Rapid Characterization of the major chemical constituents from Polygoni Multiflori Caulis by liquid chromatography tandem mass spectrometry and comparative analysis with Polygoni Multiflori Radix

Wang, Gui-yang; Shang, Jing; Wu, Yun; Ding, Gang; Xiao, Wei

doi:10.1002/jssc.201601255

Cited by 15 publications

(13 citation statements)

References 20 publications

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“…Dianthrones as secondary metabolisms resulted from the reduction product of anthraquinones in plant biosynthesis pathways 10 . Previous studies 14,27,28 showed that anthraquinones were the major constituents of PMC, which could revert to corresponding anthrones. Subsequently, dianthrones could be obtained by an oxidative coupling reaction of two anthrones by taking off 2H through C10–C10′ bond.…”

Section: Resultsmentioning

confidence: 99%

“…In recent years, minor dianthrone glycosides 9–11 isolated from PMR via phytochemical methods have proved the obvious toxicity related to liver damage 12,13 . Though, PMC and PMR come from the different parts of PM, phytochemical investigations indicate that PMC has similar main constituents in common with PMR such as anthraquinones, stilbene and flavonoids 14 . However, there has been a lack of study on dianthrones in PMC.…”

Section: Introductionmentioning

confidence: 99%

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Rapid analysis and identification of dianthrone glycosides in Polygoni Multiflori Caulis based on enrichment of macroporous absorbent resin and UPLC‐Q‐TOF‐MS/MS

et al. 2021

Phytochemical Analysis

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Introduction Polygoni Multiflori Caulis (PMC) has been used as a traditional Chinese medicine for a long time in China. However, hepatotoxic events of PMC have been reported in recent years, but the potential toxic compounds have remained unclear. Dianthrones as the secondary plant metabolites were revealed to potential hepatotoxicity in a previous study. However, no reports focused on dianthrones in PMC. Objective In the quest for exploring potential hepatotoxic compounds in PMC, the aim of this work was to undertake a comprehensive characterisation of dianthrones in PMC. Methods A simple and effective macroporous absorbent resin column chromatography method was established in this study to enrich the minor dianthrones from PMC extracts. Exploration and characterisation of dianthrones in PMC was conducted by an ultra‐high‐performance liquid chromatography‐quadrupole time‐of‐flight tandem mass spectrometry (UPLC‐QTOF‐MS/MS) method and information dependent acquisition (IDA) mode. The aglycones of dianthrone glycosides were further verified by acid hydrolysis method. Results Seventy‐two dianthrone glycosides and their five aglycones were discovered and tentatively characterised in PMC for the first time, of which 29 dianthrones were identified as potential new compounds. Dianthrone glycosides could be classified into three types according to their aglycone structures, and their fragmentation pathway rules and diagnosed ions were also summarised comprehensively. Conclusion This was the first comprehensive investigation on dianthrones in PMC. The result would help to fully understand the phytochemical constituents and toxic components in PMC, and highlight the need for further toxicological investigations of the dianthrones in PMC due to their potential hepatotoxicity correlation.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Rapid analysis and identification of dianthrone glycosides in Polygoni Multiflori Caulis based on enrichment of macroporous absorbent resin and UPLC‐Q‐TOF‐MS/MS

et al. 2021

Phytochemical Analysis

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“…As the content of the four components greatly differed between Polygonum multiflorum Radix and Polygoni multiflori Radix Preaparata samples obtained from different production areas, it was difficult to use a concrete content limit to differentiate Polygonum multiflorum Radix from Polygoni multiflori Radix Preaparata, which is a drawback and has remained unsolved previously. Through a mass data analysis in 2016, the “ Polygonum multiflorum rules” theory was proposed for the first time in a thesis [25], and the F value was used to differentiate Polygonum multiflorum Radix from Polygoni multiflori Radix Preaparata. As four control samples, emodin, physcion, emodin-8-O- β -D-glucopyranoside, and physcion-8-O- β -D-glucopyranoside, were used in this method, it had disadvantages such as high cost and complicated operations; in addition, the limit value was set as 1, which caused misjudgment.…”

Section: Discussionmentioning

confidence: 99%

“…Previous studies have analyzed the quality of Polygonum multiflorum Radix based on the relationship among 2,3,5,4′-tetrahydroxy diphenyl ethylene-2-O- β - glucoside, combined anthraquinones, and calcium oxalate [17] by determining the contents of glucosides and combined anthraquinones in Polygonum multiflorum Radix using HPLC-DAD [18]; determining the contents of 2,3,5,4′- tetrahydroxy diphenyl ethylene-2-O- β - glucoside, emodin, and emodin monemethyl ether in Polygonum multiflorum Radix and its residues using HPLC [19]; determining the contents of five anthraquinones, aloe-emodine, rheine, emodine, chrysophanol, and physcione in Polygonum multiflorum using HPLC [20]; determining the contents of four phenols, gallic acid, trans-2,3,5,4′-tetrahydroxystilbene-2-O- β -D-glucopyranoside, emodin, and emodin-8-O- β -D-glucopyranoside in Polygonum multiflorum and its processed form using UHPLC-MS/MS [21]; determining the contents of 2,3,5,4′-tetrahydroxystilbene-2-O- β -D-glucoside, emodin-8-O- β -D-glucoside, emodine, and physcion using LC-VWD-MS, UPLC-PDA, and HPLC-PAD [22–24] comparing the compositions of Polygonum multiflorum Thunb. and Polygonum multiflorum Radix using UHPLC-Q-TOF-MS [25]; and determining the 14 main components of Polygonum multiflorum Radix collected from different areas as well as the amounts of stibene glucosides, phenolic acids, flavones, and anthraquinones present in Polygonum multiflorum Radix using LC-MS/MS [26, 27]. One study showed that after processing of Polygonum multiflorum Radix, the contents of two anthraquinones, emodin-8-O- β -D-glucopyranoside and emodin monemethyl ether-8-O- β -D-glucopyranoside, were decreased in Polygoni multiflori Radix Preaparata, but the contents of emodin and emodin monemethyl ether increased [28–30].…”

Section: Introductionmentioning

confidence: 99%

Identification and Differentiation of Polygonum multiflorum Radix and Polygoni multiflori Radix Preaparata through the Quantitative Analysis of Multicomponents by the Single-Marker Method

Luo¹,

Jia

Zhao

et al. 2019

Journal of Analytical Methods in Chemistry

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The quantitative analysis of multicomponents by the single-marker (QAMS) method was established and the relationship between F value (the ratio of the sum of the contents of emodin-8-O-β-D-glucopyranoside and physcion-8-O-β-D-glucopyranoside to the sum of the contents of emodin and physcion) and the steaming time was found to identify and differentiate Polygonum multiflorum Radix and its processed product. Emodin was considered as the control substance, and the correction factors of physcion, emodin-8-O-β-D-glucopyranoside, and physcion-8-O-β-D-glucopyranoside were computed. In addition, the contents of the four components were determined. When the F value is greater than or equal to 1.0, the sample was identified as Polygonum multiflorum Radix, and if the F value was between 0.6 and 1.0, the sample of Polygoni multiflori Radix Preaparata was processed incompletely. The F value of the qualified Radix Polygonum multiflorum should be no more than 0.6. However, the influence of different sample injection volumes and the chromatographic columns and instruments used on the durability of the correction factors and RSD ≤3% hindered accurate identification; therefore, a QAMS method using an external standard value with methodological verification was developed. We redefined the “Polygonum multiflorum rules.” The method using “Polygonum multiflorum rules” revised after optimization of the determination results was used, as it was accurate and led to convenient operation and low inspection costs, and moreover, the method could differentiate Polygoni multiflori Radix Preaparata and Polygonum multiflorum Radix medicinal samples and precisely identify samples that were different from the completely processed product Polygoni multiflori Radix Preaparata.

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“…The role of PM has been investigated in various biological activities, including antioxidant activity, nerve cell protection, lipid regulation, and hair-follicle growth [10,11]. Furthermore, PM has been used for a long time as an antiageing agent [12]. However, the adverse effects of PM, such as hepatotoxicity, skin allergy, and bleeding in the upper digestive tract, have been reported occasionally [13,14].…”

Section: Introductionmentioning

confidence: 99%

Protective Effect of Processed Polygoni multiflori Radix and Its Major Substance during Scopolamine-Induced Cognitive Dysfunction

Kim

et al. 2021

Processes

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Alzheimer’s disease (AD) is the most common cognitive disorder in the elderly population. However, effective pharmacological agents targeting AD have not been developed. The processed Polygoni multiflori Radix (PPM) and its main active substance, 2,3,5,4′-tetrahydroxystilbene-2-O-β-glucoside (TSG), has received considerable attention, majorly due to its neuroprotective activities against multiple biological activities within the human body. In this study, we provide new evidence on the therapeutic effect of PPM and TSG during cognitive impairment by evaluating the ameliorative potential of PPM and TSG in scopolamine-induced amnesia in ICR mice. PPM (100 or 200 mg/kg) was orally administered during the experimental period (days 1–15), and scopolamine was intraperitoneally injected to induce cognitive deficits during the behavioural test periods (days 8–15). The administration of PPM and TSG significantly improved memory loss and cognitive dysfunction in behavioural tests and regulated the cholinergic function, brain-derived neurotrophic factor, and neural apoptosis. The present study suggests that PPM and TSG improved scopolamine-induced cognitive dysfunction, but further study has to be supported for the clinical application of PPM and TSG for AD prevention and treatment.

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Rapid Characterization of the major chemical constituents from Polygoni Multiflori Caulis by liquid chromatography tandem mass spectrometry and comparative analysis with Polygoni Multiflori Radix

Cited by 15 publications

References 20 publications

Rapid analysis and identification of dianthrone glycosides in Polygoni Multiflori Caulis based on enrichment of macroporous absorbent resin and UPLC‐Q‐TOF‐MS/MS

Rapid analysis and identification of dianthrone glycosides in Polygoni Multiflori Caulis based on enrichment of macroporous absorbent resin and UPLC‐Q‐TOF‐MS/MS

Identification and Differentiation of Polygonum multiflorum Radix and Polygoni multiflori Radix Preaparata through the Quantitative Analysis of Multicomponents by the Single-Marker Method

Protective Effect of Processed Polygoni multiflori Radix and Its Major Substance during Scopolamine-Induced Cognitive Dysfunction

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