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. 2019 Dec 13;8(12):604.
doi: 10.3390/plants8120604.

The Quality Assessment of Commercial Lycium Berries Using LC-ESI-MS/MS and Chemometrics

Mariam Jarouche  1 Harsha Suresh  2 James Hennell  1 Shaun Sullivan  1 Samiuela Lee  3 Swastika Singh  1 Declan Power  2 Cindy Xu  4 Cheang Khoo  4
Affiliations

The Quality Assessment of Commercial Lycium Berries Using LC-ESI-MS/MS and Chemometrics

Mariam Jarouche et al. Plants (Basel). .

Abstract

Lycium (also known as Goji berry) is used in traditional Chinese medicine (TCM) with claimed benefits, including eye and liver protection, immune system fortification and blood glucose control. The commercially available product comes from either the L. barbarum or L. chinense species, with the former dominating the marketplace due to its better taste profile. The main objective of this study was to develop a validated LC-ESI-MS/MS method to quantify multiple key bio-active analytes in commercially available Lycium berries and to qualitatively assess these samples using a principal component analysis (PCA). A LC-ESI-MS/MS method for the quantitation of seven analytes selected using the Herbal Chemical Marker Ranking System (Herb MaRS) was developed. The Herb MaRS ranking system considered bioavailability, bioactivity and physiological action of each target analyte, its intended use and the commercial availability of an analytical standard. After method optimization combining high resolving power with selective detection, seven analytes were quantified and the Lycium samples were quantitatively profiled. Chromatographic spectra were also obtained using longer run-time LC-UV and GC-MS methods in order to qualitatively assess the samples using a principal component analysis (PCA). The result of the method validation procedure was a 15.5 min LC-ESI-MS/MS method developed for the quantification of seven analytes in commercial Lycium samples. Wide variation in analyte concentration was observed with the following results (analyte range in mg/g): rutin, 16.1-49.2; narcissin, 0.37-1.65; nictoflorin, 0.26-0.78; coumaric acid, 6.84-12.2; scopoletin, 0.33-2.61; caffeic acid, 0.08-0.32; chlorogenic acid, 1.1-9.12. The quantitative results for the L. barbarum and L. chinense species samples indicate that they cannot be differentiated based on the bio-actives tested. A qualitative assessment using PCA generated from un-targeted LC-UV and GC-MS phytochemical spectra led to the same conclusion. The un-targeted quantitative and qualitative phytochemical profiling indicates that commercial L. barbarum and L. chinense cannot be distinguished using chemical analytical methods. Genetic fingerprinting and pharmacological testing may be needed to ensure the efficacy of commercial Lycium in order to validate label claims.

Keywords: Chemometrics; Herb MaRS; LC-MS; Lycium; PCA.

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Conflict of interest statement

The authors declare no conflict of interest regarding the publication.

Figures

Figure 1
Figure 1
Representative LC-ESI-MS/MS chromatogram of the extract of sample LB7 containing (1) Rutin, (2) Narcissin, (3) Nictoflorin, (4) Coumaric acid, (5) Scopoletin, (6) Caffeic acid and (7) Chlorogenic acid.
Figure 2
Figure 2
LC-UV spectra PCA score plot for the L. barbarum and L. chinense samples.
Figure 3
Figure 3
GC-MS spectra PCA score plot for the L. barbarum and L. chinense samples.
See this image and copyright information in PMC

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