky, H. (1998) Extraction of Tocopherol from Serum Prior to Reversed-Phase Liquid Chromatography. Journal of Agriculture and Food Chemistry, 46, 973-978. http://dx.doi.org/10.1021/jf970596i
[12] Andrikopoulos, N.K., Brueschweller, H., Felber, H. and Taeschler, Ch. (1991) HPLC Analysis of Phenolic Antioxidants, Tocopherols and Triglycerides. Journal of the American Oil Chemists Society, 68, 359-364. http://dx.doi.org/10.1007/BF02663750
[13] Indyk, H. and Woollard, D.C. (1986) Antioxidant Analysis in Edible Oils and Fats by Normal-Phase High-Perfor- mance Liquid Chromatography. Journal of Chromatography, 356, 401-408. http://dx.doi.org/10.1016/S0021-9673(00)91506-1
[14] Gao, Z., Liu, X., Zhou, Y. and Wu, M. (2007) Study on Phy-tosterol Extraction from Crude Rapeseed Oil. Academic Periodical of Farm Products Processing.
[15] Felix, M.C. (2007) Chinese Herbal Drug Research Trends. P. 152.
[16] Li, X.Q., Ji, C., Sun, Y.Y., Yang, M.L. and Chu, X.G. (2008) Analysis of Synthetic Antioxidants and Preservatives in Edible Vegetable Oil by HPLC/TOF-MS Food Chemi-stry.
[17] Zhong, S., He, G.W., Zhang, C.J., Hua, H. and Yan, Q.Y. (2008) RP2HPLC Determination of Tea Saponin in Tea2 Seed Cake. China Academic Journal.
[18] Tasioula-Margari, M. and Okogeri O. (2001) Simultaneous Determination of Phenolic Compounds and Tocopherols in Virgin Olive Oil Using HPLC and UV Detection. Food Chemistry. http://dx.doi.org/10.1016/S0308-8146(01)00176-5
[19] Okogeri, O. and Tasioula-Margari, M. (2000) Evaluation of Greek Virgin Olive Oil Phenolic Compounds by HPLC/ UV and GC/MS. In: 2000 IFT Annual Meeting Book of Abstracts, Illinois: Institute of Food Technologists, Dallas, Texas, 113.
[20] Zhu, X. (2012) Transesterified Soybean Oil Technology and Establishment of Rapid Determination of Phytosterol. Master Thesis, Northeast Agricultural University.

Copyright © 2024 by authors and Scientific Research Publishing Inc.

Creative Commons License

This work and the related PDF file are licensed under a Creative Commons Attribution 4.0 International License.