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.Moringa oleifera Prolongs Lifespan via DAF-16/FOXO Transcriptional Factor in Caenorhabditis elegans.
Jun Sang IM ; Ha Na LEE ; Jong Woo OH ; Young Jin YOON ; Jin Suck PARK ; Ji Won PARK ; Jung Hoon KIM ; Yong Sung KIM ; Dong Seok CHA ; Hoon JEON
Natural Product Sciences 2016;22(3):201-208
Here in this study, we investigated the lifespan-extending effect and underlying mechanism of methanolic extract of Moringa olelifa leaves (MML) using Caenorhabditis elegans (C. elegans) model system. To define the longevity properties of MML we conducted lifespan assay and MML showed significant increase in lifespan under normal culture condition. In addition, MML elevated stress tolerance of C. elegans to endure against thermal, oxidative and osmotic stress conditions. Our data also revealed that increased activities of antioxidant enzymes and expressions of stress resistance proteins were attributed to MML-mediated enhanced stress resistance. We further investigated the involvement of MML on the aging-related factors such as growth, food intake, fertility, and motility. Interestingly, MML significantly reduced growth and egg-laying, suggesting these factors were closely linked with MML-mediated longevity. We also observed the movement of aged worms to estimate the effects of MML on the health span. Herein, MML efficiently elevated motility of aged worms, indicating MML may affect health span as well as lifespan. Our genetic analysis using knockout mutants showed that lifespan-extension activity of MML was interconnected with several genes such as skn-1, sir-2.1, daf-2, age-1 and daf-16. Based on these results, we could conclude that MML prolongs the lifespan of worms via activation of SKN-1 and SIR-2.1 and inhibition of insulin/IGF pathway, followed by DAF-16 activation.
Caenorhabditis elegans*
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Caenorhabditis*
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Eating
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Fertility
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Longevity
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Methanol
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Moringa oleifera*
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Moringa*
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Osmotic Pressure
4.Acute Pancreatitis Induced by Moringa Oleifera in a 48 years Old Korean Women: A Case Report.
Rim LEE ; Seong AHN ; Sang Yoon HA ; Cheon KOO ; Joon Tae KANG
Journal of the Korean Society of Emergency Medicine 2015;26(6):612-615
Moringa oleifera (Moringa) induced acute pancreatitis is an unreported cause of acute pancreatitis. A 48-year-old female who took Moringa for one week complained of abdominal pain, nausea, and vomiting. Her symptoms and biochemical studies showed close accordance with acute pancreatitis. We found no other cause of acute pancreatitis except Moringa. After cessation of Moringa, her symptoms improved and biochemical studies normalized. One month later, she developed recurrent acute pancreatitis after taking Moringa. Thus we thought that Moringa was the cause of acute pancreatitis. No case of acute pancreatitis associated with Moringa has been reported, therefore we report this case.
Abdominal Pain
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Female
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Humans
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Middle Aged
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Moringa oleifera*
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Moringa*
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Nausea
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Pancreatitis*
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Vomiting
5.Bleeding time using Moringa oleifera (Malunggay) leaf extract versus saline control in a rabbit epistaxis model: A randomized controlled trial.
Paula Luz G CABALLERO ; Joseph E CACHUELA
Philippine Journal of Otolaryngology Head and Neck Surgery 2017;32(1):14-16
OBJECTIVE: To determine bleeding time using Moringa oleifera leaf extract versus saline control in an experimental epistaxis model.
METHODS:
Design: Randomized controlled trial
Setting: Tertiary Government Training Hospital
Participants: Ten adult male New Zealand White rabbits were acclimatized for 1 week in a standard environment. One-centimeter long, full-thickness mucosal wounds in the junction of the nasal floor and anterior part of the septum were treated randomly with topical Moringa oleifera extract or colored isotonic saline control in either right or left nasal cavity, one site at a time. The duration of bleeding - time bleeding started to time bleeding stopped -- was recorded in seconds. Data was subjected to a t-test for paired samples.
RESULTS: The mean bleeding time for wounds treated with Moringa extract was 53 seconds (range 38-70 secs), versus 159 seconds (range 100-218 secs) for controls. The bleeding time in the former was significantly shorter than in the latter (p = .000019, t-stat = 8.139), with a mean difference of 106 seconds between the two groups.
CONCLUSION: Moringa oleifera leaf extract was associated with significantly shorter bleeding time than saline control in this experimental epistaxis model and may be worth investigating further as a hemostatic agent for epistaxis.
Animal ; Male ; Rabbits ; Moringa Oleifera ; Moringa ; Epistaxis ; Bleeding Time ; Nasal Cavity ; Hemostatics ; Nose ; Acclimatization ; Environment ; Erythromycin
6.Induction of Apoptosis with Moringa oleifera Fruits in HCT116 Human Colon Cancer Cells Via Intrinsic Pathway.
Natural Product Sciences 2017;23(4):227-234
Moringa oleifera Lam (M. oleifera, Moringaceae) is a tree of the Moringaceae family that can reach a height of between 5 and 10 m. The current paper presents cytotoxic effect of M. oleifera fruits and its flavonoids 1 and 2. The viability of HCT116 human colon cancer cells were 38.5% reduced by 150 µg/mL of ethanolic extracts in a concentration-dependent manner; in addition, we observed the apoptotic features of cell shrinkage and decreased cell size. Bcl-2 family proteins were regulated as determined by Western blotting analysis, suggesting that M. oleifera fruits and their flavonoids 1 and 2 induced apoptosis through an intrinsic pathway. Based on our findings, 70% ethanolic extracts of M. oleifera fruits and flavonoids 1 and 2 might be useful as cytotoxic agents in colorectal cancer therapy.
Apoptosis*
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Blotting, Western
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Cell Size
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Colon*
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Colonic Neoplasms*
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Colorectal Neoplasms
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Cytotoxins
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Ethanol
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Flavonoids
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Fruit*
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Humans*
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Moringa oleifera*
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Moringa*
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Trees
7.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
8.A randomized controlled trial: Comparison of malunggay (Moringa oleifera) and ferrous sulfate in preventing anemia in pregnant patients in the outpatient department of a tertiary hospital (January 2013-July 2016).
Angeli Rose O. CARAOS ; Antonio C. CORTEZ
Philippine Journal of Obstetrics and Gynecology 2017;41(6):26-35
9.UPLC characteristic fingerprint of leaves of Moringa oleifera.
Lin XU ; Chun-Lin FAN ; Xiao-Jun HUANG ; Hu-Hu ZENG ; Hui LIU ; Ying WANG ; Wen-Cai YE
China Journal of Chinese Materia Medica 2018;43(22):4474-4478
This study aims to establish the characteristic fingerprint of the leaves of Moringa oleifera by Ultra High Performance Liquid Chromatography (UPLC) for its quality control. The method was developed on a column of Agilent Eclipse XDB-C₁₈ with acetonitrile-0.01% TFA solution as the mobile phase by gradient elution at a flow rate of 0.5 mL·min⁻¹. The detective wavelength was 210 nm, and the column temperature was 35 °C. The 14 batches of the leaves of M. oleifera were compared for the similarity by using Traditional Chinese Medicine Chromatographic Fingerprint Similarity Evaluation System (2004A). The UPLC characteristic fingerprint was established, and twelve common peaks were identified by comparison with the references and UPLC-MS. The relative retention times were 0.08 (No. 1, adenosine), 0.14 (No. 2, L-phenylalanine), 0.22 (No. 3, 5-caffeoylquinic acid), 0.28 (No. 4, L-tryptophane), 0.42 (No. 5, 4-caffeoylquinic acid), 0.65 (No. 6, vicenin-2), 0.94 (No. 7, vitexin), 0.96 (No. 8, isovitexin), 1.00 (No. 9, isoquercitrin), 1.11 [No. 10, quercetin 3-O-β-D-(6"-malonyl)-glucopyranoside], 1.21 (No. 11, astragalin) and 1.37 [No. 12, kaempferol 3-O-β-D-(6"-malonyl)-glucopyranoside]. It is the first time to establish the UPLC characteristic fingerprint of the leaves of M. oleifera. The method is simple, quick and reproducible with high precision, which can provide a scientific basis for the quality control of the leaves of M. oleifera.
Chromatography, High Pressure Liquid
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Chromatography, Liquid
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Drugs, Chinese Herbal
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Moringa oleifera
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Quality Control
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Tandem Mass Spectrometry
10.Efficacy and mechanism of new resource medicinal materia Moringa oleifera leaves against hyperlipidemia.
Zi-Jun SHA ; Cai-Feng LI ; Shi-Huan TANG ; Hong-Jun YANG ; Yi ZHANG ; Zhi-Yong LI ; Bin YANG
China Journal of Chinese Materia Medica 2021;46(14):3465-3477
High fat diet induced hyperlipidemia hamster model was used to explore the anti-hyperlipidemia effect of water extract of Moringa oleifera leaves( WEMOL). On this basis,the possible action mechanism was predicted by network pharmacology. Golden hamsters were randomly divided into normal diet group( NFD),high-fat diet group( HFD),simvastatin group,high dose group of WEMOL( HIWEMOL) and low dose group of WEMOL( LOWEMOL). The model was administered simultaneously for 66 days,during which the body weight changes of hamsters were recorded. At the end of the experiment,serum lipid level and serum transaminase level of golden hamsters in each group were detected,and the pathological changes of liver were observed by hematoxylin-eosin( HE) staining. The results showed that WEMOL could significantly decrease the serum total cholesterol( TC),total triglyceride( TG),low density lipoprotein cholesterol( LDL-c) levels,and reduce the lipid deposition in liver tissue,thus improving the hyperlipidemia of golden hamsters. According to the prediction of network pharmacology,219 targets of potential active components of M.oleifera leaves and 185 targets of water-soluble potential active components of M. oleifera leaves for the treatment of hyperlipidemia were obtained separately. The MCODE analysis was performed on the PPI network of 219 targets and 185 targets obtained above and got five and four clusters respectively. The signaling pathway analysis of clusters showed that among the common pathways,nonalcoholic fatty liver,insulin resistance,MAPK signaling pathway,estrogen signaling pathway,cell apoptosis and HIF-1 signaling pathway were associated with hyperlipidemia. In addition,the potential active components of M. oleifera leaves could also inhibit the metabolic inflammation of hyperlipidemia by modulating complement and coagulation cascades signaling pathway,and GSK3 B,F2,AKT1,RELA,SERPINE1 might be the key targets. The water-soluble potential active components of M. oliefera leaves could modulate lipid metabolism by modulating AMPK signaling pathway and JAK-STAT signaling pathway,with PIK3 CB,PIK3 CA,CASP3,AKT1 and BCL2 as the key targets. These results suggested that WEMOL had anti hyperlipidemia effect,and its mechanism might be related to the protein expression regulation of lipid metabolism,nonalcoholic fatty liver disease and atherosclerosis related signaling pathways.
Animals
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Cricetinae
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Diet, High-Fat
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Glycogen Synthase Kinase 3
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Hyperlipidemias/drug therapy*
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Liver
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Moringa oleifera
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Plant Leaves