Standardization and Quality Control of the Herbal Medicine Mist Nibima, Employed to Treat Malaria and COVID-19, Using Physicochemical and Organoleptic Parameters and Quantification of Chemical Markers via UHPLC-MS/MS

Mist Nibima is an essential herbal medicine used to treat malaria, bacterial, yeast, and COVID-19 infections. However, the drug has not been standardized and its active chemical ingredients are also not known. This study employed physicochemical, organoleptic, qualitative, and quantitate phytochemical analysis to established standards for Mist Nibima. Additionally, UHPLC was used to quantify the alkaloid cryptolepine in the drug using calibration curve. The chemical ingredients in Mist Nibima were thereafter characterized using UHPLC-MS. Organoleptic evaluation shows that Mist Nibima is a very bitter, cloudy, broom yellow decoction with the following physicochemical parameters: pH = 6.10 ± 0.08 (at 28.3°C), total solid residue = 5.34 ± 0.27%w/v, and specific gravity = 1.0099 ± 0.0000. The total alkaloid (23.71 ± 1.311%) content of the drug is 3 times its total saponins (7.993 ± 0.067%) content. Methyl cryptolepinoate (37.10%), cryptolepine (33.56%), quindoline (20.78%), 11-isopropylcryptolepine (5.16%), and hydroxycryptolepine (3.14%) were the active chemical ingredients in the drug with the concentrations of 18.64 ± 0.255, 16.85 ± 0.231, 10.42 ± 0.143, 2.56 ± 0.034, and 1.70 ± 0.023 µg/mL, respectively. Administration of a single oral therapeutic dose (30 mL) of Mist Nibima corresponds to ingestion of 559.2 ± 7.662, 505.5 ± 6.930, 312.6 ± 4.285, 76.8 ± 1.028, and 51.0 ± 0.699 µg of methyl cryptolepinoate, cryptolepine, quindoline, 11-isopropylcryptolepine, and hydroxycryptolepine, respectively. This translates into a corresponding daily dose of 1677.6 ± 22.986, 1516.5 ± 20.790, 937.8 ± 12.855, 230.4 ± 3.084, and 153.0 ± 2.097 µg of methyl cryptolepinoate, cryptolepine, quindoline, 11-isopropylcryptolepine, and hydroxycryptolepine. These results could now serve as tools for authentication, standardization, and quality control of Mist Nibima to ensure its chemical and pharmacological consistency and safety.

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Comparative Pharmacognostic, Physicochemical and Phytochemical Studies of Different Samples of Plumbago zeylanica L. Roots

International Journal of Pharmaceutical Sciences and Drug Research ◽

10.25004/ijpsdr.2017.090601 ◽

2017 ◽

Vol 9 (06) ◽

Author(s):

Neha Jain ◽

Mohan Lal Kori

Keyword(s):

Phytochemical Analysis ◽

Local Market ◽

Herbal Drugs ◽

Disease Treatment ◽

Organoleptic Evaluation ◽

Plumbago Zeylanica ◽

Qualitative And Quantitative ◽

Crude Drugs ◽

Phytochemical Studies

The objective of the present study is to evaluate the quality of the marketed and self collected samples of Plumbago zeylanica L. roots on the standardization parameters. This study is planned mainly to confirm changes with quality of drug. Now a day’s more demand of herbal drugs for disease treatment, lack of knowledge of proper methodology and availability are promoting the practices of adulteration and substitution. Thus, the standardization of the plant crude drugs is necessary to maintain their therapeutic efficacy. Comparative studies were carried out to evaluate the standards of P. zeylanica L. with emphasis on organoleptic evaluation, physicochemical and phytochemical analysis. Samples were procured from local market and self collected to determine the qualitative and quantitative variations. The result indicates that self collected sample showed significant results with comparison to marketed sample.

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Improving the quality of randomized controlled trials in Chinese herbal medicine, Part Ⅲ: quality control of Chinese herbal medicine used in randomize

Journal of Chinese Integrative Medicine ◽

10.3736/jcim20060302 ◽

2006 ◽

Vol 4 (3) ◽

pp. 225-232 ◽

Cited By ~ 14

Author(s):

Kelvin S.Y. LEUNG

Keyword(s):

Quality Control ◽

Herbal Medicine ◽

Randomized Controlled Trials ◽

Chinese Herbal Medicine ◽

Controlled Trials ◽

Randomized Controlled ◽

Chinese Herbal

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A quality control perspective on Devil's claw, Harpagophytum procumbens and H. zeyheri: phytochemical analysis and DNA barcoding

South African Journal of Botany ◽

10.1016/j.sajb.2021.09.029 ◽

2022 ◽

Vol 146 ◽

pp. 90-100

Author(s):

E. Pretorius ◽

N.P. Mncwangi ◽

R.M. Kabongo ◽

W. Chen ◽

I. Vermaak ◽

...

Keyword(s):

Quality Control ◽

Dna Barcoding ◽

Phytochemical Analysis ◽

Devil’S Claw ◽

Harpagophytum Procumbens

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Protection and Quality Control of Wild Chinese Herbal Medicine Resources in Nature Reserves by Taking Longyuwan Scenic Spot Within Funiu Mountain Nature Reserve as an Example

Journal of Northeast Agricultural University (English edition) ◽

10.1016/s1006-8104(16)30063-0 ◽

2016 ◽

Vol 23 (3) ◽

pp. 90-96

Author(s):

Wang Shao-hui ◽

Liu Meng-na ◽

Wang Xu ◽

Zhang Ya-chen ◽

Han Yi-wen ◽

...

Keyword(s):

Quality Control ◽

Herbal Medicine ◽

Chinese Herbal Medicine ◽

Nature Reserve ◽

Nature Reserves ◽

Chinese Herbal ◽

Scenic Spot ◽

Funiu Mountain

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Differentiation of Cyanthillium cinereum, a smoking cessation herb, from its adulterant Emilia sonchifolia using macroscopic and microscopic examination, HPTLC profiles and DNA barcodes

Scientific Reports ◽

10.1038/s41598-020-71702-7 ◽

2020 ◽

Vol 10 (1) ◽

Author(s):

Kannika Thongkhao ◽

Veerachai Pongkittiphan ◽

Thatree Phadungcharoen ◽

Chayapol Tungphatthong ◽

Santhosh Kumar J. Urumarudappa ◽

...

Keyword(s):

Quality Control ◽

Smoking Cessation ◽

Microscopic Examination ◽

Dna Barcode ◽

Species Level ◽

Raw Material ◽

Phytochemical Analysis ◽

Dna Barcodes ◽

Leaf Base

Abstract Cyanthillium cinereum (L.) H.Rob. is one of the most popular herbal smoking cessation aids currently used in Thailand, and its adulteration with Emilia sonchifolia (L.) DC. is often found in the herbal market. Therefore, the quality of the raw material must be considered. This work aimed to integrate macro- and microscopic, chemical and genetic authentication strategies to differentiate C. cinereum raw material from its adulterant. Different morphological features between C. cinereum and E. sonchifolia were simply recognized at the leaf base. For microscopic characteristics, trichome and pappus features were different between the two plants. HPTLC profiles showed a distinct band that could be used to unambiguously differentiate C. cinereum from E. sonchifolia. Four triterpenoid compounds, β-amyrin, taraxasterol, lupeol, and betulin, were identified from the distinct HPTLC band of C. cinereum. The use of core DNA barcode regions; rbcL, matK, ITS and psbA-trnH provided species-level resolution to differentiate the two plants. Taken together, the integration of macroscopic and microscopic characterization, phytochemical analysis by HPTLC and DNA barcoding distinguished C. cinereum from E. sonchifolia. The signatures of C. cinereum obtained here can help manufacturers to increase the quality control of C. cinereum raw material in commercialized smoking cessation products.

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The Physicochemical analysis and Phytochemical screening of some medicinal plants of Letang Municipality of Morang district, Nepal

BIBECHANA ◽

10.3126/bibechana.v17i0.25236 ◽

2020 ◽

Vol 17 ◽

pp. 67-74

Author(s):

Narendra Kumar Chaudhary ◽

Rijan Ojha ◽

Tilak Prasad Gautam

Keyword(s):

Medicinal Plants ◽

Chemical Constituents ◽

Powdered Material ◽

Physicochemical Analysis ◽

New Drugs ◽

Phytochemical Analysis ◽

Plumbago Zeylanica ◽

The People ◽

Active Chemical ◽

Medicinal Properties

Ethnobotany gives the basic idea about the medicinal properties of plants. Identification of active compounds of the medicinal plants and their standardization is essential for the production of new drugs. In the present work, different parts of the five medicinal plants (Curcuma caesia, Costus speciosus, Drymaria cordata, Leea macrophylla, Plumbago zeylanica) were washed, air dried and crushed. Three different extracts of each powdered material were prepared and standard phytochemical analysis procedure was followed for the analysis of physicochemical properties of plants and the identification of active chemical constituents. Among 5 plants, the highest moisture content (14.83%) was found in Plumbago zeylanica, higher total ash (9.22%) and acid insoluble ash (4.43%) were observed in Cucurma caesia. Phytochemical analysis revealed the presence of 12 varieties of bioactive chemicals in the 5 different plants. The plants of the area have great diversity of phytochemicals of numerous medicinal properties. In conclusions, these five important medicinal plants could be useful for the people of the locality to cure several diseases as well as to generate the source of income. BIBECHANA 17 (2020) 67-74

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A Chemical Marker Proposal for the Lantana genus: Composition of the Essential Oils from the Leaves of Lantana radula and L. canescens

Natural Product Communications ◽

10.1177/1934578x1000500429 ◽

2010 ◽

Vol 5 (4) ◽

pp. 1934578X1000500

Author(s):

José G. Sena Filho ◽

Haroudo S. Xavier ◽

José M. Barbosa Filho ◽

Jennifer M. Duringer

Keyword(s):

Quality Control ◽

Chemical Analysis ◽

Essential Oil ◽

Essential Oils ◽

The Other ◽

Chemical Markers ◽

Chemical Marker ◽

High Concentration ◽

Minor Compounds ◽

Prior Analysis

Essential oil extracts from the leaves of two Lantana species ( L. radula Sw. and L. canescens Kunth), for which no prior analysis has been reported, were analyzed by GC-MS. This information was utilized to propose chemical markers for Lantana species so that identification between physically similar plant species can be achieved through chemical analysis. Results showed 33 constituents for L. canescens, among which β-caryophyllene (43.9%), β-cubebene (10.1%), elixene (8.6%), β-phellandrene (6.1%), α-caryophyllene (2.6%) and dehydro-aromadendrene (2.6%) were the principle components. L. radula revealed the presence of 21 compounds, the most abundant of which were β-cubebene (31.0%), β-caryophyllene (20.8%), elixene (10.0%), α-salinene (6.4%), β-phellandrene (6.1%), copaene (4.9%) cadinene (1.4%) and psi-limonene (1.4%). The high concentration of β-caryophyllene in the samples tested here and those in the literature make it a good candidate for a chemical marker for Lantana species, with β-cubebene, elixene and β-phellandrene following as minor compounds identified more sporadically in this genus. On the other hand, Lippia species, which are morphologically similar to those from the Lantana genus, would contain limonene, citral, carvacrol, β-myrcene, camphor and thymol as the main chemical markers. These chemical markers would be a powerful tool for maintaining quality control in the extraction of essential oils for use in medicinal applications, as well as in identification of plant specimens to a taxonomist.

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Xanthine Oxidase Inhibitory Activity, Chemical Composition, Antioxidant Properties and GC-MS Analysis of Keladi Candik (Alocasia longiloba Miq)

Molecules ◽

10.3390/molecules25112658 ◽

2020 ◽

Vol 25 (11) ◽

pp. 2658 ◽

Cited By ~ 1

Author(s):

Ferid Abdulhafiz ◽

Arifullah Mohammed ◽

Fatimah Kayat ◽

Matcha Bhaskar ◽

Zulhazman Hamzah ◽

...

Keyword(s):

Chemical Composition ◽

Side Effects ◽

Herbal Medicine ◽

Xanthine Oxidase ◽

Inhibitory Activity ◽

Total Phenolic ◽

Phytochemical Analysis ◽

Fruit Extracts ◽

Ms Analysis ◽

Ic50 Value

Alocasia longiloba, locally known as ‘Keladi Candik’, has been used traditionally to treat wounds, furuncle and joint inflammations. A. longiloba can be a new source of herbal medicine against hyperuricemia by inhibiting the activity of xanthine oxidase enzyme, the enzyme which is responsible for the development of hyperuricemia in human. Existing xanthine oxidase inhibitors (XOI drugs) show several side effects on gout patients. Therefore, an alternative herbal medicine from plants, with high therapeutic property and free of side effects, are greatly needed. This study was conducted to evaluate XO inhibitory activity, chemical composition, antioxidant activity and GC-MS profile of A. longiloba. Our results showed that ethanolic petiole extract exhibited the highest XO inhibitory activity (70.40 ± 0.05%) with IC50 value of 42.71 μg/mL, followed by ethanolic fruit extracts (61.44 ± 1.24%) with the IC50 value of 51.32 μg/mL. In a parallel study, the phytochemical analysis showed the presence of alkaloid, flavonoid, terpenoids, glycoside and saponin in petiole and fruit extracts, as well as higher total phenolic and flavonoid contents and strong scavenging activity on DPPH and ABTS antioxidant assay. The GC-MS analysis of fruit and petiole extracts revealed the presence of various compounds belonging to different chemical nature, among them are limonen-6-ol, α-DGlucopyranoside, paromomycin, aziridine, phenol, Heptatriacotanol, Phen-1,2,3-dimethyl and Betulin found in ethanolic fruit extract, and Phen-1,4-diol,2,3-dimethyl-, 1-Ethynyl-3,trans(1,1-dimethylethyl), Phenol,2,6-dimethoxy-4-(2-propenyl)- and 7-Methyl-Z-tetradecen-1-olacetate found in ethanolic petiole extract. Some compounds were documented as potent anti-inflammatory and arthritis related diseases by other researchers. In this study, the efficiency of solvents to extract bioactives was found to be ethanol > water, methanol > hexane > chloroform. Together, our results suggest the prospective utilization of fruit and petiole of A. longiloba to inhibit the activity of XO enzyme.

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