Analysis of Soy Isoflavones from a Dietary Supplement Using UPLC with PDA and SQ Detection (2024)

Abstract

This application note provides a rapid method using reversed-phase UPLC to detect and characterize the isoflavone glucoside conjugates present in a commercial soy nutritional supplement using PDA and MS detection.

Introduction

The consumption of soy products has been linked to many health benefits, as they contain isoflavones. Isoflavones are commonly known as phytoestrogens and 12 isoflavones found in soybeans are daidzein (De), glycitein (Gle), and genistein (Ge) and their respective malonyl (6”-O-malonyl-β-glucoside-), acetyl (6”-O-acetyl-β-glucoside-) and glucosyl (β-glucoside-) forms.1 Their structures are shown in Figure 1.

Figure 1. Structures of three soy isoflavones: daidzein, genistein, and glycitein and their conjugates.

Many research studies have indicated that consumption of isoflavone-containing functional foods are associated with a wide variety of health benefits, including prevention of breast and prostate cancers, cardiovascular disease and reduced symptoms of diabetes and postmenopausal bone loss.2–6 These functional foods include soy milk and soy flour.

The approval by the U.S. Food and Drug Administration in 1999, allowing the food industry to promote soy protein for heart health,7 led to an escalation in sales of soy foods as functional foods. These foods are also being promoted for their isoflavones content.

This application note provides a rapid method using reversed-phase UPLC to detect and characterize the isoflavone glucoside conjugates present in a commercial soy nutritional supplement using PDA and MS detection.

Experimental

The isoflavones were extracted from the soy capsules using methanol: water (9:1) liquid extraction and sonification for 10 minutes. The extract was filtered through a 0.45 μm filter.

The mass spectrometer was used in two modes: Full scan (m/z: 50-550) and single ion recording (SIR) mode.

LC Conditions

LC system:

Waters ACQUITY UPLC System

Column:

ACQUITY UPLC BEH C8 Column 2.1 x 100 mm, 1.7 µm

Column temp.:

35 °C

Flow rate:

500 µL/min

Mobile phase A:

0.2% formic acid in water

Mobile phase B:

Methanol

Gradient:

25% B for 0.4 min, 25-40%/1.1 min Hold for 0.8 min

PDA Conditions

PDA:

ACQUITY UPLC PDA

Wavelength range:

205–450 nm

Resolution:

1.2 nm

Sampling rate:

20 spectra/s

MS Conditions

MS:

SQ Detector

Ionization mode:

ESI Positive

Capillary voltage:

2000 V

Desolvation temp.:

400 °C

Desolvation gas:

1000 L/Hour

Source temp:

130 °C

Full scan settings

Cone voltage:

37 V

Acquisition range:

50 to 550 m/z

SIR Settings

A dwell time of 10ms was used for each SIR and a delay of 5ms

Table 1. SIR settings showing cone voltages used for each m/z value.

Results and Discussion

The relative elution order is: glucosyl, malonyl, acetyl, and isoflavone and the retention times are noted in Table 2. The ACQUITY UPLC C8 phase was compared to the equivalent C18 column: C8 was found to give better separation using this solvent method.

Table 2. Retention times for the soy isoflavones and their conjugates.

In this application note there are two methods described: one using full scan and the other an SIR experiment, where ions indicative of the target compounds of interest have been selected.

Full scan provides spectral information (Figure 2) from the fragmentation patterns, which can help with structural determination and is useful when identifying unknown compounds.

Examples of daidzein MS spectra using the full scan method can be seen in Figure 2. For the conjugated isoflavone systems the parent ion of the conjugate ([M+H]+: m/z 417) was present along with the parent ion of the isoflavone ([M+H]+: m/z 255). The m/z 439 and 277 may be attributed to [M+Na]+.

Figure 2. Spectra for daidzein glucoside (daidzin) and daidzein where the parent ions in positive ESI are 417 and 255, respectively.

Using the full scan data it is possible to extract the ions of interest and this procedure has been performed in Figure 3A for m/z 255, 271 and 285. The same procedure was performed for 260 nm from the PDA detector.

Figure 3B shows the selected ions for genistein and the genistein conjugates. The m/z 153 is a product ion from the isoflavone structure (see Discussion).

Figure 3. A: Selected wavelength of 260 nm and full scan MS data with m/z ions for daidzein, genistein and glycitein, extracted from the TIC and B: SIR method and the respective ions for genistein in the soy supplement.

For quantification experiments, SIR is preferred as it provides more sensitivity (Figure 4) than the compared extracted ion full scan data.

Figure 4. Comparison of S/N using SIR data (top) and extracted ion from full scan data (bottom).

Current interest in soy isoflavones is based on a vast literature reporting a wide range of biological properties for genistein and daidzein8–10 and on clinical studies supporting their potential health benefits.12,13

Studies using a tandem quadrupole MS have described that the isoflavones and their glucoside conjugates have a common product ion other than the [M+H]+ from the isoflavone. In the reaction pathway (Figure 5) this product ion may be assigned to [a+1]: for daidzein, genistein and glycitein the m/z values are 137, 153 and 167 respectively.

Figure 5. Fragmentation pathway of daidzein.

It is possible to see the [a+1] ion using the SIR method, which allows a separate higher cone voltage energy to be selected for the three ions from Table 1.

Chromatographic Data Points

When using mass spectrometry, in particular for quantification, it is important to have at least 10 data points across a peak for repeatable peak integration. For UPLC-based experiments where the peak widths are much smaller than comparable HPLC peaks, MS acquisition rates have to be faster to achieve this. Figure 6 shows the comparison of the data points when the dwell time is changed in SIR mode.

Figure 6. Comparison of dwell times and data points.

For the SIR experiment in this application note, a dwell time of 10 ms was used to achieve the recommended data points for the compounds analysed.

Conclusion

In this application note, a soy supplement has been used to look at the soy isoflavone content. With the increasing interest in functional foods and functional ingredients, it is also important to analyse for these compounds in the functional food and also their bio-availability in the body.

Here, a method 5.5 minute method has been described using UV and MS data. For structural information for the compounds a full scan method was used, however, if quantification is required, the SIR method is recommended as it provides better sensitivity.

References

  1. P.A. Murphy, T. Song, G. Buseman, K. Barua, G.R. Beecher, D. Trainer, J. Holden, J. Agric. Food Chem. 47 (1999) 2697
  2. Lamartiniere, C. A. Protection against breast cancer with genistein, a component of soy. Am. J. Clin. Nutr. 2000, 71, 1705S–1707S
  3. Santibáñez J F, Navarro A, Martinez J. Genistein inhibits proliferation and in vitro invasive potential of human prostatic cancer cell lines. Anticancer Res. 1997, 17, 1199–1204
  4. Anderson J W, Johnstone B M, Cook-Newell M E. Metaanalysis of the effects of soy protein intake on serum lipids. N. Engl. J. Med. 1995, 333, 276–282
  5. Mezei O, Banz W J, Steger R W, Peluso M R, Winters T A, Shay N. Soy isoflavones exert antidiabetic and hypolipidemic effects through the PPAR pathways in obese Zucker rats and murine RAW 264.7 cells. J. Nutr. 2003, 133, 1238–1243
  6. Picherit C, Coxam V, Bennetau-Pelissero C, Kati-Coulibaly S, Davicco M, Lebecque P, Barlet J. Daidzein is more efficient than genistein in preventing ovariectomy-induced bone loss in rats. J. Nutr. 2000, 130, 1675–1681
  7. US Food and Drug Administration. Food labeling, health claims, soy protein and coronary heart disease. Fed Regist 1999;57:699–733
  8. Setchell KDR, Adlercreutz H. Mammalian lignans and phytoestrogens. Recent studies on their formation, metabolism and biological role in health and disease. In: Rowland IR, ed. Role of the gut flora in toxicity and cancer. London: Academic Press, 1988:315–34.
  9. Adlercreutz H. Phytoestrogens: epidemiology and a possible role in cancer protection. Environ Health Perspect 1995;7(suppl):103–12.
  10. Kim H, Peterson TG, Barnes S. Mechanisms of action of the soy isoflavone genistein: emerging role for its effects via transforming growth factor signaling pathways. Am J Clin Nutr 1998;68(suppl): 1418S–25S.
  11. Setchell KDR. Phytoestrogens: the biochemistry, physiology, and implications for human health of soy isoflavones. Am J Clin Nutr 1998;68(suppl):1333S–46S.
  12. Setchell KDR, Cassidy A. Dietary isoflavones: biological effects and relevance to human health. J Nutr 1999;129(suppl):758S–67S.
Analysis of Soy Isoflavones from a Dietary Supplement Using UPLC with PDA and SQ Detection (2024)

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