Address for correspondence: Prof. Rajiv Gupta, Department of Pharmacognosy, Faculty of Pharmacy, Babu Banarasi Das National Institute of Technology and Management, Lucknow, Uttar Pradesh, India. E-mail: moc.liamffider@169vijar
Received 2011 Feb 18; Revised 2011 Apr 2; Accepted 2012 Aug 23. Copyright : © Pharmacognosy ReviewsThis is an open-access article distributed under the terms of the Creative Commons Attribution-Noncommercial-Share Alike 3.0 Unported, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Mimosa pudica L. (Mimosaceae) also referred to as touch me not, live and die, shame plant and humble plant is a prostrate or semi-erect subshrub of tropical America and Australia, also found in India heavily armed with recurved thorns and having sensitive soft grey green leaflets that fold and droop at night or when touched and cooled. These unique bending movements have earned it a status of ‘curiosity plant’. It appears to be a promising herbal candidate to undergo further exploration as evident from its pharmacological profile. It majorly possesses antibacterial, antivenom, antifertility, anticonvulsant, antidepressant, aphrodisiac, and various other pharmacological activities. The herb has been used traditionally for ages, in the treatment of urogenital disorders, piles, dysentery, sinus, and also applied on wounds. This work is an attempt to explore and compile the different pharmacognostic aspects of the action plant M. pudica reported till date.
Keywords: Antidepressant, aphrodisiac, diuretic, Mimosa pudica, pulvini, symbiontsMimosa pudica L. is a creeping annual or perennial herb. It has been identified as lajjalu in Ayurveda and has been found to have antiasthmatic, aphrodisiac, analgesic, and antidepressant properties. M. pudica is known to possess sedative, emetic, and tonic properties, and has been used traditionally in the treatment of various ailments including alopecia, diarrhea, dysentery, insomnia, tumor, and various urogenital infections. Phytochemical studies on M. pudica have revealed the presence of alkaloids, non-protein amino acid (mimosine), flavonoids C-glycosides, sterols, terpenoids, tannins, and fatty acids.[1] Two well-known movements are observed in M. pudica L. (ojigi-so in Japanese): one is the very rapid movement of the leaves when it is stimulated by touch, heating, etc., and the other is the very slow, periodical movement of the leaves called nyctinastic movement which is controlled by a biological clock.[2] The leaves of the sensitive plant M. pudica can adapt their closing response to electrical and mechanical stimulation so that they reopen to repeated stimulation. The more intense the stimuli and the longer the intertribal interval, the longer it takes to adapt. Leaves adapted to the effects of mechanical stimulation can still respond by closing to electrical stimulation and vice versa.[3]
Mimosa pudica L. is a diffuse prickly undershrub belonging to family Mimosaceae [ Figure 1 ].
Mimosa pudica flower head
Whole plant, leaves, and roots.
Laajvanti, Touch me not, and Chhui-mui
Ayurveda – Lajjalu, Namaskari, Samangaa, Samokchini, and Shamipatraa
Siddha – Thottal Chinungi.[4]
English – Sensitive plant
Hindi – Laajvanti and Chhui-mui
Telugu – Attapatti and Peddanidrakanni
Tamil – Tottaaladi and Thottalchnungi
Kannada – Lajja, Nachika and Mudugu-davare
The plant is a native of tropical America and naturalized nearly all through the tropical and subtropical parts of India.
Commonly distributed in open-spaces, especially road side, cultivated land, and waste area.
By seeds and vegetative methods.
Semi-prostrate, prickly course herb, or subshrub up to 0.5-m tall.[5]
Cylindrical, tapering rependant, with secondary and tertiary branches, varying in length up to 2-cm thick, surface more or less rough or longitudinally wrinkled; grayish-brown to brown, cut surface of pieces pale yellow, fracture hard, woody, bark-fibrous; odor, distinct; taste, slightly astringent.
Cylindrical, up to 2.5 cm in diameter; sparsely prickly, covered with long, weak bristles longitudinally grooved, external surface light brown, internal surface grey, bark fibrous; easily separable from wood.
Digitately compound with one or two pairs of sessile, hairy pinnae, alternate, petiolate, stipulate, linear lanceolate; leaflets 10–20 pairs, 0.6–1.2-cm long, 0.3–0.4-cm broad, sessile, obliquely narrow or linear oblong; obliquely rounded at base, acute, nearly glabrous; yellowish green.
Pink, in globose head, peduncles prickly; calyx very small; corolla pink, lobes 4, ovate oblong; stamens 4, much exerted; ovary sessile; ovules numerous.
Lomentum, simple, dry, 1–1.6-cm long, 0.4–0.5-cm broad, with indehisced segments and persistent sutures having —two to five seeds with yellowish spreading bristle at sutures, 0.3-cm long, glabrous, and straw colored.
Compressed, oval-elliptic, brown to gray, 0–0.3-cm long, 2.5-mm broad, having a central ring on each surface.
Mature root shows cork 5–12 layered, tangentially elongated cells, a few outer layer crushed or exfoliated; secondary cortex consisting of 6–10 layered, tangentially elongated thin-walled cells; secondary phloem composed of sieve elements, fibers, crystal fibers, and phloem parenchyma traversed by phloem rays, phloem fibers, single or in groups, arranged in tangential bands; crystal fibers thick walled, 3–25 chambered, each with single or two to four prismatic crystals of calcium oxalate; phloem rays uni-to-multi-seriate, —two to three seriate more common; secondary xylem consists of usual elements traversed by xylem rays; vessels scattered throughout secondary xylem having bordered pits and reticulate thickenings; crystal fibers containing one or rarely two to four prismatic crystals of calcium-oxalate in each chambers; parenchyma, thick walled, scattered throughout secondary xylem; xylem rays uni-to-bi-seriate; rarely multi-seriate, wider toward secondary phloem and narrow toward center; starch grains, prismatic crystals of calcium oxalate and tannin present in secondary cortex, phloem and xylem rays, and parenchyma; starch grains both simple and compound having two to three components, rounded to oval measuring 6–20 mm and 16–28 mm in diameter, respectively.
Mature stem shows four to eight layered, exfoliated cork of tangentially elongated cell filled with reddish brown contents; secondary cortex wide, consisting of large, moderately thick walled, tangentially elongated to oval, parenchymatous cells, filled with reddish brown contents, a few cells contain prismatic crystals of calcium oxalate, a number of lignified, fibers single or in groups, scattered throughout; secondary phloem consisting of usual elements, two to five transversely arranged strips of fibers occur alternating with narrow strips of sieve elements and parenchyma, crystal fibers elongated, thick-walled, containing single crystal of calcium oxalate in each chamber; phloem rays thick walled radially elongated; secondary xylem composed of usual elements traversed by xylem rays, vessels, drum shaped with spiral thickenings, tracheids pitted with pointed ends, fibers of two types, shorter wide lumen and longer with narrow lumen; xylem rays radially elongated, thick walled, 1–6 cells wide and 3-30 cells high; pith consisting of polygonal, parenchymatous cells with intracellular spaces.
Petiole shows single layered epidermis, covered with thin cuticle; cortex four to seven layered of thin walled, parenchymatous cells; pericycle arranged in a ring; four central vascular bundles present with two smaller vascular bundles arranged laterally, one in each wing.
Shows a single-layered epidermis, covered with thin cuticle, upper epidermis followed by a single-layered palisade, spongy parenchyma single-layered, pericycle same as in petiole; vascular bundle single.
Shows epidermis on both surfaces, palisade single-layered; spongy parenchyma, three to five layers consisting of circular cells; rosette crystals and few veins present in spongy parenchyma.
Shows single-layered epidermis with few nonglandular, branched, shaggy hair; mesocarp five to six layers of thin walled, parenchymatous cells; some amphicribral vascular bundles found scattered in this region; endocarp of thick-walled lignified cells followed by single-layered thin-walled, parenchymatous cells.
Shows single-layered radially elongated cells; followed by five- to six-layered angular cells filled with dark brown contents; endosperm consists of angular or elongated cells, a few containing prismatic crystals of calcium oxalate; cotyledons consist of thin-walled cells, a few cells containing rosette crystals of calcium oxalate; embryo straight with short and thick radical.
Reddish brown, shows reticulate, pitted vessels, prismatic and rosette crystals of calcium oxalate, fibers, crystal fibers, yellow or brown parenchymatous cells, palisade cells, nonglandular, branched, shaggy hair, single and compound starch grains, measuring 6–25 mm in diameter with two to three components [ Figure 2 ].[6]
(a) Stomata on M. pudica leaf. (b) Water transport system in M. pudica (800 × 800)
Plant leaf movements can be mediated by specialized motor organs, the pulvini or can be epinastic (i.e. based on different growth velocities of the adaxial and abaxial halves of the leaf).
Both processes are associated with diurnally regulated increase in the rates of membrane water transport, which in many cases, has been shown to be facilitated by aquaporins. Rhythmic leaf movements are known from many plant species but more recently a promising model plant to study pulvinus-mediated leaf movements is M. pudica. The contribution of both plasma membrane and tonoplast localized aquaporins to the seismonastic leaf movements in M. pudica has been analyzed.[7] The bending movement of the pulvinus of M. pudica is caused by a rapid change in volume of the abaxial motor cell, in response to various environmental stimuli. The bending of the pulvinus is retarded by treatments with actin-affecting reagents and calcium channel inhibitors. The actin filaments in the motor cells are fragmented in response to electrical stimulation. Hence the study demonstrated that depolymerization of the actin cytoskeleton in pulvinus motor cells in response to electrical signals results in increased levels of calcium.[8]
The seismonastic movement of M. pudica is triggered by a sudden loss of turgor pressure. On comparing the cell cytoskeleton by immunofluorescence analysis before and after movement and evaluation of the effects of actin and microtubule targeted drugs by injecting them into the cut pulvinus, it is seen that fragmentation of actin filaments and microtubule occurs during bending, although the actin cytoskeleton and not the microtubules are involved in the regulation of the movement.
TEM reveals that actin cables become loose after bending. On injecting phosphatase inhibitors into several pulvinus to examine the effects of such inhibitors, it is seen that changes in actin isoforms, fragmentation of actin filaments and the bending movements are all inhibited after injecting a tyrosine phosphatase inhibitor.[9] Special red cells are found on the adaxial surface of the tertiary pulvini of M. pudica. Using anatomical (light, scanning and transmission electron microscopy) and electrophysiological techniques it has been demonstrated that these red cells are the real mechanoreceptor cells. They can generate receptor potential following mechanical stimuli and they are in connection with excitable motor cells (through plasmodesmata). These red cells are derived from stomatal subsidiary cells and not the guard cells [ Figure 3 ].[10]
Mimosa pudica leaves (a) open and (b) closed
Bacteria isolated from Mimosa nodules in Taiwan, Papua New Guinea, Mexico, and Puerto Rico were identified as belonging to either the alpha- or beta-proteobacteria. The beta-proteobacteria Burkholderia and Cupriavidus strains formed effective symbiosis with the common invasive species Mimosa diplotricha, M. pigra, and M. pudica, but the alpha-proteobacterial Rhizobium etli and R. tropici strains produced a range of symbiotic phenotypes from no nodulation through ineffective to effective nodulation, depending on Mimosa species.
The largest significant effect was for M. pudica, in which LMG19424 formed 57% of the nodules in the presence of 0.5 mM potassium nitrate. In the host, ammonium also had a similar, but lesser, effect. Comparable results were also found using an N-containing soil mixture, and environmental N levels are therefore suggested as a factor in the competitive success of the bacterial symbionts in vivo.[11] The ability of Burkholderia phymatum STM815 to effectively nodulate Mimosa species, and to fix nitrogen ex planta, was compared with that of the known Mimosa symbionts Cupriavidus taiwanensis LMG19424. Both strains were equally effective symbionts of M. pudica, but nodules formed by STM 815 had greater nitrogenase activity. STM 815 was shown to have a broader host range across the genus Mimosa than LMG 19424 nodulating 30 out of 31 species, 21 of these effectively. LMG 19424 effectively nodulated only nine species.[12]
Several studies have shown several biochemical substances involved in the contractility of the leaves.[13] Fresh tissues give nor-epinephrine, d-pinitol (3-mono-methyl ether of inositol), and b-sitosterol. Leaves contain alkaloids.[4] An alkaloid mimosine has been isolated from the plant.[13] The preliminary phytochemical screening of the M. pudica leaf extract showed the presence of bioactive components such as terpenoids, flavonoids, glycosides, alkaloids, quinines, phenols, tannins, saponins, and coumarins [ Table 1 ].[14,23]
Phytochemical screening of Mimosa pudica leaf extracts
Roots of the plant are indicative of the presence flavonoids, phytosterol, alkaloids, amino acids, tannins, glycoside, and fatty acids. Chromatographic procedures revealed that petroleum ether fraction majorly contains flavonoids, phytosterol, alkaloids, and amino acids. Acetone fraction has confirmed the presence of flavonoids. The chloroform fraction showed the presence of alkaloids. The essential oils and fatty acids were majorly contained in the benzene extract [ Table 2 ].[38]
Detection of constituents in roots of M. pudica by chromatographic scheme
The yield of the plant material in various solvents obtained by successive extraction was found out [ Table 3 ].
Successive solvent extraction of Mimosa pudica Linn. leaves
Crocetin dimethyl ester and tannin have been isolated from the plant. The mucilage from seed is composed of D -xylose and D -glucoronic acid 4-O-(3,5-dihydroxybenzoic acid)-b- D -glucoronide.[15] The constituents were separated and purified by column chromatography with macroporous adsorption resin Diaion HP-20, Sephadex LH-20, Tyopearl HW-40, MCI Gel CHP-20, RP-18, and normal phase silica gel. Their structures were identified on the basis of physical and spectral data. Four compounds were isolated and identified as:
7,8,3’,4’-tetrahydroxyl-6-C-[alpha-l-rhamnopyranosyl-(1→2)]-b- D -glucopyranosyl flavone (I); 5,7,4’-trihydroxyl-8-C-[a-l-rhamnopyranosyl-(1→2) ]-b- D -glucopyranosyl flavones (II); 5,7,3’,4’-tetrahydroxyl-6-C-[a-l-rhamnopyranosyl-(1→2) ]- b- D -glucopyranosyl flavone (III); catcher (IV).
Compound I is a new compound and compounds II–IV were isolated from this plant for the first time.[16] Cellular and chloroplast lipids of leaves of M. pudica have been analyzed. Qualitatively the total lipid composition of this plant is similar to that reported for the photosynthetic tissues of other plants. Chloroplast lipids show some resemblance to those of algae. The cerebroside fraction of both leaves and chloroplasts contains a polyunsaturated fatty acid (20:4ω3) and a long chain sphingosine base whose Rf value coincides with that from ox brain cerebroside and not that of phytosphingosine from spinach[17] Jasmonic acid was identified from M. pudica L. plants by mass spectrometry, high performance liquid chromatography, and thin layer chromatography. Effects of authentic jasmonic acid on pulvinule movement and transpiration of the pinnae were compared with those of abscisic acid. Jasmonic acid and abscisic acid each at 10 −5 M inhibited both auxin- and light-induced opening of the pulvinules. A closure-inducing activity of jasmonic acid at 10 −4 M was greater than that of abscisic acid at 10 −4 M. Pinnae transpiration was reduced by 10 −5 M abscisic acid but not by 10 −4 M jasmonic acid.[18]
The secretory cells accumulate material that gives a positive test for carbohydrates and a negative test for proteins.[19] Interestingly certain compounds with enzyme inhibitory activity have also been isolated from M. pudica recently [ Figure 4 ].
Structure of chemical constituents
Foreign matter – not more than 2%
Total ash – not more than 10%
Acid-insoluble ash – not more than 5%
Alcohol-soluble extractive – not less than 9%
Water-soluble extractive – not less than 9%.
TLC of alcoholic extracts of drug on Silica Gel G plates using n-butanol:acetic acid:water (4:1:5). Under UV (366 nm) four fluorescent zones appear at Rf 0.35, 0.62, 0.69 (all blue) and 0.81 (bluish pink). On exposure to iodine vapor two spots appear at Rf 0.35 and 0.94 (both yellow). On spraying with the Dragendorff reagent followed by 5% methanolic sulfuric acid reagent one spot appears at Rf 0.35 (orange).[6]
A sensitive, simple, and reliable reversed-phase HPTLC method has been established for quantification of mimosine in M. pudica L. whole plant powder. The plant powder was first extracted with methanol. The residue was then extracted with water and the aqueous extract was used for quantification. Chromatography was performed on silica gel RP-18 F254s plates with ethyl acetate-glacial acetic acid–water, 6 + 1 + 1.7 (v/v), as the mobile phase. Quantification was achieved by densitometric scanning at λmax = 282 nm in the reflectance–absorbance mode. The response to mimosine was a linear function of concentration over the range 30–100 mg/mL in the extract. The amount of mimosine in M. pudica was found to be 20 mg g/−1 whole plant powder. The method was validated for linearity, precision, accuracy, and robustness.[20]
The water distribution in the pulvinus of Mimosa can be visualized by an NMR imaging technique. After stimulation of a Mimosa plant, water in the lower half of the main pulvinus disappeared, the water previously contained in this area seems to be transferred to the upper half of the main pulvinus. Movement of the water in conjunction with Mimosa movement was visualized sequentially by a noninvasive NMR imaging procedure.[21]
Wherever a movement factor is suspected, its aqueous extract is prepared and tests are performed on it as such or after separation into components, making use of the rapid reactivity of M. pudica. In the bioassay in the climate chamber, a pinna of M. pudica is placed in a solution of the supposed active principles and is observed. The movement factors are drawn up and cause each pair of the pinnules to fold up neatly one behind the other. The reaction behavior induced by the chemonastic stimulus of a Mimosa crude extract can be demonstrated as a function of its concentration in a number of tests. Despite individual variation which can always be observed in the bioassay, a clear decrease in the reaction time with declining concentrations can be seen.[22]
The powdered leaf samples as well as leaf extracts were subjected to fluorescence analysis on long and short wavelengths in day light [Tables [Tables4 4 and and5 5 ].[23]
Fluorescence analysis of extracts of Mimosa pudica L. leaves
Fluorescence analysis of drug powder of Mimosa pudica Linn. leaves
The roots of M. pudica were studied for wound healing activity by incorporating the methanolic and the total aqueous extracts in simple ointment base B.P. in concentration of 0.5% (w/w), 1% (w/w), and 2% (w/w). Wound healing activity was studied in three types of model in rats viz. excision, incision, and estimation of biochemical parameters. Treatment of wound with ointment containing 2% (w/w) the methanolic and 2% (w/w) the total aqueous extract exhibited significant (P < 0.001) wound healing activity. The methanolic extract exhibited good wound healing activity probably due to phenols constituents.[24]
An extract administered in a dose of 1.6 mg/100 g parenterally every 4th day up to 120 days in rats having experimental injury of sciatic nerve, exhibited 30–40% higher results in the process of regeneration of sciatic nerve as compared to the hydrocortisone group.[4]
In Mexico, aqueous extracts from dried leaves of M. pudica are employed to alleviate depression. In this study, behavioral actions of aqueous extracts of M. pudica at various concentrations were tested. Rats having received saline (0.9%; 0.30 mL; I.P.), clomipramine, desipramine, or several dosage of aqueous extracts from M. pudica (m1 = 2.0 mg/kg; m2 = 4.0 mg/kg; m3 = 6.0 mg/kg; m4 = 8.0 mg/kg) during a 30-day period were submitted to the forced swimming test and to the test for differential reinforcement of low rates of response at 72 s (DRL-72 s). Any possible anxiolytic action resulting from several doses (m1 = 2.0 mg/kg; m2 = 4.0 mg/kg; m3 = 6.0 mg/kg; m4 = 8.0 mg/kg) of extracts of M. pudica were compared with those caused by diazepam (1.3 mg/kg, I.P.) in the elevated plus-maze test.
Results showed that clomipramine (1.25 mg/kg, I.P.), desipramine (2.14 mg/kg, I.P.), and M. pudica (6.0 mg/kg and 8.0 mg/kg, I.P.) reduced immobility in the forced swimming test and increased the rate of reinforces received in the DRL-72 s test; these data suggest that M. pudica produces antidepressant effects in the rat. Diazepam increased the open-arms exploration time in the elevated plus-maze test, but M. pudica did not show any comparable action at any tested dose. M. pudica therefore produced an anti-depressant like profile similar to two tricyclic anti- depressants.[25]
The decoction of M. pudica leaves given intraperitoneally at a dose of 1000-4000 mg/kg protected mice against pentylenetetrazole and strychnine-induced seizures. M. pudica had no effect against picrotoxin-induced seizures. It also antagonized N-methyl- D -aspartate-induced turning behavior. These properties could explain its use in African traditional medicine.[26]
Ethanolic extracts of M. pudica leaves given by oral route to mice at a dose of 250 mg/kg showed a significant hyperglycemic effect.[27]
Decoction of leaves of M. pudica in doses of 200, 500, 1000, and 2000 mg/kg in rats and dogs exhibited diuretic activity (considering urinary output Na + –K + –Cl - excretion). The activity in rats at 250 mg/kg dose was found to be 82% of standard diuretic (hydrochlorthiazide 2.5 mg/kg) treated group of rats. There was significant reduction (above 50%) of Na + and Cl - excretion without affecting K + excretion. The drug can be combined as a moderate diuretic with any modern synthetic diuretic causing K + loss.
Aqueous extracts of root powder in pilot studies on patients with dysfunction uterine bleeding gave promising results.[4]
Mimosa pudica is one of the folk medicinal plants commonly used as antifertility agent in some places in India. Air-dried roots of M. pudica were extracted using methanol. The dried methanol extract of the root was administered orally to Swiss albino mice for 21 consecutive days. Estrous cycle, reproductive hormones (LH, FSH, prolactin, estradiol, and progesterone) and number of litters produced were studied in both control and extract administered groups by using standard methods. Phytochemical studies of the methanolic root extract were carried out using qualitative and TLC methods. The root extract of M. pudica has antifertility effect as it prolongs the estrous cycle and disturbs the secretion of gonadotropin hormone in albino mice. The decrease in FSH levels in the proestrous and estrous stages in the extract administered group compared with those of control animals indicates the disturbance of estrous cycle and ovulation through suppression of FSH.[28]
M. pudica root powder (150 mg/kg body weight) when administered intragastrically, altered the estrous cycle pattern in female Rattus norvegicus. Nucleated and cornified cells were absent in all rats. The smear was characterized by leucocytes only, as in diestrus, which persisted for 2 weeks. There was a significant reduction in the number of ova in rats with the root powder compared with the control rats, and a significant increase in the number of degenerated ova.[29]
Ethanol extracts (50%) of the whole plant exhibited spasmogenetic activity in isolated guinea pig ileum.[4]
Reactive oxygen species (ROS) are believed to be responsible for pathogenesis of various diseases affecting tissues and the main organ, the liver. Hence, in this study, the extent of lipid peroxidation (LPO) and ROS elimination and its defense mechanisms by the enzymic and nonenzymic antioxidants in liver and serum was investigated. Hepatotoxicity was manifested by significantly decreased (P < 0.05) levels in the activities of the enzymic antioxidants such as superoxide dismutase (SOD), catalase (CAT), glutathione peroxidase, and the non-enzymic antioxidants such as glutathione and vitamin-C in rats with induced hepatic damage by ethanol. Simultaneous administration of the leaf extract M. pudica along with the toxin ethanol in rats showed a considerable protection against the toxin-induced oxidative stress and liver damage as evidence by a significant increase (P < 0.05) in antioxidant activities. The study reveals that the co-administration of the M. pudica aqueous extract significantly lowered the level of lipid peroxidation in alcohol-fed mice.[30]
The aqueous root extract of M. pudica dose dependently inhibited the hyaluronidase and protease activities of Indian snakes (Naja naja, Vipera russelii, and Echis carinatus) venom.
Aqueous and alcoholic extracts of dried roots of M. pudica were tested for their inhibitory activity on lethality, myotoxicity, and toxic enzymes of Naja kaouthia venom. The aqueous extract, particularly the normal water extract, displayed a significant inhibitory effect on the lethality, myotoxicity, and tested enzyme activities of venom compared with alcoholic extracts. The present findings suggest that an aqueous extract of M. pudica root possesses compound(s), which inhibit the activity of cobra venom.[31]
Antimicrobial activity of the successive extracts of M. pudica whole plant in petroleum ether, chloroform, ethyl acetate, methanol, and water was studied against various Gram positive and Gram negative bacterial strains using the zone of inhibition. Both the agar well diffusion method and agar disc diffusion method were used to evaluate the antibacterial efficacy of the said plant extracts. The microorganisms used in the test were: Escherichia coli, Staphylococcus aureus, Staphylococcus albus, Proteus vulgaris, Salmonella typhi, Salmonella paratyphi A, Salmonella paratyphi B, Shigella flexneri, Klebsiella pneumonia, and Pseudomonas aeruginosa. The minimum inhibitory concentration (MIC) of the methanolic extract of said plant was determined by the agar well diffusion method. The reference antibiotics chloramphenicol and ampicillin were also tested against the said microorganisms used in the assay and the results were compared with that of the plant extracts. The results of the study revealed that the M. pudica whole plant extract possesses good antimicrobial activity between the range of 7–18 mm against the pathogens used for screening.[32]
The methanolic extract and aqueous extract of 100, 200, and 500 mg were tested against different fungal pathogens, Aspergillus fumigates for their antifungal activity. It was demonstrated by a well diffusion assay.[14]
Four of the seven tested medicinal plants exhibited antimicrobial activity against Vibrio cholerae. These seven plants are: Ficus capensis, Mitragyna stipulosa, Entada Africana, Piliostigma reticulatum, Terminalia avicennoides, M. pudica, and Lannea acid. M. pudica showed antimicrobial activity. Potential of these herbs in the control of cholera needs to be determined.[33]
This study was aimed to investigate the effect of the ethanolic extract of roots of M. pudica Linn. (Mimosae) on libido of sexually normal Swiss albino male mice. The suspension of the extract was administered orally at the dose of 100, 250, and 500 mg/kg, to different groups of male mice (n = 6) once a day for 7 days. The female albino mice involved in mating were made receptive by hormonal treatment. The general libido and potency were determined and compared with the standard reference drug sildenafil citrate. A change in hormonal parameter like testosterone was evaluated. Oral administration of the extract significantly increased the libido and hormonal levels of testosterone. The most appreciable effect of the extract was observed at the dose of 500 mg/kg. The results indicated that the ethanolic extract of roots of M. pudica Linn. (Mimosae) produced a significant and sustained increase in the aphrodisiac activity of normal male mice, without any adverse effects.[34]
Charak and Sushruta prescribed a decoction, with Samangaa as an important ingredient in hemothermia, piles, diarrhea, and persistent dysentery. Included in an ointment, the herb was applied over piles, ulcers, and wounds.
During 16th century, Lajjalu was a popular herb for treating piles and diseases of female genital tract. Samangaadi churna is available over the counter, prescribed internally in bleeding piles.[4]
Raktapita, atisara, yoniroga, sopha, daha, svasa, vrana, and kustha.[6] The plant is sheetala (Sheetaveerya), tikta, kashaya; subdues deranged kapha and pitta beneficial in hemorrhagic diseases, diarrhea, and gynecological disorders.[15]
The leaves together with leaves from other medicinal plants are used in treating hemorrhoids and urinary infections.[5] The juice is used in sinus, sores, piles, and fistula, paste is applied to glandular swellings, and hydrocele.
Decoction is efficacious in gravel and other urinary complaints.[15] Treats dysentery, fever, syphilis, leprosy, stomach worms, veneral diseases, insect bite, insomnia, nervousness, and piles.[5]
As Chhuimui, leaves used for increasing the sexual potency in men in Kurukshetra District (Haryana), India.
As Laajvanti; its leaves and roots are used for gravel and other kidney diseases, also for piles and fistula in the Sagar District, Madhya Pradesh, India. The roots are also used in an oral snakebite remedy.
As Lazaoni, root decoction is gargled for gum trouble and toothache by Rahba in West Bengal.As Punyo-sisa; leaves are used in pillows to induce sleep in children and the elderly in Ecuador.[35]
In Orissa (Kandhamal district) as Lajakulilata: The warmed root paste is plastered with the help of a cloth on boils to get relief. The paste of root fried in castor oil is applied on deep cut wounds to stop bleeding and for healing. The warmed leaf paste is applied around furuncle, abscess, and boils to burst and release of pus. The leaf paste is applied on the burst boils and itches for quick healing. The paste of root fried in ghee is applied on caries teeth for relief from toothache. The leaf paste is applied on forehead to get relief from headache and migraine. The leaf paste with honey is prescribed twice a day in empty stomach for 3–4 days for stomach ache and intestinal worms.[36]
This study was conducted to investigate the sustained release properties of M. pudica seed mucilage. Matrix tablets of diclofenac sodium containing different proportions of mucilage and dibasic calcium phosphate as diluent were formulated by the wet granulation method. The tablets had uniform physical appearance, average weight, drug content, and adequate hardness. The results of in vitro release conducted using an USP type II dissolution rate apparatus, in a dissolution media comprising of 900 mL of 0.1 N HCl for 2 h followed by phosphate buffer (pH 6.8) for 24 h at 37 °C and 50 rpm, revealed that as proportion of mucilage in the matrix was increased there was corresponding decrease in the release of drug.
Further, the matrix tablets were found to release the drug following Higuchi square root kinetics, with the mechanism of release being diffusion for tablets containing higher proportion of mucilage and a combination of matrix erosion and diffusion for tablets containing smaller proportion of mucilage. The swelling and erosion studies revealed that, as the proportion of mucilage in tablets was increased, there was a corresponding increase in percent swelling and a decrease in percent erosion of tablets. The SEM photomicrographs showed gelling structures in tablets containing higher percentage of mucilage, while both pores and gelling structures were present on the surface of tablets containing smaller proportion of mucilage and commercial formulation. On comparative evaluation, the dissolution profile from formulation containing mucilage to drug in the proportion of 1:40 was found to be similar to the commercial sustained release formulation of diclofenac.[37]
The brine shrimp lethality assay (BSL) has been used routinely in the primary screening of the crude extracts as well as the isolated compounds to assess the toxicity toward brine shrimps, which could also provide an indication of possible cytotoxic properties of the test materials. It has been established that the cytotoxic compounds usually show good activity in the BSL assay, and this assay can be recommended as a guide for the detection of antitumor and pesticidal compounds because of its simplicity and cost effectiveness. The extracts of M. pudica did not show any significant toxicity toward brine shrimps in the BSL assay. Owing to a high degree of lipophilicity, the n-hexane extract could not be tested. Whereas the LD50 value of the DCM and MeOH extracts of M. pudica was 1.0 mg/mL. The LD50 value of the positive control, podophyllotoxin, was 2.8 × 10 -3 mg/mL.[1]
Samangaadi Churna, Kutajavaleha, Pusyanug Churna, Bhret Gangadhara Churna.
10–20 g of drug for decoction.[6]
The plant prominently features in the texts of ‘Ayurveda′, i.e. the traditional Indian system of medicine, which prompted the authors to compile the published data and to critically analyze it, and is an honest, though rather the preliminary attempt for the preparation of the plant monograph. The review presented a brief profile of M. pudica, a plant associated with fond memories of almost every Indian childhood (chhui-mui). The literature claims that there is vast potential in this herb in view of therapeutics and furthermore, commercialization of this herb would be in line with the WHO guidelines (developing country needs to give more emphasis on exploration of their natural resources like medicinal plants) is highly desirable for the benefits of humanity. It is suggestive of greater benefits as it is economically viable, easily available and a reservoir of significant medicinal properties.[39]
Source of Support: Nil
Conflict of Interest: None declared.
1. Genest S, Kerr C, Shah A, Rahman MM, Saif-E-Naser GM, Nigam P, et al. Comparative bioactivity of two Mimosa species. Lat Am Caribb Bull Med Aromat Plants. 2008; 7 :38–43. [Google Scholar]
2. Ueda M, Yamamura S. The chemistry of leaf movement in Mimosa pudica L. Tetrahedron. 1999; 55 :10937–48. [Google Scholar]
3. Applewhite PB. Behavioral plasticity in the sensitive plant, Mimosa. Behav Biol. 1972; 7 :47–53. [PubMed] [Google Scholar]
4. Khare CP. Encyclopedia of Indian Medicinal Plants. Germany: Springer; 2004. pp. 313–4. [Google Scholar]
5. Prajapati ND, Purohit SS, Sharma AK, Kumar T. A complete Source Book. Jodhpur: Agrobios India; 2003. A Handbook Of Medicinal Plants; p. 271. [Google Scholar]
6. Dept. Of Indian Systems of Medicines and Homeopathy. 1st ed. Part 1. Vol. 2. New Delhi: Govt. Of India. Ministry of Health and Family Welfare; The Ayurvedic Pharmacopoeia of India; pp. 98–101. [Google Scholar]
7. Uehlein N, Kaldenhoff R. Aquaporins and plant leaf movements. Ann Bot (Lond) 2008; 101 :1–4. [PMC free article] [PubMed] [Google Scholar]
8. Yao H, Xu Q, Yuan M. Actin dynamics mediates the changes of calcium level during the pulvinus movement of Mimosa pudica. Plant Signal Behav. 2008; 3 :954–60. [PMC free article] [PubMed] [Google Scholar]
9. Kanzawa N, Hoshino Y, Chiba M, Hoshino D, Kobayashi H, Kamasawa N, et al. Change in the actin cytoskeleton during seismonastic movement of Mimosa pudica. Plant Cell Physiol. 2006; 47 :531–9. [PubMed] [Google Scholar]
10. Visnovitz V, Vilagi I, Varro P, Kristof Z. Mechanoreceptor cells on the tertiary pulvini of Mimosa pudica L. Plant Signal Behav. 2007; 2 :462–6. [PMC free article] [PubMed] [Google Scholar]
11. Elliot GN, Chou JH, Chen WM, Bloemberg GV, Bontemps C, Maartinez RE, et al. Burkholderia spp. are the most competitive symbionts of Mimosa, particularly under N-limited conditions. Environ Microbiol. 2009; 11 :762–78. [PubMed] [Google Scholar]
12. Elliot GN, Chen WM, Chou JH, Wang HC, Sheu SY, Perin L, et al. Burkholderia phymatum is a highly effective nitrogen fixing symbiont of Mimosa spp. and fixes nitrogen explanta. New Phytol. 2007; 173 :168–80. [PubMed] [Google Scholar]
13. Jha NK. Mimosa pudica: Lajjalu. Phytopharm. 2007; 8 :3–8. [Google Scholar]14. Gandhiraja N, Sriram S, Meena V, Srilakshmi K, Sasikumar C, Rajeshwari R. Phytochemical Screening And Antimicrobial Activity of the Plant Extracts of Mimosa pudica L. Against Selected Microbes. Ethnobotanical Leaflets. 2009; 13 :618–24. [Google Scholar]
15. Chatterjee A, Pakrashi SC. The Treatise on Indian Medicinal Plants. New Delhi: National Institute of Science Commission and Information Resources; 2006. pp. 65–6. [Google Scholar]
16. Yuan K, Lu JL, Yin MW. Chemical constituents of C-glycosylflavones from Mimosa pudica. Yao Xue Xue bao. 2006; 41 :435–8. [PubMed] [Google Scholar]
17. Choudhary MD, Chakrabarti P. Cellular and chloroplast lipid composition of the leaves of Mimosa pudica. Phytochemistry. 1980; 19 :519–23. [Google Scholar]
18. Tsurumi S, Asahi Y. Identification of jasmonic acid in Mimosa pudica and its inhibitory effect on auxin- and light-induced opening of the pulvinules. Physiologia Plantarum. 2006; 64 :207–11. [Google Scholar]
19. Katherine E. On the phloem of Mimosa pudica L. Ann Bot. 1970; 34 :505–14. [Google Scholar]20. Nair LS, Menon SN, Shailajan S, Baing MM, Sane RT. Reversed-phase-high-performance-thin-layer-chroamtographic-quantification of mimosine from whole plant of Mimosa pudica Linn. J Planar Chromatogr. 2007; 20 :49–51. [Google Scholar]
21. Tamiya T, Miyazaki T, Ishikawa H, Iriguchi N, Maki T, Matsumoto JJ, et al. Movement of Water in Conjunction with Plant Movement Visualized by NMR Imaging. J Biochem. 1988; 104 :5–8. [PubMed] [Google Scholar]
22. Schildknecht H, Schumacher K. Nyctinastinenes-An Approach to New Phytohormones. Pure Appl Chem. 1982; 54 :2501–14. [Google Scholar]
23. Rajendran R, Sundararajan R. Preliminary Phytochemical Analysis and Anti-Bacterial Activity of Mimosa pudica Linn. Leaves. Int J Pharm Bio Sci. 2010; 6 :1–8. [Google Scholar]
24. Kokane DD, More RY, Kale MB, Nehete MN, Mehendale PC, Gadgoli CH. Evaluation of wound healing activity of root of Mimosa pudica. J Ethnopharmacol. 2009; 124 :311–5. [PubMed] [Google Scholar]
25. Molina M, Contreras CM, Tellez AP. Mimosa pudica may possess antidepressant actions in the rat. Phytomedicine. 1999; 6 :319–23. [PubMed] [Google Scholar]
26. Bum EN, Dawack DL, Schmutz M, Rakotonirina A, Rakotonirina SV, Portet C, et al. Anticonvulsant activity of Mimosa pudica decoction. Fitoterapia. 2004; 75 :309–14. [PubMed] [Google Scholar]
27. Amalraj T, Ignacimuthu S. Hyperglycemic effect of leaves of Mimosa pudica Linn. Fitoterapia. 2002; 73 :351–2. [PubMed] [Google Scholar]
28. Ganguly M, Devi N, Mahanta R, Borthakur MK. Effect of Mimosa pudica root extract on vaginal estrous and serum hormones for screening of antifertility activity in albino mice. Contraception. 2007; 76 :482–5. [PubMed] [Google Scholar]
29. Valsala S, Karpagaganapathy PR. Effect of Mimosa pudica root powder on oestrous cycle and ovulation in cycling female albino rat, Rattus norvegicus. Phytother Res. 2002; 16 :190–2. [PubMed] [Google Scholar]
30. Nazeema TH, Brindha V. Antihepatotoxic and antioxidant defense potential of Mimosa pudica. Int J Drug Disc. 2009; 1 :1–4. [Google Scholar]
31. Mahanta M, Mukherjee AK. Neutralization of lethality, myotoxicity and toxic enzymes of Naja kaouthia venom by Mimosa pudica root extracts. J Ethnopharmacol. 2001; 75 :55–60. [PubMed] [Google Scholar]
32. Pawaskar SM, Kale KU. Antibacterial activity of successive extracts of Mimosa pudica. Indian Drugs. 2006; 43 :476–80. [Google Scholar]
33. Akinsinde KA, Olukoya DK. Vibriocidal activities of some local herbs. J Diarrhoeal Dis Res. 1995; 13 :127–9. [PubMed] [Google Scholar]
34. Pande M, Pathak A. Aphrodisiac Activity of Roots of Mimosa pudica Linn. Ethanolic Extract in Mice. Int J Pharm Sci Nanotechnol. 2009; 2 :477–86. [Google Scholar]
35. The Vaults of Erowid. Erowid Online Books: Ayahuasca: Alkaloids, plants and analogs. c1995-2010. [Last updated on 2009 Apr 21; cited 2010 May 26]. Available from: http://www.erowid.org/
36. Behera SK, Panda A, Behera SK, Misra MK. Medicinal Plants Used By the Kandhas of Kandhamal District of Orissa. Indian J Traditi Knowl. 2006; 5 :519–28. [Google Scholar]
37. Singh K, Kumar A, Langyan N, Ahuja M. Evaluation of Mimosa pudica Seed Mucilage as Sustained Release Excipient. AAPS Pharm Sci Tech. 2009; 10 :1121–7. [PMC free article] [PubMed] [Google Scholar]
38. Pande M, Pathak A. Preliminary pharmacognostic evaluations and phytochemical Studies on roots of Mimosa pudica (Laajvanti) Int J Pharm Sci Rev Res. 2010; 1 :50–2. [Google Scholar]
39. Muthumani P, Meera R, Devi P, Koduri LV, Manavarthi S, Badmanaban R. Phytochemical investigation and enzyme inhibitory activity of Mimosa pudica Linn. J Chem Pharm Res. 2010; 2 :108–14. [Google Scholar]
Articles from Pharmacognosy Reviews are provided here courtesy of Wolters Kluwer -- Medknow Publications
