1.Chemical constituents and their α-glucosidase inhibitory activities of seeds of Moringa oleifera.
Liang CHEN ; Yin-Zhi CEN ; Yang-Li TU ; Xiang-Jie DAI ; Yong-Jun LI ; Xiao-Sheng YANG ; Lin-Zhen LI
China Journal of Chinese Materia Medica 2023;48(17):4686-4692
The chemical constituents of the seeds of Moringa oleifera were isolated and purified by using Sephadex LH-20, Toyo-pearl HW-40F, silica gel, ODS, and MCI column chromatography. The structures of compounds were identified by high-resolution mass spectrometry, ~1H-NMR, ~(13)C-NMR, HMQC, HMBC, and ~1H-~1H COSY, as well as physicochemical properties of compounds and literature data. Twelve compounds were isolated from 30% ethanol fraction of the seeds of M. oleifera and identified as ethyl-4-O-α-L-rhamnosyl-α-L-rhamnoside(1), ethyl-3-O-α-L-rhamnosyl-α-L-rhamnoside(2),(4-hydroxybenzyl)ethyl carbamate(3),(4-aminophenyl)acetic acid(4), ethyl-α-L-rhamnoside(5), methyl-α-L-rhamnoside(6), moringapyranosyl(7), 2-[4-(α-L-rhamnosyl)phenyl]methyl acetate(8), niaziridin(9), 5-hydroxymethyl furfural(10), 4-hydroxybenzeneacetamide(11), and 4-hydroxybenzoic acid(12). Among them, compounds 1 and 2 are two new compounds, compound 3 is a new natural product, and compounds 4-5 were yielded from Moringa plant for the first time. All compounds were evaluated for α-glucosidase inhibitory activity in vitro. Compound 10 showed excellent inhibitory activity with IC_(50) of 210 μg·mL~(-1).
Moringa oleifera/chemistry*
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alpha-Glucosidases
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Moringa
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Seeds
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Plant Extracts/pharmacology*
2.Decocting kinetics of Moringa oleifera leaves: based on correlation of decocting factors and multiple components.
Ya-Nan SONG ; Yun WANG ; Ya GAO ; Cun ZHANG ; Xiao-Lan QU ; Hong-Jun YANG
China Journal of Chinese Materia Medica 2022;47(18):4950-4958
Content of multiple components (neochlorogenic acid,L-tryptophan,vicenin-2,isoquercitrin,and astragalin) in Moringa oleifera leaves was determined by high-performance liquid chromatography (HPLC),and the absolute content-time curves were plotted.Based on Fick's law of diffusion and Higbie's penetration theory,the parameters of the equations were calculated,and the measured results were substituted into the mathematical model to fit the equations.The n and a obtained from the equations on the decocting time factor and the solvent volume were close to each other.The dynamic models of the five components are as follows:■.The variation of the content of multiple components in M.oleifera leaves with time and solvent volume was explored.It was found that the content of the components was the highest when the leaves were decocted for 30 min with solvent volume 12 folds of the medicinal material.The dissolution and destruction of components and the diffusion movement of components are the main causes of the content change of M.oleifera leaves at different time and with different solvent volumes.The R~2of the linear equations on the content and the equations on the decocting process (5-30min and solvent volume 12-20 folds of the medicinal materials) was≥0.999 8 and≥0.9,respectively.Thus,the content determination and the decocting kinetic model had high accuracy,which can reflect the change law of the content of key components in M.oleifera leaves during the decoction.This study is expected to serve as a reference for optimizing the decocting technology.
Kinetics
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Moringa oleifera/chemistry*
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Plant Leaves/chemistry*
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Solvents
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Tryptophan/analysis*
3.Functional orientation of Moringa leaves based on text mining and molecular docking technology.
Zi-Jun SHA ; Shi-Huan TANG ; Zhi-Yong LI ; Bin YANG ; Hong-Jun YANG
China Journal of Chinese Materia Medica 2020;45(2):331-340
A new method on functional orientation of Moringa leaves based on text mining and molecular docking was explored in the study. First, PubMedplus was used to analyze research data on Moringa leaves collected in PubMed and the indications of Moringa leaves were screened along with the hotspots and development tendency of Moringa leaves. Second, Arrowsmith was used to obtain the biological targets of Moringa leaves. Third, active candidate components of Moringa leaves were filtered by SwissADME analyzing on chemical data collected from literatures. Subsequently, molecular docking between active candidate component and target was studied by systemsDock to forecast the potential active components and their possible effective targets, and GO functional annotation of the potential targets was performed by DAVID database. According to the results, tumor, diabetes and digestive diseases were suggested to be indications of Moringa leaves, correlated with 25 active components and 12 potential effective targets possibly by adjusting G protein-coupled receptor and affecting on inflammatory reaction. The new method on functional orientation by combining text mining with molecular docking was successfully practiced on Moringa leaves as a case study,which provides a useful reference for the ultilization of foreign medicinal resource.
Data Mining
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Molecular Docking Simulation
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Moringa/chemistry*
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Plant Extracts/pharmacology*
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Plant Leaves/chemistry*
4.Comparative study of purgative pharmacological effects and mechanisms of Moringa oleifera leaves and Rhei Radix et Rhizoma.
Xing-Nan YUE ; Shuo WANG ; Bin YANG ; Shu-Yi FENG ; Rao FU ; Chun-Hui QU ; Zhi-Yong LI
China Journal of Chinese Materia Medica 2023;48(19):5259-5270
Moringa oleifera leaves are known for their "Virechana"(purgative) effect in Ayurvedic medicine in India. This study compared the purgative effects and mechanisms of M. oleifera leaves with the reference Rhei Radix et Rhizoma to establish a foundation for the further application of M. oleifera leaves in traditional Chinese medicine(TCM). Using network pharmacology and molecular docking methods, this study identified the material basis, common targets, and signaling pathways through which Rhei Radix et Rhizoma and M. oleifera leaves exerted their purgative pharmacological effects. A low-fiber diet-induced constipation mouse model was established to measure fecal parameters and small intestinal propulsion rate, and histological changes in the colon were observed using HE staining. Relative expression levels of relevant genes and target proteins were assessed using RT-qPCR and immunohistochemistry, respectively. The results showed that mapping the targets of Rhei Radix et Rhizoma and M. oleifera leaves onto the biological process network of constipation revealed close proximity, indicating that they may exert their therapeutic effects on constipation through similar biological processes. Molecular docking results indicated that compounds such as sennoside C and isoquercitrin could target serine/threonine protein kinases(AKT1) and mitogen-activated protein kinase 3(MAPK3), thereby affecting MAPK and calcium signaling pathways to promote defecation. Animal experiments demonstrated that both M. oleifera leaves and Rhei Radix et Rhizoma increased the number of fecal pellets and water content in constipated mice, improved small intestine motility, colon mucosal thickness, and muscle layer thickness, upregulated the gene expression levels of AKT1 and MAPK3 in the colon, and downregulated the expression of AQP3 protein. These findings suggest that M. oleifera leaves and Rhei Radix et Rhizoma share similarities in their therapeutic efficacy and mechanisms for treating constipation. Using Rhei Radix et Rhizoma as a reference can provide a better understanding of the characteristics of the "Virechana"(purgative) effect of M. oleifera leaves in TCM.
Mice
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Animals
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Cathartics
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Moringa oleifera
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Molecular Docking Simulation
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Drugs, Chinese Herbal/chemistry*
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Constipation
5.Constituents isolated from n-butanol extract of leaves of Moringa oleifera.
Feng-Hua LI ; Hong-Qing WANG ; Xian-Ming SU ; Chang-Kang LI ; Bao-Ming LI ; Ruo-Yun CHEN ; Jie KANG
China Journal of Chinese Materia Medica 2018;43(1):114-118
Seventeen compounds were isolated from n-butanol extract of the leaves of Moringa oleifera, using column chromatography over macroporous resin HP-20,Sephadex LH-20, and ODS. Their structures were identified as two carboline,tangutorid E(1) and tangutorid F(2); three phenolic glycosides,niazirin(3),benzaldehyde 4-O-α-L-rhamnopyranoside(4) and 4-O-β-D-glucopyranosidebenzoic acid(5); four chlorogenic acid and derivatives,4-caffeoylquinic acid(6),methyl 4-caffeoylquinate(7),caffeoylquinic acid(8) and methyl caffeoylquinate(9); two nucleosids,uridine(10) and adenosine(11); one flavone,quercetin 3-O-β-D-glucopyranoside(12); five other types of compounds,phthalimidineacetic acid(13),3-pyridinecarboxamide(14),3,4-dihydroxy-benzoic acid(15),5-hydroxymethyl-2-furancarboxylic acid(16) and 5-hydroxymethyl-2-furaldehyde(17) by the spectral data of ¹H, ¹³C-NMR and MS. Among them,compounds 1-2,7,9-10,16 and 17 were isolated from M. oleifera for the first time.
1-Butanol
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Glycosides
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analysis
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Moringa oleifera
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chemistry
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Phenols
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analysis
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Phytochemicals
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analysis
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Plant Extracts
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chemistry
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Plant Leaves
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chemistry
7.Antiulcer activity of a polyherbal formulation (PHF) from Indian medicinal plants.
V C DEVARAJ ; B Gopala KRISHNA
Chinese Journal of Natural Medicines (English Ed.) 2013;11(2):145-148
AIM:
The present study was aimed at evaluating the antiulcer activity of the polyherbal formulation (PHF) containing the leaf extracts of Moringa oleifera, Raphinus sativus, and Amaranthus tricolor in rats.
METHODS:
The antiulcer activity of the polyherbal formulation (PHF) was evaluated using different models of gastric ulcers: ethanol-induced, indomethacin-induced and ischemia reperfusion-induced gastric ulcers. Efficacy was assessed by determining the ulcer index.
RESULTS:
Administration of the polyherbal formulation (150 mg·kg(-1), p.o.) offered significant protection against indomethacin-induced, ethanol-induced, and ischemic reperfusion-induced ulcer models when compared to the control group.
CONCLUSION
PHF, containing leaf extracts of Moringa oleifera, Raphinus sativus, and Amaranthus tricolor, was found to possess antiulcer properties in three experimental animal models of gastric ulcers, and these findings suggest that the significant gastroprotective activity could be mediated by its antioxidant activity.
Amaranthus
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chemistry
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Animals
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Anti-Ulcer Agents
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administration & dosage
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Brassicaceae
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chemistry
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Chemistry, Pharmaceutical
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Humans
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India
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Male
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Moringa oleifera
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chemistry
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Phytotherapy
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Plant Extracts
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administration & dosage
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Plant Leaves
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chemistry
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Plants, Medicinal
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chemistry
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Rats, Wistar
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Stomach Ulcer
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drug therapy
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prevention & control