Bioactivity evaluation of least explored traditionally acclaimed medicinally potent herb <i>Nanorrhinum ramosissimum</i>(Wall.) Betsche

Sharma, Jyotsna; Sharma, Savita; Koul, Anuja; Shankarayan, Raju; Mallubhotla, Sharada

doi:10.1590/s2175-97902023e19334

Abstract

Present study analysed the therapeutic potential of traditionally acclaimed medicinal herb Nanorrhinum ramosissimum, using plant parts extracted with different solvents (10 mg/mL). Shoot extracts exhibited comparatively better antimicrobial properties, in comparison to root extracts. Total phenolic content was estimated, to ascertain its dependency on antioxidant properties of plant extracts. Antioxidant assay revealed promising results in comparison to IC₅₀ value of standard ascorbic acid (52.2±0.07 µg/mL), for methanolic extracts of shoot (61.07±0.53 µg/mL and 64.33±0.33 µg/mL) and root (76.705±0.12 µg/mL and 89.73±0.28 µg/ mL) for in vivo and in vitro regenerants respectively. Correlation coefficient R² values ranged between 0.90-0.95, indicating a positive correlation between phenolic contents and antioxidant activity. Plant extracts were also able to inhibit DNA oxidative damage again indicating their antioxidative potential. Antidiabetic potential was confirmed by alpha amylase inhibition assay where shoot methanolic extracts (invivo, in vitro) exhibited the best IC₅₀ values (54.42±0.16 µg/mL, 66.09±0.12 µg/mL) in comparison to standard metformin (41.92±0.08 µg/mL). Ethanolic extracts of roots (in vitro, invivo) exhibited the relative IC₅₀ values (88.97±0.32µg/mL,96.63±0.44 µg/mL) indicating that shoot parts had a better alpha amylase inhibition property; thus proving the herb’s bioactive potential and its prospective therapeutic source for curing various ailments.

Keywords:
Branched cancerwort; Antimicrobial activity; Antioxidant activity; Alpha amylase inhibition; DPPH assay

INTRODUCTION

Medicinal plants are a significant resource for finding novel remedies for various human health complications (Ghorbani, 2013Ghorbani A. Best herbs for managing diabetes: a review of clinical studies. Braz J Pharm Sci. 2013;49(3):413-422.; Myo et al., 2020Myo EM, Maung CE, Mya KM, Khai AA. Characterization of bacterial endophytes from Myanmar medicinal plants for antimicrobial activity against human and plant pathogens. Braz J Pharm Sci . 2020;56:e17705.). Nanorrhinum ramosissimum is an important but less explored medicinal of that has been traditionally used in folk medicine in the Indian subcontinent to cure a multiplicity of ailments (Kirtikar, Basu, 2005Kirtikar KR, Basu BD. Indian medicinal plants. 2nd ed. DehraDun: International Book Distributors; 2005.; Amin et al., 2017Amin A, Emmy T, Kenn F, Vassiliki E, Sandra A, Luc P, et al. In vitro and in silico antidiabetic and antimicrobial evaluation of constituents from Kickxia ramosissima (Nanorrhinum ramosissimum). Front Pharmacol. 2017;8:232.). The most popular synonyms for N. ramosissimum are Kickxia ramosissima and Linaria ramosissima and are commonly known as Bhintgalodi, Kanodi (Gujarati), Banwel (Marathi), Branched cancerwort (English) (Pullaiah, Naidu, 2003Pullaiah T, Naidu K. Antidiabetic plants in India and herbal based antidiabetic research. New Delhi: Regency Publications; 2003.). The plant habituates countries like India, Pakistan, growing on walls, rocky and stony places, ascending to height of 7,000 ft in the Himalayas (Pandya et al., 2012Pandya PN, Aghera HB, Ashok BK, Acharya R. Diuretic activity of Linaria ramosissima (Wall.) Janch. leaves in albino rats. Ayu. 2012;33(4):576-578.). It is a prostrate perennial herb that grows up to a length of about 40 cms, flowering in the months of August to October. In traditional systems of medicine, the herb is mentioned as a remarkably suitable candidate for curing various diseases e.g. in cases of snake bite the roots and leaves are quite effectual, whereas in fever leaves mixed with black pepper are recommended. The whole plant has also been used traditionally for the management of diabetes, inflammatory disorders such as rheumatism, jaundice, activation of immune system and treatment of urinary stones (Bhandari, 2006Bhandari C. Vanousadhi Chandrodaya: An Encyclopedia of Indian Botanist and Herbs. Varanasi: Chaukhamba Sanskrut Sansthan; 2006.117p.; Pandya et al., 2012Pandya PN, Aghera HB, Ashok BK, Acharya R. Diuretic activity of Linaria ramosissima (Wall.) Janch. leaves in albino rats. Ayu. 2012;33(4):576-578.; Jan, Khan, 2016Jan S, Khan MR. Antipyretic, analgesic and antiinflammatory effects of Kickxia ramosissima. J Ethnopharmacol.2016;182:90-100.). However, in spite of its numerous therapeutic properties, there are very few scientific reports of evidence regarding the bioactive properties of the herb, therefore, it has not yet been included in the modern health care system. The current study was performed to inspect the antimicrobial, antioxidant, alpha amylase inhibitory activities and oxidative DNA damage response of extracts of the shoot and root parts prepared using various solvents (methanol, ethanol, ethyl acetate, petroleum ether, aqueous) from both in vivo (field) and in vitro regenerants of N. ramosissimum. This piece of study could prove to be beneficial in utilizing the remarkable therapeutic potentials of the herb for improving the health of mankind.

MATERIAL AND METHODS

Sample preparation

Nanorrhinum ramosissimum (Wall.) Betsche (Plantaginaceae) was collected from its natural habitat at Akhnoor, Jammu District, Jammu & Kashmir, India (Latitude = 32°89′ North, Longitude = 74°74’ East and Altitude = 301m). kindly identified by Sh. OP Sharma, IFS, Chief Conservator Forests, Department of Environment, Ecology and Remote Sensing, J&K, India, which served as the in vivo plant material. To verify the identity of the plant under study, a vaucher herbarium specimen has been deposited at Janaki Ammal Herbarium, CSIR-Indian Institute of Integrative Medicine (CSIR-IIIM), Jammu, J&K bearing accession No. RRLH23493 (Figure 1). Active shoot tips (0.5 cm length) of the in vivo plants were selected as explants for developing the in vitro regenerants in the appropriate multiplication medium (Sharma et al., 2021Sharma J, Koul A, Sharma S, Shankarayan R, Mallubhotla S. In vitro propagation of Nanorrhinum ramosissimum (Wall.) Betsche: A traditionally important medicinal plant. Kuwait JSci. 2021;48(3).).

FIGURE 1
Specimen submitted in Janaki Ammal Herbarium CSIR-Indian Institute of Integrative Medicine (CSIR-IIIM), Jammu, J&K bearing accession No. RRLH23493.

In vivo and in vitro shoot and root parts were collected individually, dried in shade and pulverized. The powder (100 mg) was then extracted with five different solvents (10 mL) viz. methanol, ethanol, ethyl acetate, petroleum ether, aqueous) in a conical flask implanted on a shaker (40 rpm) for 48 h at room temperature (25 °C). The extract was recovered and filtered (Whatmann filter paper No. 1). The residue obtained from the first extraction was again extracted twice in the same solvent as described above. The extracts were pooled after three successive extractions and the filtrate recovered was evaporated under reduced pressure at 50 °C using a rotary evaporator in order to obtain the crude extract which was dissolved in dimethyl sulfoxide (DMSO) and used at different concentrations (10-200 μg/mL) for bioactivity analysis.

Antimicrobial activity

The extracts prepared from in vivo plant materials of N. ramosissimum were assayed for their antimicrobial activity against different bacterial strains (gram positive and gram negative) viz. Bacillus subtilis, Mycobacterium smegmatis, Escherichia coli and Proteus vulgaris. Antibacterial activity was determined by agar-well diffusion method wherein a suspension containing bacteria 100 μL was spread on agar medium and wells were punched using a sterile cork borer. Different plant extracts (100 μL) were filled into each well followed by incubation of the petri dishes at 37 °C for 24 h. On completion of the incubation period, the radius of inhibition zones formed was measured and compared with inhibition zone obtained using streptomycin (10 μg/ mL) as a reference standard and DMSO (10%) used as a negative control.

Estimation of total phenolic content

The total phenolic concentration in different solvent extracts was analyzed by Folin-Ciocalteu method with gallic acid as the standard (Ainsworth, Gillespi, 2007Ainsworth EA, Gillespie KM. Estimation of total phenolic content and other oxidation substrates in plant tissues using Folin-Ciocalteu reagent. Nat Protoc. 2007;2(4):875-877.). Gallic acid (standard) (400 µL) and sodium carbonate (1.6 mL) were added to Folin-Ciocalteu reagent (2 mL) and repeated similarly with the different plant extracts. The mixture was incubated at room temperature for an hour and the absorbance recorded on a spectrophotometer (Lab India) at 765 nm. The entire estimations were done in triplicates, and the results are expressed as mg gallic acid equivalent (GAE) /g of extract.

Antioxidant activity

The free-radical scavenging activity of extracts of N. Ramosissimum was measured by a decline in the absorbance solution of DPPH (2, 2-Diphenyl-1-picrylhydrazyl)prepared in methanol (400 µg/mL) (Feresin et al., 2002Feresin GE, Tapia A, Gutierrez RA, Delporte C, Backhouse EN, Schmeda-Hirschmann G. Free radical scavengers, anti-inflammatory and analgesic activity of Acaena magellanica. J Pharm Pharmacol. 2002;54(6):835-844.). Stock solution of DPPH (100 µL) was mixed different concentrations of N. ramosissimum extracts ranging from 10-200 µg/mL. The solutions were incubated under dark conditions for 20 min. The absorbance was measured at 517 nm. Ascorbic acid was taken as a measure of positive control and percent inhibition of each extract was calculated using the following formula.

Free radical

S c a v e n g i n g (%) = \frac{* A b s o r b a n c e o f c o n t r o l - * A b s o r b a n c e o f s a m p l e}{* A b s o r b a n c e o f c o n t r o l} \times 100

Using the values of percent inhibition of each extract, IC₅₀ value was calculated.

Total phenolic content vs. antioxidant potential

To analyse the relationship between total phenolic content derived by Folin-Ciocalteu method and antioxidant activity assayed by DPPH assay of the plant extracts, a regression curve was obtained for best fit data and the corresponding R² value was calculated. The closer the value of R² to 1.0, the better the fit of the regression curve (Piluzza, Bullitta, 2011Piluzza G, Bullitta S. Correlations between phenolic content and antioxidant properties in twenty-four plant species of traditional ethnoveterinary use in the Mediterranean area. Pharm Biol. 2011;49(3):240-247.).

Oxidative DNA damage protection activity

In order to study the DNA damage protection activity of plant extracts an experiment was conducted taking DNA isolated from human blood. DNA sample (10 μL) was added in a microcentrifuge tube covered completely by a black paper to avoid any oxidation caused by sunlight/ tubelight. Plant extract (10 μL) was mixed with the DNA sample and incubated for 10 min at room temperature followed by addition of Fenton’s reagent (10 μL) to the above mixture, vortexed and incubated at room temperature for an hour under dark conditions. Subsequently, from each tube, 15 μL of the mixture was taken and mixed with loading dye (6x, 3 μL) and loaded on a agarose gel (1%) containing ethidium bromide. Electrophoresis was performed at 50 V until the tracking dye reached 1 cm below the upper edge of the gel. The DNA was observed and photographed on a digital gel doc as per reported protocol (Balakrishnan, Paramasivam, Arulkumar, 2014Balakrishnan B, Paramasivam S, Arulkumar A. Evaluation of the lemongrass plant (Cymbopogon citratus) extracted in different solvents for antioxidant and antibacterial activity against human pathogens. Asian Pac J Trop Dis. 2014;4(1):S134-S139.).

Alpha amylase inhibitory activity

The assay reaction mixture comprising sodium phosphate buffer (200 μL, 0.02 M), porcine pancreatic alpha amylase enzyme(0.04 units) and the plant extracts at a concentration range of 10 to 200 μg/mL were incubated for 10 min at room temperature. The three-dimensional structure of porcine pancreatic alpha amylase enzyme is extremely similar to that of human pancreatic α-amylase. Various analysis by molecular cloning and also primary structure analysis of porcine pancreatic α-amylase exhibited maximum homology (87.1%) with the sequence of human pancreatic α-amylase sequence among all the other amylases (Anitha, Muralikrishna, 2009Anitha Gopal B, Muralikrishna G. Porcine pancreatic α-amylase and its isoforms: Purification and kinetic studies. Int J Food Prop. 2009;12(3):571-86.). Starch (200 μL) was added in each test tube and subsequently DNS reagent (3,5-Dinitrosalicylic acid) (400 μL) was added in order to cease the reaction. The mixture was then placed on a boiling water bath for 5 min which was further cooled to room temperature and diluted with distilled water (15 mL). The absorbance of the mixture was recorded at 540 nm. The same was repeated for the controls where plant extracts were replaced by an equal quantity of distilled water and the reference standard used was Metformin (10 to 200 μg/ mL). The percent inhibition was calculated according to the following formula (Nanumala, Tulasi, Sujitha, 2015Nanumala SK, Tulasi P, Sujitha E. In vitro anti-diabetic activity of seed extracts of Cassia auriculata and Cassia angustifolia. Eur J Exp Biol. 2015;5(5):12-17.).

A l p h a a m y l a s e i n h i b i t o r y a c t i v i t y (%) = \frac{* A b s o r b a n c e o f c o n t r o l - * A b s o r b a n c e o f s a m p l e}{* A b s o r b a n c e o f c o n t r o l} \times 100

The IC50 values were calculated by plotting graphs between percent inhibitions versus log inhibitor.

Statistical Methods

The experimental data was collected in triplicates and the results expressed by their mean values and standard error (SE). One way analysis of variance (ANOVA) was performed (SPSS version 17.0) and significance of difference determined according to Duncan’s multiple range test (DMRT). p value≤0.05 was considered to be statistically significant.

RESULTS AND DISCUSSION

Nanorrhinum ramosissimum has been in use as a traditional folk medicine to treat microbial infections and constitute potent sources of conventional antimicrobial agents (Amin et al., 2017Amin A, Emmy T, Kenn F, Vassiliki E, Sandra A, Luc P, et al. In vitro and in silico antidiabetic and antimicrobial evaluation of constituents from Kickxia ramosissima (Nanorrhinum ramosissimum). Front Pharmacol. 2017;8:232.). During the present study, the effectiveness of different solvent extracts (methanol, ethanol, ethyl acetate, petroleum ether, aqueous) of the plant (in vivo, in vitro regenerants) were analyzed against different pathogens. Zone of inhibition values of the experiment and the results obtained exhibited that most of the solvent extracts possessed good antimicrobial properties (Table I). The inhibition potency of the methanolic shoot extract against tested organisms, was in the order of E. coli>P. vulgaris>B. subtilis and no inhibition was found in M. smegmatis. In ethanolic extracts the order was P. vulgaris>E. coli>M. smegmatis>B. subtilis where the values ranges from 2.63 to 2.90. In ethyl acetate. extracts, it was P. vulgaris>E. coli>B. subtilis. In petroleum ether, inhibition was only observed in P. vulgaris among all the other tested strains whereas in aqueous extract, the order of organisms was E. coli>P. vulgaris>M. smegmatis. From all the above results, it can be concluded that shoot extracts are more bioactive where the highest inhibition was obtained with methanolic and aqueous extracts with a zone of inhibition measuring 4.8 and 4.4 mm (E. coli) respectively. The lowest inhibition was obtained with ethyl acetate extract in B. subtilis (1.8 mm) where as petroleum ether extract exhibited no inhibition in all the organisms tested except P. vulgaris (2.03 mm).

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TABLE I
Antimicrobial activity of plant extracts of Nanorrhinum ramosissimum

To the methanolic root extract, the tested strains can be ordered as B. subtilis>P. vulgaris>E. coli where as inethanolic extract it is M. smegmatis>P. vulgaris>B. subtilis=E. coli. In ethyl acetate extracts, it is B. subtilis>P. vulgaris and no inhibition was observed in the other tested strains. In petroleum ether extracts, the order is B. subtilis>M. smegmatis and no inhibition was observed in the E. coli and P. vulgaris where as in aqueous extracts, the trend was B. subtilis>E. coli>M. smegmatis while P. vulgaris displayed no inhibition. Results obtained from the root extracts indicated that the highest inhibition was obtained in ethyl acetate extract in B. subtilis (2.73 mm) where as the lowest inhibition was obtained with ethanolic extract in E. coli (0.86 mm). Antimicrobial constituents present in plant extracts have been reported to have certain mechanisms of their action including inhibition of cell wall synthesis, protein/nucleic acid synthesis, inhibition of essential metabolite synthesis and destruction of plasma membrane synthesis by intermingling with microbial cell membrane components (i.e. enzymes, proteins) resulting into their distortion due to the release of protons to the exterior of cell which leads to cell death(Burt, 2004Burt S. Essential oils: Their antibacterial properties and potential application in foods: A review. Int J Food Microbiol. 2004;94(3):223-253.; Gill, Holley, 2006Gill AO, Holley RA. Disruption of Escherichia coli, Listeria monocytogenes and Lactobacillus sakei cellular membranes by plant oil aromatics. Int J Food Microbiol . 2006;108(1):1-9.) which could be the probable reason for the antimicrobial activity of N. ramosissimum plant extracts.

An estimation of the phenolic content was performed in the plant samples of N. ramosissimum using various polar and non-polar solvents in order to analyze its correlation with antioxidant activity. A comparison of phenolic contents obtained with different solvent extracts is shown in Table SI. Amongst all the samples analyzed methanolic extract of in vivo shoots exhibited the highest phenolic content (57.14±0.72 μg/mL) followed by ethanolic extract (43.67±0.62 μg/mL) and methanolic extract of the in vitro shoot (41.34±0.32 μg/mL).

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TABLE SI
Total phenolic content of different solvent extracts from in vitro and in vivo shoot and root parts of N. ramosissimum

Disorders like liver cirrhosis, atherosclerosis, cancer, diabetes and other neurodegenerative diseases are caused due to the generation of free radicals by metabolic activities in the human body, caused by reactive oxygen species which can be averted by using various antioxidants. This becomes particularly important when endogenous factors cannot ensure a complete control and protection of the organism against reactive oxygen species. In such cases, the need for exogenous antioxidants as a supplementation arises, to keep us safe from the oxidative processes (Kanatt, Chander, Sharma, 2007Kanatt SR, Chander R, Sharma A. Antioxidant potential of mint (Mentha spicata L.) in radiation-processed lamb meat. Food Chem . 2007;100(2):451-458.). The remedial potential of medicinal plants in reducing such free radical induced tissue injury, confirms that many plants have antioxidant activities that can be therapeutically useful (Piluzza, Bullitta, 2011Piluzza G, Bullitta S. Correlations between phenolic content and antioxidant properties in twenty-four plant species of traditional ethnoveterinary use in the Mediterranean area. Pharm Biol. 2011;49(3):240-247.). Since, herbal constituents have the potential to inhibit the oxidation caused by these free radicals, the antioxidant activity of the different extracts of N. ramosissimum were also investigated. DPPH assay is one of the methods to investigate the antioxidant action of plant constituents (Koleva et al., 2002Koleva II, Van Beek TA, Linssen JPH, de Groot A, Evstatieva LN. Screening of plant extracts for antioxidant activity: A comparative study on three testing methods. Phytochem Analysis. 2002;13(1):8-17.). The spectrophotometric quantification of the level of DPPH scavenging in N. ramosissimum extracts (shoot, root parts) was conducted in order to assess their free radical scavenging potential. An analysis of the results obtained, indicates that there is a rise in the scavenging effect of N. ramosissimum extracts with an increase in its concentration. The methanolic in vivo and in vitro shoot extract at a concentration of 200 µg/mL exhibited maximum free radical scavenging capacity (96.50±0 μg/ mL, 95.0±0 μg/mL respectively) and ethanolic in vivo shoot extract (95.06±0.06 μg/mL) at 200µg/mL. Standard ascorbic acid had an IC₅₀ value of 52.2±0.07 µg/mL, while amongst all the samples analysed, methanolic extract of in vivo shoot samples showed the least and most suitable IC₅₀ value (61.07±0.53 µg/mL) as comparable to the standard followed by the in vitro shoot extract of the same solvent (64.33±0.33 µg/mL) (Table S II). It can be inferred from the results obtained that the methanolic extract of in vivo shoot is most appropriate in comparison to the standard as an antioxidizing agent where as in root samples, both methanolic (90.20%) and ethanolic (90.50%) extracts of in vivo samples exhibited the maximum inhibition with IC₅₀ value of 76.70±0.12 µg/mL and 80.90±0.18 µg/mL respectively in comparison to the standard (Table S II). Among the root extracts, methanolic extracts of in vivo samples exhibited maximum inhibition as shown in Table S III but it is less than that of the shoot samples

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TABLE SII
DPPH assay of different solvent (Methanol, ethanol, ethyl acetate, petroleum ether and aqueous) extracts of shoot parts of both in vitro and in vivo samples of Nanorrhinum ramosissimum

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TABLE SIII
DPPH assay of different solvent (Methanol, ethanol, ethyl acetate, petroleum ether and aqueous) extracts of root parts of both in vitro and in vivo samples of Nanorrhinum ramosissimum

Various available reports indicate that there exists a correlation between total phenolic content and antioxidant potential but it may not always be true, since non-phenolic components can also be responsible for the antioxidant potential shown by different plant extracts (Kim et al., 2003Kim DO, Chun OK, Kim YJ, Moon HY, Lee CY. Quantification of polyphenolics and their antioxidant capacity in fresh plums. J Agric Food Chem.2003;51(22):6509-6515.; Djeridane et al., 2006Djeridane A, Yousfi M, Nadjemi B, Boutassouna D, Stocker P, Vidal N. Antioxidant activity of some Algerian medicinal plants extracts containing phenolic compounds. Food Chem . 2006;97(4):654-660.; Tabart et al., 2007Tabart J, Kevers C, Sipel A, Pincemail J, Defraigne JO, Dommes J. Optimisation of extraction of phenolics and antioxidants from black currant leaves and buds and of stability during storage. Food Chem . 2007;105(3):1268-1275.). The highest phenolic content was obtained in the methanolic extract that could be attributed to its high polar nature and also having good capacity for solubility to phenols (Zhao et al., 2006Zhao M, Yang B, Wang J, Li B, Jiang Y. Identification of the major flavonoids from pericarp tissues of lychee fruit in relation to their antioxidant activities. Food Chem . 2006; 98(3):539-544.). In order to study the phenolic dependency of antioxidant potential for N. ramosissimum, the phenolic estimation was done by the method as discussed previously(Ainsworth, Gillespie, 2007Ainsworth EA, Gillespie KM. Estimation of total phenolic content and other oxidation substrates in plant tissues using Folin-Ciocalteu reagent. Nat Protoc. 2007;2(4):875-877.). To estimate its dependency, different plots (linear, quadratic and exponential) were plotted. From the results obtained it can be inferred that there is a positive correlation between these two values for different extracts as depicted from the linear graphs obtained (in vitro shoot extract R² = 0.9007, in vivo shoot extract R² = 0.919, in vitro root extract R² = 0.952, in vivo root extract R² = 0.932). Their linear relationship curve gave the best fit with R² values ranging from 0.90 to 0.95. Previous reports also support our inference that there is a correlation between phenolic content and antioxidant activity. Numerous other components like reducing carbohydrates, ascorbates, carotenoids, terpenes, and tocopherols as well as the synergistic outcome amongst them could also possibly add on to the antioxidant activity (Babbar et al., 2011Babbar N, Oberoi HS, Uppal DS, Patil RT. Total phenolic content and antioxidant capacity of extracts obtained from six important fruit residues. Food Res Int. 2011;44(1):391-396.; Piluzza, Bullitta, 2011Piluzza G, Bullitta S. Correlations between phenolic content and antioxidant properties in twenty-four plant species of traditional ethnoveterinary use in the Mediterranean area. Pharm Biol. 2011;49(3):240-247.).

The effectiveness of N. ramosissimum extracts in DNA protection was investigated against free radicals induced by action of H O which indicated that all the extracts analysed possessed significant DNA damage protective potential against free radicals. DNA bands (Figure 2) were obtained in the test samples with induced oxidation. Studies have revealed that high concentrations of extra and intra-cellular glucose lead to oxidative stress during diabetes in general. Oxidative stress coexists with a diminution in the antioxidant significance which can boost the detrimental effects of free radicals (West, 2000West IC. Radicals and oxidative stress in diabetes. Diabet Med. 2000;17(3):171-180.). Supplementation with non-toxic antioxidants could provide a chemoprotective role in diabetes (Bajaj, Khan, 2012Bajaj S, Khan A. Antioxidants and diabetes. Indian J Endocr Metab. 2012;16(Suppl 2):S267-S271.). It has also been reported that oxidative injury could be enhanced during diabetes and can become a precursor for various cardiovascular disorders (Siti, Kamis, Kamsiah, 2015Siti HN, Kamisah Y, Kamsiah J. The role of oxidative stress, antioxidants and vascular inflammation in cardiovascular disease (a review). Vasc Pharmacol. 2015;71:40-56.). Treatments with various antioxidants can be helpful in managing such diseases due to their free radical scavenging activity and if the antioxidant is of natural origin than it will be an added benefit due to its lesser side effects.

FIGURE 2
DNA damage protection assay: A-DNA (human blood), B-DNA + Fenton’s reagent, C-DNA + Fenton’s reagent + aqueous plant extract, D-DNA + Fenton’s reagent + ethanolic plant extract, E-DNA + Fenton’s reagent + methanolic plant extract, F-DNA + Fenton’s reagent + petroleum ether plant extract, G-DNA + Fenton’s reagent + ethyl acetate plant extract.

Alpha amylase is an enzyme which plays an important role in the process of breakdown of long chain carbohydrates to glucose and is therefore involved in digestion and aids in intestinal absorption of the ingested food. It has been reported that inhibitors of alpha amylase are the key agents for the treatment of diabetes (Anagnostopoulouet al., 2006Anagnostopoulou MA, Kefalas P, Papageorgiou VP, Assimopoulou AN, Boskou D. Radical scavenging activity of various extracts and fractions of sweet orange peel (Citrus sinensis). Food Chem. 2006;94(1):19-25.). Moreover, there are reports that N. ramosissimum has been widely used in ancient times for the cure of diabetes, therefore, in order to confirm its antidiabetic potential the alpha amylase inhibition test was performed. The results of percentage alpha amylase inhibitory activity exhibited by the plant extracts and standard Metformin at a concentration 200 μg/mL showed a 73.59% inhibitory effect on the alphaamylase activity with an IC₅₀ value of 41.92±0.08μg/ml (Figure 3). The methanolic in vitro shoot extract at 200 μg/mL showed a maximum alpha amylase inhibition activity (59%) as compared to other extracts (Table S IV, Figure 3). Methanolic in vivo shoot samples exhibited a maximum inhibition percentage at equal concentration of 200 μg/mL (57.62%) with the lowest IC₅₀ value of 54.42±0.16 μg/mL. All the plant extracts showed a promising alpha amylase inhibitory activity in a dosedependent manner. Among the root extracts, ethanolic (47%) and methanolic (46%) extracts of in vivo samples exhibited maximum inhibition at a concentration of 200 μg/mL with IC₅₀ values of 96.63±0.44 μg/mL and 100.96±0.28 μg/mL respectively (Table S V, Figure 3). On comparing the IC₅₀ values of each extract, it was found that the most promising value that is comparable to the control (41.92±0.08 μg/mL) was obtained in the methanolic shoot extracts (in vitro 54.42±0.16 μg/mL; in vivo 66.09 ± 0.12 μg/mL) which is attributed to the presence of more flavonoids and glycosides in the herb as has been earlier reported (Amin et al., 2017Amin A, Emmy T, Kenn F, Vassiliki E, Sandra A, Luc P, et al. In vitro and in silico antidiabetic and antimicrobial evaluation of constituents from Kickxia ramosissima (Nanorrhinum ramosissimum). Front Pharmacol. 2017;8:232.).

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TABLE SIV
Alpha amylase inhibition assay of different solvent (Methanol, ethanol, ethyl acetate, petroleum ether and aqueous) extract of shoot parts of both in vitro and field samples of Nanorrhinum ramosissimum

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TABLE SV
Alpha amylase inhibition assay of different solvent (Methanol, ethanol, ethyl acetate, petroleum ether and aqueous) extract of root parts of both in vitro and field samples of Nanorrhinum ramosissimum

FIGURE 3
Alpha amylase inhibition assay of different extracts (Methanol, ethanol, ethyl acetate petroleum ether, aqueous) of shoot and root parts of in vivo and in vitro plant samples. The data represents mean of three experiments ±SE.

CONCLUSION

The results of the study indicated the potential of various extracts obtained from polar and non polar solvents of Nanorrhinum ramosissimum for their substantial antimicrobial, antioxidant, DNA damage protection and α-amylase inhibitory activities. The results obtained signify that in general the methanolic extracts emerged as the best solvent followed by ethanolic extracts of N. ramosissimum. Shoot extracts exhibited more antimicrobial potential against the tested strains in comparison to root extracts. Highest phenolic concentration as well as antioxidant potential was obtained in the methanolic shoot extract and on correlating the results obtained, it can be concluded that phenols do have a role in the antioxidant attribute of the herb. Antioxidant activity was also confirmed from the DNA damage assay as plant extracts were potentially able to protect the DNA damage. Antidiabetic potential of the herb has also been demonstrated and the best results were obtained in methanolic shoot extracts of the herb. Significant differences were not observed between the extracts of in vivo and in vitro regenerants indicating the possibility of large scale cultivation of herb under controlled conditions for its commercial usage. The result of the present study supports the traditional ayurvedic conception that the herb has a substantial potential in management of various human diseases.

REFERENCES

Ainsworth EA, Gillespie KM. Estimation of total phenolic content and other oxidation substrates in plant tissues using Folin-Ciocalteu reagent. Nat Protoc. 2007;2(4):875-877.
Amin A, Emmy T, Kenn F, Vassiliki E, Sandra A, Luc P, et al. In vitro and in silico antidiabetic and antimicrobial evaluation of constituents from Kickxia ramosissima (Nanorrhinum ramosissimum). Front Pharmacol. 2017;8:232.
Anagnostopoulou MA, Kefalas P, Papageorgiou VP, Assimopoulou AN, Boskou D. Radical scavenging activity of various extracts and fractions of sweet orange peel (Citrus sinensis). Food Chem. 2006;94(1):19-25.
Anitha Gopal B, Muralikrishna G. Porcine pancreatic α-amylase and its isoforms: Purification and kinetic studies. Int J Food Prop. 2009;12(3):571-86.
Babbar N, Oberoi HS, Uppal DS, Patil RT. Total phenolic content and antioxidant capacity of extracts obtained from six important fruit residues. Food Res Int. 2011;44(1):391-396.
Bajaj S, Khan A. Antioxidants and diabetes. Indian J Endocr Metab. 2012;16(Suppl 2):S267-S271.
Balakrishnan B, Paramasivam S, Arulkumar A. Evaluation of the lemongrass plant (Cymbopogon citratus) extracted in different solvents for antioxidant and antibacterial activity against human pathogens. Asian Pac J Trop Dis. 2014;4(1):S134-S139.
Bhandari C. Vanousadhi Chandrodaya: An Encyclopedia of Indian Botanist and Herbs. Varanasi: Chaukhamba Sanskrut Sansthan; 2006.117p.
Burt S. Essential oils: Their antibacterial properties and potential application in foods: A review. Int J Food Microbiol. 2004;94(3):223-253.
Djeridane A, Yousfi M, Nadjemi B, Boutassouna D, Stocker P, Vidal N. Antioxidant activity of some Algerian medicinal plants extracts containing phenolic compounds. Food Chem . 2006;97(4):654-660.
Feresin GE, Tapia A, Gutierrez RA, Delporte C, Backhouse EN, Schmeda-Hirschmann G. Free radical scavengers, anti-inflammatory and analgesic activity of Acaena magellanica. J Pharm Pharmacol. 2002;54(6):835-844.
Ghorbani A. Best herbs for managing diabetes: a review of clinical studies. Braz J Pharm Sci. 2013;49(3):413-422.
Gill AO, Holley RA. Disruption of Escherichia coli, Listeria monocytogenes and Lactobacillus sakei cellular membranes by plant oil aromatics. Int J Food Microbiol . 2006;108(1):1-9.
Jan S, Khan MR. Antipyretic, analgesic and antiinflammatory effects of Kickxia ramosissima. J Ethnopharmacol.2016;182:90-100.
Kanatt SR, Chander R, Sharma A. Antioxidant potential of mint (Mentha spicata L.) in radiation-processed lamb meat. Food Chem . 2007;100(2):451-458.
Kim DO, Chun OK, Kim YJ, Moon HY, Lee CY. Quantification of polyphenolics and their antioxidant capacity in fresh plums. J Agric Food Chem.2003;51(22):6509-6515.
Koleva II, Van Beek TA, Linssen JPH, de Groot A, Evstatieva LN. Screening of plant extracts for antioxidant activity: A comparative study on three testing methods. Phytochem Analysis. 2002;13(1):8-17.
Kirtikar KR, Basu BD. Indian medicinal plants. 2nd ed. DehraDun: International Book Distributors; 2005.
Myo EM, Maung CE, Mya KM, Khai AA. Characterization of bacterial endophytes from Myanmar medicinal plants for antimicrobial activity against human and plant pathogens. Braz J Pharm Sci . 2020;56:e17705.
Nanumala SK, Tulasi P, Sujitha E. In vitro anti-diabetic activity of seed extracts of Cassia auriculata and Cassia angustifolia. Eur J Exp Biol. 2015;5(5):12-17.
Pandya PN, Aghera HB, Ashok BK, Acharya R. Diuretic activity of Linaria ramosissima (Wall.) Janch. leaves in albino rats. Ayu. 2012;33(4):576-578.
Piluzza G, Bullitta S. Correlations between phenolic content and antioxidant properties in twenty-four plant species of traditional ethnoveterinary use in the Mediterranean area. Pharm Biol. 2011;49(3):240-247.
Pullaiah T, Naidu K. Antidiabetic plants in India and herbal based antidiabetic research. New Delhi: Regency Publications; 2003.
Sharma J, Koul A, Sharma S, Shankarayan R, Mallubhotla S. In vitro propagation of Nanorrhinum ramosissimum (Wall.) Betsche: A traditionally important medicinal plant. Kuwait JSci. 2021;48(3).
Siti HN, Kamisah Y, Kamsiah J. The role of oxidative stress, antioxidants and vascular inflammation in cardiovascular disease (a review). Vasc Pharmacol. 2015;71:40-56.
Tabart J, Kevers C, Sipel A, Pincemail J, Defraigne JO, Dommes J. Optimisation of extraction of phenolics and antioxidants from black currant leaves and buds and of stability during storage. Food Chem . 2007;105(3):1268-1275.
West IC. Radicals and oxidative stress in diabetes. Diabet Med. 2000;17(3):171-180.
Zhao M, Yang B, Wang J, Li B, Jiang Y. Identification of the major flavonoids from pericarp tissues of lychee fruit in relation to their antioxidant activities. Food Chem . 2006; 98(3):539-544.

Publication Dates

Publication in this collection
08 May 2023
Date of issue
2023

History

Received
07 Nov 2019
Accepted
07 Mar 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[2] Amin A, Emmy T, Kenn F, Vassiliki E, Sandra A, Luc P, et al. In vitro and in silico antidiabetic and antimicrobial evaluation of constituents from Kickxia ramosissima (Nanorrhinum ramosissimum). Front Pharmacol. 2017;8:232.

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[8] Bhandari C. Vanousadhi Chandrodaya: An Encyclopedia of Indian Botanist and Herbs. Varanasi: Chaukhamba Sanskrut Sansthan; 2006.117p.

[9] Burt S. Essential oils: Their antibacterial properties and potential application in foods: A review. Int J Food Microbiol. 2004;94(3):223-253.

[10] Djeridane A, Yousfi M, Nadjemi B, Boutassouna D, Stocker P, Vidal N. Antioxidant activity of some Algerian medicinal plants extracts containing phenolic compounds. Food Chem . 2006;97(4):654-660.

[11] Feresin GE, Tapia A, Gutierrez RA, Delporte C, Backhouse EN, Schmeda-Hirschmann G. Free radical scavengers, anti-inflammatory and analgesic activity of Acaena magellanica. J Pharm Pharmacol. 2002;54(6):835-844.

[12] Ghorbani A. Best herbs for managing diabetes: a review of clinical studies. Braz J Pharm Sci. 2013;49(3):413-422.

[13] Gill AO, Holley RA. Disruption of Escherichia coli, Listeria monocytogenes and Lactobacillus sakei cellular membranes by plant oil aromatics. Int J Food Microbiol . 2006;108(1):1-9.

[14] Jan S, Khan MR. Antipyretic, analgesic and antiinflammatory effects of Kickxia ramosissima. J Ethnopharmacol.2016;182:90-100.

[15] Kanatt SR, Chander R, Sharma A. Antioxidant potential of mint (Mentha spicata L.) in radiation-processed lamb meat. Food Chem . 2007;100(2):451-458.

[16] Kim DO, Chun OK, Kim YJ, Moon HY, Lee CY. Quantification of polyphenolics and their antioxidant capacity in fresh plums. J Agric Food Chem.2003;51(22):6509-6515.

[17] Koleva II, Van Beek TA, Linssen JPH, de Groot A, Evstatieva LN. Screening of plant extracts for antioxidant activity: A comparative study on three testing methods. Phytochem Analysis. 2002;13(1):8-17.

[18] Kirtikar KR, Basu BD. Indian medicinal plants. 2nd ed. DehraDun: International Book Distributors; 2005.

[19] Myo EM, Maung CE, Mya KM, Khai AA. Characterization of bacterial endophytes from Myanmar medicinal plants for antimicrobial activity against human and plant pathogens. Braz J Pharm Sci . 2020;56:e17705.

[20] Nanumala SK, Tulasi P, Sujitha E. In vitro anti-diabetic activity of seed extracts of Cassia auriculata and Cassia angustifolia. Eur J Exp Biol. 2015;5(5):12-17.

[21] Pandya PN, Aghera HB, Ashok BK, Acharya R. Diuretic activity of Linaria ramosissima (Wall.) Janch. leaves in albino rats. Ayu. 2012;33(4):576-578.

[22] Piluzza G, Bullitta S. Correlations between phenolic content and antioxidant properties in twenty-four plant species of traditional ethnoveterinary use in the Mediterranean area. Pharm Biol. 2011;49(3):240-247.

[23] Pullaiah T, Naidu K. Antidiabetic plants in India and herbal based antidiabetic research. New Delhi: Regency Publications; 2003.

[24] Sharma J, Koul A, Sharma S, Shankarayan R, Mallubhotla S. In vitro propagation of Nanorrhinum ramosissimum (Wall.) Betsche: A traditionally important medicinal plant. Kuwait JSci. 2021;48(3).

[25] Siti HN, Kamisah Y, Kamsiah J. The role of oxidative stress, antioxidants and vascular inflammation in cardiovascular disease (a review). Vasc Pharmacol. 2015;71:40-56.

[26] Tabart J, Kevers C, Sipel A, Pincemail J, Defraigne JO, Dommes J. Optimisation of extraction of phenolics and antioxidants from black currant leaves and buds and of stability during storage. Food Chem . 2007;105(3):1268-1275.

[27] West IC. Radicals and oxidative stress in diabetes. Diabet Med. 2000;17(3):171-180.

[28] Zhao M, Yang B, Wang J, Li B, Jiang Y. Identification of the major flavonoids from pericarp tissues of lychee fruit in relation to their antioxidant activities. Food Chem . 2006; 98(3):539-544.

Plant part	Extraction solvent	Zone of inhibition (mm)
Plant part	Extraction solvent	*B. subtilis*	*M. smegmatis*	*E. coli*	*P. vulgaris*
Shoot extract	Methanol	2.33±0.33b	N	4.80±0.12a	3.93±0.06a
	Ethanol	2.63±0.36a	2.83±0.08a	2.83±0.08c	2.90±0.10b
	Ethyl acetate	1.80±0.11c	N	1.83±0.08d	2.90±0.08b
	Petroleum ether	N	N	N	2.03±0.08c
	Aqueous	N	1.86±0.08b	4.40±0.14b	2.90±0.05b
Root extract	Methanol	1.80±0.11c	N	1.76±0.14b	1.30±0.05a
	Ethanol	0.86±0.08d	2.83±0.08a	0.86±0.08c	1.48±0.08b
	Ethyl acetate	2.73±0.08a	N	N	1.26±0.03c
	Petroleum ether	1.90±0.05b	0.90±0.057c	N	N
	Aqueous	2.70±0.14a	1.46±0.98b	1.93±0.12a	N

Extraction Solvent	Total phenolic content±SE ( mg GAE/gm extract)
	Shoot		Root
	*In vitro*	*In vivo*	*In vitro*	*In vivo*
Methanol	41.34±0.32	57.14±0.72	36.44±0.12	21.34±0.12
Ethanol	36.67±0.22	43.67±0.62	26.64±0.56	18.47±0.19
Petroleum ether	31.89±0.12	38.89±0.65	32.69±0.11	12.49±0.32
Aqueous	31.89±0.16	39.89±0.52	21.89±0.11	10.59±0.13
Ethyl acetate	14.51±0.08	29.41±0.05	16.31±0.14	16.21±0.43

Extraction Solvent	Concentration	In vivo sample		In vitro sample		Standard
Extraction Solvent	(μg/mL)	% inhibition	IC50 (μg/mL)	% inhibition	IC50 (μg/mL)	% inhibition	IC50 (μg/L)
Methanol	10	91.03±0.03	61.07±0.53	91.03±0.03	64.33 ±0.33	96.37±0.65	52.2±0.07
	20	92.96±0.61		91.5±0.00		96.90±0.16
	40	92.93±0.03		93±0.00		97.21±0.22
	60	94±0		93.066±0.06		97.40±0.53
	80	95.03±0.03		94±0		97.73±0.53
	100	96±0		94.5±0		98±0.21
	150	96.46±0.03		94.96±0.03		98.1±0.17
	200	96.5±0		95±0		98.2±0.13
Ethanol	10	91.033±0.03	66.24±0.94	88.506±0.006	74 ±0.94
	20	91.5±0.00		88.51±0.01
	40	93±0		89.5±0.00
	60	93±0		90±0
	80	94.033±0.03		90.13±0.0
	100	94.5±0.00		90.5±0.00
	150	95±0.00		91±0.00
	200	95.066±0.06		91.03±0.04
Ethyl acetate	10	89±0.00	69.25±0.09	85.5±0.00	80.44 ±0.18
	20	89±0.00		86±0.00
	40	90±0.00		86.803±0.003
	60	90.3±0.003		88±0
	80	90.3±0.00		88.033±0.003
	100	90.50±0.003		89.50±0.006
	150	91±0.00		90.133±0.03
	200	91±0.00		90.5±0.003
Petroleum ether	10	87.06±0.066	89.02±0.55	90.03±0.03	92.658 ±0.35
	20	87.53±0.033		90±0.00
	40	87.56±0.066		90.303±0.003
	60	88.06±0.066		90.71±0.005
	80	88±0.00		92±0
	100	89.5±0.00		92.223±0.01
	150	90±0.00		92.5±0
	200	90.13±0.057		93.03±0.03
Aqueous	10	85.5±0	76.09±0.49	87.033±0.03	90.48 ±0.56
	20	86.04±0.04		87.5±0.00
	40	86.8±0.00		87.5±0.00
	60	88±0		88±0.00
	80	88.03±0.30		88.033±0.033
	100	89.503±0.03		89.506±0.006
	150	90.03±0.033		90±0.00
	200	90.166±0.03		90.20±0.003

Extraction Solvent	Concentration	In vivo sample		In vitro sample		Standard
Extraction Solvent	(μg/mL)	% inhibition	IC50 (μg/mL)	% inhibition	IC50 (μg/mL)	% inhibition	IC50 (μg/L)
Methanol	10	85.503±0.03	76.705±0.12	87±0.00	89.73 ±0.28	96.37±0.65	52.2±0.07
	20	86.033±0.03		87.5±0.00		96.90±0.16
	40	86.8±0.00		87.50±0.00		97.21±0.22
	60	88±0.00		88±0.00		97.40±0.53
	80	88±0.00		88.03±0.03		97.73±0.53
	100	89.50±0.003		89.5±0.00		98.0±0.21
	150	90±0.00		90.00±0.00		98.1±0.17
	200	90.20±0.006		90.2±0.00		98.2±0.13
Ethanol	10	85.5±0.00	80.90±0.18	86±0.00	104.368 ±0.21
	20	86±0.00		87.04±0.04
	40	86.803±0.03		87±0
	60	88.04±0.04		87.5±0.003
	80	88±0.00		87.5±0
	100	89.50±0.006		88.066±0.03
	150	90±0.00		88±0.00
	200	90.5±0.00		90±0.00
Ethyl acetate	10	86±0.00	104.13±0.56	84.5±0.00	110.50 ±0.36
	20	87.04±0.04		84.50±0.00
	40	87±0.00		85±0.00
	60	87.50±0.003		85.6±0.00
	80	87.5±0.00		86.04±0.04
	100	88.033±0.03		86±0.00
	150	88.06±0.06		86.5±0.00
	200	90±0.00		88.03±0.00
Petroleum ether	10	84.5±0.00	110.55±0.30	84.5±0.00	118.73 ±0.48
	20	84.5±0.00		84.50±0.003
	40	85±0.00		84.5±0.00
	60	85.6±0.00		85±0.00
	80	86.04±0.04		85±0
	100	86±0.00		85.6±0.017
	150	86.5±0.00		86.03±0.03
	200	88±0		87±0.4
Aqueous	10	84.5±0.00	119.121±0.16	84±0.00	126.50 ±0.26
	20	84.50±0.00		84±0.00
	40	84.5±0.00		84.04±0.04
	60	85±0.00		84.506±0.006
	80	85±0.00		84.5±0.00
	100	85.606±0.003		84.50±0.002
	150	86±0.00		85±0
	200	87±0.00		86±0

Extraction Solvent	Concentration	In vivo sample		In vitro sample		Standard
Extraction Solvent	(μg/mL)	% inhibition	IC50 (μg/mL)	% inhibition	IC50 (μg/mL)	% inhibition	IC50 (μg/L)
Methanol	10	44±0.00	54.42±0.16	42±0	66.09 ±0.12	48±0	41.92 ±0.12
	20	50.8±0.00		46.03±0.04		56.04±0.04
	40	51±0.00		51±0		66±0
	60	52.04±0.04		52.03±0.03		67.13±0.066
	80	52.80±0.003		52.8±0.23		68±0
	100	54±0.00		55.04±0.12		71.5±0.30
	150	57.03±0.03		56.04±0.32		72.4±0
	200	57.62±0.02		59±0.03		73.59±0.0
Ethanol	10	44±0.00	70.58±0.09	33.5±0.00	83.75 ±0.23
	20	46.03±0.03		33.9±0.00
	40	49±0.00		36.03±0.03
	60	49.9±0.24		37±0.00
	80	50±0.00		40.04±0.04
	100	50.5±0.01		42±0.00
	150	53.03±0.00		43±0
	200	54±0.00		44±0
Ethyl acetate	10	16.8±0.00	108.388±0.03	17.2±0.00	122.02 ±0.20
	20	17.2±0.00		17.2±0.00
	40	17.20±0.00		17.20±0.00
	60	19.2±0.00		19.2±0.00
	80	19.6±0.00		19.6±0.03
	100	20±0.00		20.03±0.03
	150	20±0.00		20±0.00
	200	24±0.00		24±0.00
Petroleum ether	10	33.5±0.00	90.14±0.12	23±0.00	96.122 ±0.04
	20	34±0.00		23.04±0.04
	40	36.04±0.04		25.6±0.00
	60	36.8±0.00		27±0.00
	80	39.6±0.00		27.5±0.00
	100	40.03±0.03		28±0.00
	150	40.11±0.01		29±0.00
	200	43±0.00		32±0.00
Aqueous	10	20.4±0.00	89.4681±0.01	21.6±0.00	123.60 ±0.010
	20	21.6±0.0		22±0.00
	40	22±0		22±0.0.00
	60	22.13±0.02		22±0.00
	80	23±0		23±0.00
	100	23.30±0.003		23.30±0.00
	150	25.6±0.00		25.603±0.00
	200	26±0.00		28±0.00

Brasil

Brasil

Bioactivity evaluation of least explored traditionally acclaimed medicinally potent herb Nanorrhinum ramosissimum(Wall.) Betsche

Abstract

INTRODUCTION

MATERIAL AND METHODS

Sample preparation

Antimicrobial activity

Estimation of total phenolic content

Antioxidant activity

Free radical

Total phenolic content vs. antioxidant potential

Oxidative DNA damage protection activity

Alpha amylase inhibitory activity

Statistical Methods

RESULTS AND DISCUSSION

CONCLUSION

REFERENCES

Publication Dates

History