|Year : 2020 | Volume
| Issue : 1 | Page : 1-16
“Haripriya” god's favorite: Anthocephalus cadamba (Roxb.) Miq. - At a glance
Sumanta Mondal1, Kausik Bhar2, Ashes Sinha Mahapatra1, Joy Mukherjee1, Prasenjit Mondal3, Syed Tazib Rahaman1, Aishwarya P Nair1
1 Department of Pharmaceutical Chemistry, Institute of Pharmacy, GITAM (Deemed to be University), Visakhapatnam, Andhra Pradesh, India
2 Department of Pharmaceutical Chemistry, Bengal School of Technology, Hooghly, West Bengal, India
3 Department of Pharmaceutical Chemistry and Analysis, Vaageswari College of Pharmacy, Karimnagar, Telangana, India
|Date of Web Publication||3-Feb-2020|
Dr. Sumanta Mondal
Institute of Pharmacy, GITAM (Deemed to be University), Visakhapatnam - 530 045, Andhra Pradesh
Source of Support: None, Conflict of Interest: None
| Abstract|| |
The Kadam tree is highly regarded as religiously and culturally in India being sacred to Lord Krishna, and hence, the tree is also known as Haripriya, God's favorite. This article provides a detailed review of Anthocephalus cadamba (Roxb) Miq. (family – Rubiaceae) that covers taxonomical classification, vernacular names, geographical distribution, botanical description, ethnobotanical information, pharmacological studies, and phytochemistry. Several parts of this plant have a number of traditional applications for treating humanity, which includes mouth ulcer, subdermal inflammatory deposits, stomatitis, fever, gastric disturbance, astringent, febrifuge, antiseptic, diuretics, anemia, uterine complaints, increase breast milk in lactating women, improvement of semen quality in men, nanotechnology, and agroforestry. The plant parts produce various pharmacological activities such as antidiabetic, antioxidant, antitumor, nephrotoxicity, diuretic and laxative, antihepatotoxic, hypolipidemic, analgesic, antipyretic, anti-inflammatory, antifilarial antimalarial, sedative, antiepileptic, urolithiatic, immunomodulatory, antivenom, gastroprotective, anthelminthic, wound healing, antimicrobial, geranyl acetate esterase inhibition along with toxicological studies, nanotechnology, and agroforestry, which are newly added applications. Many phytoconstituents were isolated using various solvents and obtained compounds, such as cadambine, 3α-dihydrocadambine, isodihydrocadambine, β-sitosterol, amygdalin, phelasin, ursolic acid, linalool, and geraniol that belong to alkaloids, coumarins, terpenoids, diterpenoids, triterpenes glycosides, sterols, flavonoids, amides, and fatty acids. Various solvent extracts and their gas chromatography–mass spectrometry studies have confirmed structures of some important phytoconstituents. Hence, this review can be a good reference for researchers who are willing to continue further research about A. cadamba.
Keywords: Anthocephalus cadamba, ethnobotanical information, Haripriya, pharmacological activities, phytoconstituents
|How to cite this article:|
Mondal S, Bhar K, Mahapatra AS, Mukherjee J, Mondal P, Rahaman ST, Nair AP. “Haripriya” god's favorite: Anthocephalus cadamba (Roxb.) Miq. - At a glance. Phcog Res 2020;12:1-16
|How to cite this URL:|
Mondal S, Bhar K, Mahapatra AS, Mukherjee J, Mondal P, Rahaman ST, Nair AP. “Haripriya” god's favorite: Anthocephalus cadamba (Roxb.) Miq. - At a glance. Phcog Res [serial online] 2020 [cited 2020 Sep 27];12:1-16. Available from: http://www.phcogres.com/text.asp?2020/12/1/1/277472
- Anthocephalus cadamba (Roxb) Miq. (Family ― Rubiaceae) is commonly known as Haripriya or God's favorite due to love flute of Lord Krishna and Radha under this tree shades. This article contains detailed information about taxonomical classification, vernacular names, geographical distribution, botanical description, ethnobotanical information, pharmacological studies, and phytochemistry. It posses several pharmacological activities that includes antidiabetic, antioxidant, antitumor, nephrotoxicity, diuretic and laxative, antihepatotoxic, hypolipidemic, analgesic, antipyretic, anti-inflammatory, antifilarial antimalarial, sedative, antiepileptic, urolithiatic, immunomodulatory, antivenom, gastroprotective, anthelminthic, wound healing, antimicrobial, geranyl acetate esterase inhibition along with toxicological studies, nanotechnology, and agroforestry and many phytoconstituents were isolated from this plant that belongs to alkaloids, coumarins, terpenoids, diterpenoids, triterpenes glycosides, sterols, flavonoids, amides, and fatty acids. Gas Chromatography-Mass Spectrometry analysis confirmed structures of a number of phytoconstituents.
Abbreviations Used: A. cadamba: Anthocephalus cadamba, A. niger: Aspergillus niger, ABTS: 2,2'-azino-bis (3-ethylbenzothiazoline-6-sulfonic acid), ACALK: Alkaloid-rich fraction, B. subtilis: Bacillus subtilis, C. albicans: Candida albicans, CCl4: Carbon tetrachloride, CGA: Chlorogenic acid, cm: Centimeter, COX-2: Cyclooxygenase-2, DNA: Deoxyribonucleic acid, DPPH: 1,1-diphenyl-2-picrylhydrazyl, E. coli: Escherichia More Details coli, EAC: Ehrlich ascites carcinoma, g/ml: Gram/milliliter, GAE: Geranyl acetate esterase, GI50: Growth inhibition 50%, IASM: Indian Ayurvedic System of Medicine, IC50: Half maximal inhibitory concentration, IL-2: Interleukin-2, INH: Isoniazid-induced seizures, LC50: Lethal concentration 50, m: Meter, MBC: Minimum bactericidal concentration, MES: Maximal electroshock-induced seizures, mg/kg: Milligram/kilogram, MIC: Minimum inhibitory concentration, ml: Milliliter, P. aeruginosa: Pseudomonas aeruginosa, PTZ: Pentylenetetrazole-induced seizures, RBC: Red Blood Corpuscle, S. aureus: Staphylococcus aureus, S. typhi: Salmonella More Details typhi, SOD: Superoxide dismutase, μg/ml: Microgram/milliliter, μm: Micrometer.
| Introduction|| |
Since the beginning of human civilization, medicinal plants have been used by humanity for its therapeutic value. The connection between human and his/her search for drugs in nature dates from the far past, of which there is ample evidence from various sources: written documents, preserved monuments, and even original plant medicines. The knowledge of the development of ideas related to the usage of medicinal plants as well as the evolution of awareness has increased the ability of pharmacists and physicians to respond to the challenges that have emerged with the spreading of professional services in the facilitation of human's life.
The Kadam tree is highly regarded as religiously and culturally in India being sacred to Lord Krishna. Radha and Krishna conducted their love-play in the hospitable and sweet-scented shade of the Kadamba tree. In Hindu mythology, the Kadam tree is the favorite tree of Lord Krishna, who is usually depicted playing his flute under it. He also used to play with his friends under the Kadam tree in Vrindavan using the unique globular flower of the tree. Hence, the tree is also known as Haripriya, God's favorite. The word Kadamba lends its name to the Kadamba Dynasty which ruled from Banavasi in what is now the state of Karnataka from 345 AD to 525 AD. The Kadamba tree was considered a holy tree by the Kadamba dynasty. Kadambotsava (“The festival of Kadamba”) is also the festival that is celebrated every year by the Government of Karnataka in honor of the Kadamba kingdom.
India has a wide variety of medicinal plants popularly known as the Indian Ayurvedic System of Medicine. Anthocephalus cadamba (Roxb) Miq. (Family Rubiaceae) is commonly known as “Kadamba” in Ayurveda. It is said to be one of the most valuable medicinal evergreen tropical trees because of its greatest medicinal value in Ayurveda – an Indian native system of medicine. Kadamba is a plant drug that is widely used in many instances in the classical Ayurvedic texts for various ailments.,,
Charaka mentioned Kadamba to be used as vegetable and fruit. Sushruta has described it in the first group of sour fruits. Sushruta has mentioned Kadamba and Nipa as two different plants. However, in most instances, Kadamba and Nipa are used as synonyms. It is widely distributed in India, Bangladesh, Nepal, Sri Lanka, Myanmar, Philippines, Indonesia, and Papua New Guinea. The trees found in the greater part of India in moist locations in West Bengal, Bihar, Odisha, Andhra Pradesh, Karnataka, Kerala, and peninsular India. It is also found in the sub-Himalayan tract from Nepal eastward on the lower hills of Darjeeling terai in West Bengal; it is very common tree found in damp places along with large streams in Chota Nagpur (Bihar), Odisha and Andhra Pradesh, in the Andaman, on the west coast of Karnataka and Kerala also found at low-level wet places of Western Ghats. It is also distributed in Thailand and Indo-China and eastward in Malaysian archipelago to Papua New Guinea., The tree is said to have a medium-to-large-sized deciduous tree attaining a height of 20–40 m and a girth of about 2–2.5 m along with clean cylindrical branches and rounded crown. It is habitually found on the slopes of evergreen forests which are spread all over India which are up to 500 m. The stem of younger trees appears grayish-green with smooth bark. As it gets older, the bark gets rough and gray with longitudinally fissured. Leaves are glossy, dark green, opposite, simple pulvinus base subsessile to petiolate, broadly ovate to elliptic-oblong, entire apex mucronate, and venation pinnate. The flowers that appear from August to October are orange to yellow. Inflorescences are clusters with terminal globose heads, subsessile and fragrant. Fruitlets are numerous with upper parts containing solid structures along with tiny seeds which are trigonal or irregular in shape. The species occurs in wooded grasslands, deciduous woodland and bushland, and riverine and groundwater forests in altitudes between sea level and 1500 m.
A. cadamba has been known for curing a number of diseases; particularly, the extract prepared from the bark and leaves is crucial. The barks and leaves of the plant are reported to have various medicinal uses such as astringent, antihepatotoxic, antidiuretic, wound healing, antiseptic, and anthelmintic. The pharmacognostical study of leaves, roots, and stem bark of the plant is also reported. Various researches across the world have focused their studies on discovering a number of phytochemicals as well as secondary metabolites (saponins, triterpenes, indole, and quinoline alkaloids) with pharmacological significance from the Cadamba.,,
In India, A. cadamba is a well-known plant for its rapid growing in several climatic conditions. Due to its rapid-growing nature, it is highly popular tree as supply of wood in various farmlands and in agro factory. A. cadamba woods are creamy-white and straight grain having medium texture wood that is commonly used in multipurpose fields such as plywood, pencil making, match splints, paper pulpwood, packing cases, toys, wooden shoes, flooring, carving, and crates. The fast decomposition rate of A. cadamba is also made it more compatible with the emerging agroforestry systems in various parts of India and considered to be very useful tree in agroforestry and carbon sequestration.
| Taxonomical Classification|| |
A. cadamba (Roxb) Miq. (family: Rubiaceae) is a miracle tree species with considerable economic potential used as a timber wood and traditional medicine resource in South and Southeast Asia, thereby J. Li et al. (2018), reported the complete chloroplast genome of A. cadamba which are similar to genomes from Rubiaceae family. The detailed taxonomical classification of A. cadamba is given in [Table 1].
| Vernacular Names and Synonyms|| |
A. cadamba is extensively available all over India and is acknowledged by various names at various places. The details of vernacular names and synonyms are listed in [Table 2].,
| Geographical Distribution|| |
A. cadamba are mostly located in deciduous forests and are generally cultivated in plains. They are mostly found in Asia, Australia, and the Pacific region. In India, they are mostly found in Kerala, Maharashtra, Tamil Nadu, Madhya Pradesh, Assam, and Andhra Pradesh. They are also cultivated in India, Pakistan, Sri Lanka, Burma, Thailand, Laos, Vietnam, Cambodia, Indo-Malesia, and many other tropical regions all over the world. Native range of Cadamba is Australia, China, India, Indonesia, Malaysia, Papua New Guinea, Philippines, Singapore, Vietnam, and Maharashtra. In Maharashtra, it is widely distributed over central plains of Marathwada, dry deciduous forests of Vidarbha and Western Maharashtra, and moist deciduous forests of Konkan.,
| Botanical Description|| |
A. cadamba (Rubiaceae) is a fast-growing large tree with a broad umbrella-shaped crown and straight cylindrical bole. It has broad spreading branches and rapidly grows within 5–6 years. The branches are characteristically arranged in tiers. The tree may reach a height of 45 m with a stem diameter of 100–160 cm, and sometimes, it has a small buttress up to 2 m high [Figure 1].,,
The barks are grayish-brown with characteristic taste and order [Figure 2]. The inner bark consists of secondary phloem, whereas the outer bark is rhytidoma with two or three narrow, wavy zones of periderm which occurs one after the other with wide secondary phloem between the sequent periderm zones; simultaneously, the inner bark consists of secondary phloem that can be differentiated into two zones namely broader collapsed phloem and narrow noncollapsed phloem. The ray cells are narrowly oblong and thin-walled. Sieve elements are arranged in radial files in between the rays. The sieve-tube members are wide and polygonal in outline with thin-walled.
The shape of A. cadamba leaves are broadly ovate, glossy green, opposite, simple sessile to petiolate, bitter in taste, mucronate apex, glabrous surface, pinnate venation, length varying from 7.5 to 18 cm, and breadth varying from 4.5 to 16 cm [Figure 3]. Presence of unicellular, lignified trichomes, paracytic stomata, simple starch grains, and sandy balls of calcium oxalate crystals is found in the microscopic study of leaf powder. The reported stomatal number for upper epidermis (41–47) and lower epidermis (42–45), the stomatal index for upper epidermis is 27.2% and lower epidermis is 26.9%, whereas the vein islet number and vein termination number are 11 and 21.
Inflorescence are clusters with terminal globose heads without bracteoles and subsessile fragrant. Flowers are yellow to orange in colour, bisexual with 5-merous along with funnel-shaped calyx, simultaneously, corolla are gamopetalous saucer-shaped with an arrow tube, the narrow lobes imbricate in bud. Five stamens inserted on the corolla tube, filaments are short and anthers are basified. Ovary are inferior, bilocular, sometimes 4-locular present in the upper part along with a spindle-shaped stigma.,
The fruitlets are numerous, somewhat fleshy, with their upper parts containing four hollow or solid structures [Figure 4] and [Figure 5]. The fruit occurs in small, fleshy capsules packed closely together to form a fleshy yellow-orange infructescence containing approximately 8000 seeds [Figure 6]. The seeds somewhat are trigonal or irregular shaped, not winged.
|Figure 5: Anthocephalus cadamba pseudocarp (false-fruit) with dried corolla|
Click here to view
The fresh matured roots are thick but cylindrical, whitish-gray with fissures and surface rough and scars. Taproot branched with true kinds of rootlets. The powdered roots are odorless and tasteless and consists of vessel elements such as fibers, parenchyma, and few cork cells. The fibers are abundant in the powders which are narrow and long with thick lignified secondary walls. Parenchyma cells are also found clearly. In fresh condition, the cut surface of the root is smooth, with white border and yellow middle region. The microscopic characteristics of matured root consist of wide periderm and solid vascular cylinder with cork layer along with cortex amid lenticels. The periderms are scaly flacks with shallow irregular fissured crevices containing phellem, phellogen, and phelloderms. Xylem vessels are found between the medullary rays. Secondary phloem is comparatively massive unlignified, containing sieve tubes, phloem parenchyma, and starch grains.
The detailed general description and pharmacognostical parameters of A. cadamba are depicted in [Table 3] and [Table 4].,,
| Ethnobotanical Information|| |
The plant is known to play an important economical, ecological, as well as medicinal role. According to various Indian Ayurveda practitioners and traditional herbal healers, several parts of A. cadamba are used for the treatment of a number of health hazards. Each and every plant part is used for the preparation of several medicines. There are several benefits of A. cadamba in Ayurvedic system such as inshishira, grahi, guru, vranaropana, vishtambhakrut, shukravardhana, raktapitta, atisara, arochaka, visha, kasa, and daha.
Indian tribal used leaf paste in the treatment of dyspepsia and locally applied for mouth ulcer in children. Lodhas apply bruised leaves on boils for removing of subdermal inflammatory deposits. Leaves are bitter, nutritious, and astringent and are also used for gargling in aphthae or stomatitis. Dried powdered leaves are used as anthelmintic and hot water extract of the leaves is used as astringents, as stomatitis, and for washing wounds in the throat., The fresh juice of the leaf is consumed in a dose of 10–15 ml to treat leucorrhea and increased menstrual flow.
The flowers are used as vegetable and as gurgle to remove the foul smell from mouth. Kadam flowers are an important raw material in the production of “attar,” which are Indian perfumes with sandalwood (Santalum spp.) base in which one of the essences is absorbed through hydro-distillation.
The fruit is cooling and said to destroy the phlegm and impurity of blood when eaten. Lodhas take ripened fruits as carminative/masticate. Fruit juice is given during fever and gastric disturbance. The fresh juice of the fruit is useful to increase breast milk in lactating women.
Similarly, stem barks reported to possess astringent, febrifuge, and antiseptic and acts as diuretics. Juice of the bark given orally against cough and fever and in inflammation of eyes., Dried stem bark is also used as folk medicine (ethno medicines) in the treatment of various skin diseases, anemia, and uterine complaints and for the improvement of semen quality., Lodhas apply stem bark paste on swelling of legs and juice to cure eye inflammation. In Konkan, the fresh juice of the bark is applied to the heads of infant when the fontanels sunken. Mundas prescribe the bark paste duly suspended in water in reducing blood sugar in the patients with diabetes mellitus. The paste prepared from the bark of stem and leaf of A. cadamba is useful to treat pain, redness, and itching due to insect bite.
The tribes of Ganjam district of Odisha drink the root paste duly suspended in water in reducing blood sugar in the patients with diabetes mellitus. The decoction of the root of A. cadamba is useful for the treatment of urinary tract infection and renal calculi.
| Pharmacological Activities|| |
Different doses of ethanolic fraction (250, 500, 750, and 1000 mg/kg body weight [body wt.]) and methanolic extract (200 and 400 mg/kg) of stem bark of A. cadamba were reported for its antidiabetic (hypoglycemic) potential in alloxan-induced diabetic rats and rectifying the problems such as fatigue and irritation associated with this disease. The reported experimental studies helped in proving that 400–500 mg/kg extract of drug was effective in the treatment of diabetes, and it is thought to be due to the presence of flavonoids, which stimulated the insulin secretion. The alcoholic and aqueous extracts of the roots of A. cadamba also possessed the antidiabetic activity in dose 400 mg/kg body wt. and were tested against the normoglycemic and alloxan-induced hyperglycemic rats. Similarly, the aqueous (400 mg/kg) and methanolic extracts (200 and 400 mg/kg body wt.) of the leaves had beneficial effects in reducing the elevated blood glucose level of hyperglycemic mice and rats with lipid-lowering activity. The hydroethanolic extract (100 and 200 mg/kg body wt.) of the flowering tops of A. cadamba was also reported for its potential hypoglycemic effect and antioxidant property in alloxan-induced diabetic rats.
The extract of A. cadamba whole plant (barks, leaves, flowers, and fruits) reportedly possessed potent antioxidant activity by inhibition of lipid peroxidation and by rapid increase in the superoxide dismutase (SOD) and catalase activity., The antioxidant potential of the extracts isolated from A. cadamba which have the capacity to act as therapeutic agents in the treatment of radical-related pathological damage. In another study, extracts, namely, AC-4 and alkaloid-rich fraction was isolated from leaves and barks of A. cadamba using two varied methodologies for isolation to evaluate bothin vitro antioxidant and antiproliferative properties. Simultaneously, both leaf and fruit extracts (methanol and n-hexane) exhibited strong 1,1-diphenyl-2-picrylhydrazyl (DPPH) radical-scavenging and Fe2+ chelating activities; however, superoxide anion scavenging activity of the fruit extract was much higher than leaf extract. Similarly, the hydroethanolic extract of A. cadamba flowering tops displayed remarkable antioxidative potential in the DPPH, the hydrogen peroxide, the nitric oxide scavenging, the reducing power, the total antioxidant capacity, the lipid peroxidation inhibition (thiobarbituric acid-reactive substances production), and the RBC membrane stabilization assays. While in the DPPH assay, the IC50 value of the extract was 146.5 and 24.8 μg/ml for nitric oxide scavenging assay, whereas the extract at a concentration range of 0.50–2.0 mg/ml significantly protected the rat erythrocyte membrane against lysis induced by hypotonic solution. Hot aqueous extract and ethyl acetate fraction of the leaves also exhibit significant and powerful antioxidant activity. Chandel et al. also reported the antioxidant potential of methanol extract from the bark of A. cadamba. Here, antioxidant activity was determined byin vitro assays, viz., DPPH radical scavenging assay, 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS) radical cation decolorization assay, and reducing power assay. The extract also evaluated for DNA protection activity in DNA protection assay using pBR322 plasmid DNA. In addition, the extract also showed good genoprotective potential comparable to gallic acid. Similarly, the methanol extract of leaf–calli and internode–calli of this plant also possesses positive antioxidant activities in total phenolic content and DPPH radical scavenging activity assay. The leaf, twig, and calli extracts also showed the potential to protect the plasmid DNA (pBR322) against the attack of hydroxyl radicals generated by Fenton's reagent.
Recently, various studies have been carried out on A. cadamba to evaluate its antitumor activity. Reported cytotoxicity tests on methanol extract (200 and 400 mg/kg) of A. cadamba leaf performing through Trypan blue method by inoculating it on Ehlrich ascites carcinoma (EAC)-treated mice and the extract showed direct cytotoxicity on EAC cell line in a dose-dependant manner and decrease in the tumor volume, viable cell count, tumor weight and elevated the life span of EAC tumor bearing mice. Kamal et al. reported that the leaves of A. cadamba possess moderate cytotoxic (brine shrimp lethality bioassay) activity of crude methanol extract and lethal concentration 50 (LC50) values of the extract was found 130.617 ± 0.82 μg/ml. Two flavonols, viz., 6-hydroxycoumarin-(4→8)-(-)-epicatechin and 6-hydroxycoumarin-(4→8)-(-)-epicatechin-(4→6)-(-)-epicatechin, were isolated from of A. cadamba leaves, and both the compounds exhibited potent antioxidant and antigenotoxic activity and also showed cytotoxicity in COLO-205 cancer cell line with growth inhibition 50% of 435.71 g/ml. Both the compounds also showed moderate cyclooxygenase-2 inhibitory activity. The cytotoxic potential of chloroform extract from A. cadamba leaves against different human cancer cell lines was also reported by Singh et al. Chloroform extract exerts potent cytotoxic effect against human lung (A-549), ovary (IGR-OV-1), prostate (PC-3), and central nervous system (CNS, SF-295) cancer cell lines IC50 of 8, 57, 49, and 39 μg/ml, respectively. Ethanolic extract was found to be active only against one cell line CNS (SF-295). In 2016, Dolai et al. reported anticancer activity of methanol extract of A. cadamba stem bark. Investigation indicates that the extract (200 and 400 mg/kg) exhibit potential antitumor activity. The tumor-suppressing mechanism involved the induction of apoptosis and/or cell death followed due to DNA damage property of the methanol extract of A. cadamba. Fatima et al. reported antiproliferative and antioxidant activities of methanol extract from A. cadamba bark along with estimation of total phenolic contents. Simultaneously methanol extract of the bark also shown significant antiproliferative activity (IC50=319±4.98 μg/ml) against human cervical cancer cells when compared with standard cisplatin (IC50=5.6±0.52 μg/ml) drug along with high antiradical activity demonstrated by the extract against DPPH and ABTS and the authors also suggested that the antiproliferative activity may be due to induction of apoptosis which is credited to the phenolic contents. Simultaneously, preliminary cytotoxic (Brine shrimp lethality bioassay) effects of ethanol extract and its fractions of A. cadamba bark were reported by Abu et al., and the LC50 values for pet-ether, chloroform fractions, and standard vincristine sulfate were 17.78, 15.66, and 12.02 μg/ml, respectively, and the studies revealed that chloroform fractions of ethanol extracts of stem bark possess moderate cytotoxicity's effect. Two new monoterpene, indole alkaloids (vincosamide-N-oxide and isodihydroaminocadambine), and seven known alkaloids and triterpenoids (such as vincosamide, vallesiachotamine, iso-vallesiachotamine, dihydrocadambine, cadambine, ursolic acid, and oleanolic acid) were isolated from the fruits of A. cadamba, and all the molecules were evaluatedin vitro antiproliferative activity against human lung cancer cell line H1299, cytotoxic profile in mouse macrophage RAW 264.7 cell line, and induction of apoptosis in MCF-7 cells. Compounds vallesiachotamine and iso-vallesiachotamine were found to exhibit potent anticancer activity with IC50 values of 4.24 and 3.79 μM, respectively. Both compounds demonstrated significant fragmentation in the chromatin within the nucleus cells as a result of apoptosis. In addition, none of the compounds showed any toxic effect on normal cells.
Ethanol extract of A. cadamba roots has a potential role in the abatement of cisplatin-induced nephrotoxicity. The nephroprotective potential of the extract (200 and 400 mg/kg) was evaluated in Wistar rats. Extract significantly attenuated nephrotoxicity induced by cisplatin which was confirmed by reducing levels of serum markers, urinary total protein, lipid peroxidation, and increased creatinine clearance. Extract also compensated deficits in the renal antioxidant system. Simultaneously, aqueous extract of A. cadamba fruit possesses antidote and acts effectively against arsenic-induced nephrotoxicity. It was observed that administration of the crude extract (100 mg/kg, p.o.) reduces the toxic effect of arsenic trioxide on the kidney of mice.
Diuretic and laxative activity
The various extracts of the barks of A cadamba were studied for its diuretic and laxative activity, and it was found that the methanol extract (300 mg/kg) of the bark of A cadamba significantly showed enhancement of the urinary output (diuresis) comparatively with the aqueous, chloroform, and petroleum ether extract, whereas the chloroform extract (300 mg/kg) reportedly produced significant laxative property. Prathibhakumari and Prasad also reported the efficacy of aqueous fruit extract (200 and 400 mg/kg, p.o.) of A. cadamba on diuretic property in albino rats via oral route.
In 1995, Kapil et al. reported the hepatoprotective activity of chlorogenic acid (CGA) isolated from A. cadamba. It was also found that the intraperitoneal (i.p) administration of CGA to mice at a dose of 100 mg/kg, i.p., for 8 days, exhibited a better liver protective action than silymarin, in carbon tetrachloride (CCl4)-administered mice. Similarly, the flowers of A. cadamba also reported for its promising hepatoprotective and antioxidant activity of due to inhibition of tissue lipid peroxidation and activation of tissue SOD and catalase. Swarnkar et al. also reported that the ethanolic extract (200, 400, and 600 mg/kg, p.o) of A. cadamba leaves showed significant hepatoprotective effect against paracetamol-induced liver damage model in rats. Methanol extract fraction of stem bark also reported hepatoprotective property against CCl4-induced hepatotoxicity in rats.
From the experimental studies which were carried out by various research scholars, we can analyzed that the marked decrease in the lipid level in alloxan (150 mg/kg body wt.)-induced diabetic rats. Oral administration of root extract (500 mg/kg body wt.) of A. cadamba for 30 days in dyslipidemic animals resulted in effective decline in levels of total cholesterol, phospholipids, triglycerides, and lipid peroxides. In one of the studies, the root of extract of A. cadamba was administered into rats which are induced initially with hyperlipidemia, which showed decreased plasma lipids and reactivated postheparin lipolytic activity in hyperlipidemic rats. In another model, A. cadamba fruit extract exerted promising lipid-lowering effect with hepatic lipolytic activity. Both bark and leaf of Cadamba were effective in bringing back the symptomatology explained in Ayurveda for Medoroga and the abnormal lipid profile to normalcy laid down in modern classics with special reference to hyperlipidemia, but the leaf is clinically effective in Medoroga and leaf is little more efficacious than bark and it is a drug of choice in the management of Medoroga.
Analgesic, antipyretic, and anti-inflammatory activities
Extracts of the bark and leaf of A. cadamba possessed valuable properties such as analgesic, antipyretic, and anti-inflammatory activities. The defatted aqueous extract of the leaves of A. cadamba reportedly showed significant analgesic and anti-inflammatory activity at varying doses (50, 100, 300, and 500 mg/kg)., Similarly, ethanolic extract of the leaf showed significant anti-inflammatory, analgesic, and antipyretic activity. The acute toxicity was also reported over Rats, was found to be higher than 2000 mg/kg. The methanolic extract of the bark of A. cadamba was effectively evaluated for analgesic, antipyretic, and anti-inflammatory activities in one of the studies.,
Antifilarial and antimalarial activities
Mosquito-borne diseases such as malaria, dengue, chikungunya, filariasis, and Japanese encephalitis cause thousands of deaths per year in India as well as in other developing countries. Dimethyl sulfoxide extract of Cadamba slows the larvicidal effect on the filarial vector at low concentrations with LC50 at 0.61 ppm. Similarly, methanolic leaf extract of A. cadamba also possess promising inhibiting effect on both growth and developmental activity against Culex quinquefasciatus.
Sedative and antiepileptic effects
The sedative and antiepileptic activities of ethanolic extract of A. cadamba bark are also reported in various experimental animal models. The extract at dose of 100, 200, and 400 mg/kg p.o. showed significant increase in ketamine-induced sleeping time, and it also exhibited significant increase in latency to clonic convulsion, tonic extension, and time of death in pentylenetetrazole-induced seizures, isoniazid-induced seizures, and maximal electroshock-induced seizures models at all tested doses.
The methanol fruit extract of A. cadamba also reported for its promising urolithiatic activity on calcium oxalate-induced nephrolithiasis in Wistar albino rats. The extract (200 and 400 mg/kg, p.o) was found to be effective to both curative and preventive treatment groups. Calcium oxalate crystals are found to be reduced by the extract administration as evident from Pizzolato staining and histopathological studies.
Hot aqueous extract of A. cadamba leaves have promising immunomodulating potential as indicated by the antibody response in immunized animals. Increase in interleukin-2 expression at gene as well as at protein level clearly suggests its application in immunosuppressed animals.
It has been found that methanolic extract of the root bark of Cadamba can be used as an antidote against snakebite. It is used in neutralizing Vipera russellii and Naja kaouthia venom, which can induce hemorrhage, cardiotoxicity, neurotoxicity, defibrinogenation, and inflammation. The pentacyclic triterpenes (free or as glycosides) have a crucial significance in providing around 20% protection against snake venom.
The antiulcer activity of aqueous and methanol extracts of A cadamba leaves and bark was investigated in both pylorus ligation and aspirin-induced ulcer models. Both the extracts at dose of 200 and 400 mg/kg, p.o., produced significant inhibition of gastric lesion induced by pylorus-ligation induced ulcer and aspirin-induced gastric ulcer. Simultaneously, the extracts also showed significant reduction in gastric volume, pH, free acidity, total acidity, ulcer index, and % ulcer inhibition.
Aqueous and ethanolic extracts of stem–bark of this plant were screened for anthelminthic activity against earthworms, tapeworms, and roundworms using albendazole as reference drug. The ethanol extract was found potent than aqueous extract. Simultaneously, various extracts of A. cadamba barks possess anthelmintic activity in a dose-dependent manner. Potency of the test samples was found to be inversely proportional to the time taken for paralysis/death of the worms. The activities were compared with the reference drug piperazine citrate. Among the tested extracts, the chloroform extract and pet-ether extract were found to possess potent anthelmintic activity while methanol extract showed moderate activity. In one of the studies, anthelmintic activity was evaluated using the aquarium worm (Tubifex tubifex) and the study concluded that the leaves of A. cadamba have found to possess moderate and significant anthelmintic activity. Similarly, aqueous and methanolic extracts of the leaves possess remarkable anthelminthic property which was performed on the adult Indian earthworm Pheretima posthuma. The fresh bark juice also showed significant anthelminthic activity at 25, 50, and 100 mg/ml concentration. Various extracts of A. cadamba roots was also evaluated for anthelmintic activity on adult Indian earthworms using piperazine citrate as reference standard and the results indicated that the chloroform and methanolic extracts were more potent than the petroleum ether extract.
Whole plant of A. cadamba (barks, leaves, flowers, and fruits) extract has potent wound-healing capacities which possess promising wound contraction and increased tensile strength. The results also reported that the extract possesses potent antioxidant activity by inhibiting lipid peroxidation and increase in the SOD and catalase activity. Similarly, the ethyl acetate fraction of methanolic leaves extract of A. cadamba showed potent wound-healing activity in both excision and incision wound models along with potent antioxidant and free radical scavenging activity.
Aqueous extracts of A. cadamba fruits reported promising antioxidant and antibacterial effect against Escherichia coli, Pseudomonas aeruginosa, Yersinia More Details enterocolitica, Staphylococcus aureus, Bacillus cereus, and Listeria innocua. Similarly, different solvent extracts of A. cadamba fruits were also screened for its antimicrobial activity against Gram-positive (S. aureus and B. cereus) and Gram-negative (E. coli, Salmonella abony, and Shigella boydii) bacterial cultures by agar well diffusion method as well as by minimum inhibitory concentration (MIC) and minimum bactericidal concentration; here, alcoholic extract showed significant antibacterial activity against E. coli and S. aureus with the zone of inhibition of 22–24 cm and low MIC value up to 1.00 mg/ml. Mishra and Siddique reported that methanolic extracts of unripened fruits possess very low MIC value and inhibited the growth of P. aeruginosa and S. aureus with MIC as low as 1.00 mg/ml. Silver nanoparticles synthesized using leaf and fruit extracts were also screened for antibacterial activity by using four human pathogens, namely E. coli, P. aeruginosa, S. aureus, and Bacillus subtilis, but silver nanoparticles synthesized using leaf extract have shown predominant antibacterial activity rather than fruit extract. The experimental evidence also proved that the various extracts of the leaves of A. cadamba has been studied by agar cup plate diffusion method, but chloroform and acetone extracts exhibited strong activity against bacteria (E. coli, P. aeruginosa, S. aureus, and Salmonella typhi) and fungi (Aspergillus niger and Candida albicans). The crude methanolic extract of the leaves showed moderate broad spectrum antibacterial activity against both Gram-positive and Gram-negative bacteria. The zone of inhibitions was observed in the range of 6.5-14.5 mm for concentrations 300 μg/μl; in addition, the methanol extract of A. cadamba leaf showed effective antioxidative potential against DPPH and ABTS radicals with relatively moderatein vitroα-amylase inhibitory activities. The antimicrobial analysis using the agar well diffusion method and MIC value is been used by many researchers, but the n-hexane, ethyl acetate, and ethanolic extracts of the leaf suggested that the plant extracts were bacteriostatic at lower concentration but bactericidal at higher concentration. Simultaneously,in vitro antimicrobial assay in both methanolic and aqueous extract of A. cadamba bark depicted inhibitory zone for bacterial growth, but the results were found only to be significant against test bacteria B. subtilis and Klebsiella pneumonia. Butea monosperma revealed no methanolic as well aqueous extract activity against any test bacteria except Proteus vulgaris in aqua media. Petroleum ether (60°C–80°C), chloroform, methanolic, and aqueous extracts of the roots were also evaluated separately for antimicrobial study; all the extracts were tested against certain Gram-positive and Gram-negative organisms by well diffusion method, but it was reported that both methanolic and aqueous extracts at the concentration of 20 mg/ml possess significant antimicrobial activity against all the tested organisms, viz., E. coli, S. aureus, K. pneumoniae and P. aeruginosa.
Toxicity is the fundamental science of poisons and the ancient humans categorized some plants as harmful and some as safe; therefore, considerable attention has been directed toward identification of plants with no toxicity that may be used for human consumption. The methanolic extract of A. cadamba barks was reported for its toxicity in various animal models. The results suggested that acute toxicity was found in animal models at doses range higher than 3000 mg/kg, and there was no mortality found. The subacute toxicity was also carried out at dose 600 mg/kg, p.o. and it suggested that at tested dose level, the extract was nontoxic and does not affect circulating red cells, hematopoiesis, or leucopoiesis. The results of the histopathology study revealed no sign and symptoms of degeneration on the isolated organs. Similarly, the reported acute toxicity studies of various extracts of roots, leaves, and fruits of A. cadamba was observed that all animals groups could tolerate a maximum dose of higher than 2000 mg/kg, p.o., without noticeable behavioral changes and there was no mortality found.
Geranyl acetate esterase inhibitory activity
Gupta and Ganjewala report the unique property of the methanol extract of A. cadamba fruit, which inhibited the geranyl acetate esterase (GAE) of lemongrass and this is the first report on GAE inhibitory activity. It was also suggested that the flavonoids present in the fruit extract act as suicide substrates ahead of cholesterol esters and GAE.
Nanoparticle formulation of a chlorophyll-rich biomolecular extract of A. cadamba combined with a near-infrared dye has been found to selectively kill skin cancer cells. The plant extract is particularly toxic to cancer cells as there is enhanced generation of reactive oxygen species while the dye aids in the destruction of cancer cells through photothermal therapy.
As A. cadamba is a fast-growing tropical hardwood tree and extensively used for various purposes such as plywood and pulp production and light furniture fabrication and as a raw material for the preparation of indigenous medicines. Hence, lack of genomic information is available which hampers to progress in the molecular breeding and genetic improvement of this species thereby, transcriptome profiling of differentiating stems was performed to understand A. cadamba xylogenesis and identified several genes responsible for xylogenesis using Illumina paired-end sequencing technology. As A. cadamba has economically benefited, so various researchers involve to developin vitro propagation and conversation of this species through apical bud and nodal and tissue culture techniques for sustainable supply of planting materials for commercial plantation., As A. cadamba are economically and medicinally important plant thereby to enhance the production of bioactive compounds through in vitro plant tissue culture system are using, thereby this biotechnological approach helps in production of secondary metabolites through plant tissue culture technique and provides an alternative mean for commercial production of alkaloid and flavonoids. This can also help to prevent the plant from becoming endangered due to routine use of conventional methods of collection of plant material and extracting bioactive compounds. In addition, it provides great promise for controlled production of myriad of useful bioactive compounds on demand at a continuous and large scale. Similarly, 3β-isodihydrocadambine was isolated from the bark and leaf of A. cadamba, which is eco-friendly because for its corrosion inhibitors for mild steel.
| Phytochemistry|| |
Numerous numbers of phytoconstituents has been reported from various parts of Anthocephalus cadamba and as a consequence, varied classes of compound, viz., alkaloids, coumarins, terpenoids, diterpenoids, triterpenes glycosides, sterols, flavonoids, amides, fatty acids, and its esters have been isolated from its different parts through various chromatography and spectrophotometric methods. The details of chemical constituents and their structures obtained from A. cadamba depicted in [Table 5], [Table 6], [Table 7].
|Table 6: Phytochemical screening of solvent extract of Anthocephalus cadamba leaves by gas chromatography–mass spectrometry|
Click here to view
| Conclusion|| |
Several parts of A. cadamba including stem bark, stem, leaves, bark, root bark, flower, seed, heartwood, sapwood, and branches contain a number of phytoconstituents that belong to alkaloids, coumarins, terpenoids, diterpenoids, triterpenes glycosides, sterols, flavonoids, amides, and fatty acids. These have been reported to possess various pharmacological activities such as antidiabetic, antioxidant, antitumor, nephrotoxicity, diuretic and laxative, antihepatotoxic, hypolipidemic, analgesic, antipyretic, anti-inflammatory, antifilarial antimalarial, sedative, antiepileptic, urolithiatic, immunomodulatory, antivenom, gastroprotective, anthelminthic, wound healing, antimicrobial, GAE inhibition, toxicological studies, nanotechnology, and agroforestry. Various solvent extract and their gas chromatography–mass spectrometry studies established a number of chemical compounds and their structures. This review mainly highlights about pharmacological and phytochemical studies which have illustrated therapeutic potential and phytochemical constituents of A. cadamba.
We are thankful to GITAM Institute of Pharmacy, GITAM (Deemed to be University), Visakhapatnam, Andhra Pradesh, India, for carrying out this review.
Financial support and sponsorship
This study was supported by GITAM (Deemed to be University), Visakhapatnam, Andhra Pradesh, India.
Conflicts of interest
There are no conflicts of interest.
| References|| |
Moraes GM. The Kadamba Kula, A History of Ancient and Medieval Karnataka. New Delhi: Asian Educational Services; 1931.
Government of India, Ministry of Health and Family Welfare, Department of Ayush. The Ayurvedic Pharmacopoeia of India. Part 1, Vol. 2. Government of India, Ministry of Health and Family Welfare, Department of Ayush; 2008. p. 68-9.
Sharma PV. Dravyaguna. Vol. 2. Varanasi: Chaukhambha Bharati Academy; 2009.
Sharma PV, Sharma GP. Kaiyadeva Nighantu. Varanasi: Chaukhambha Orientalia; 1975.
Gupta SM. Plant Myths and Traditions in India. 2nd
ed. New Delhi: Munshiram Manoharlal Publishers Pvt. Ltd.; 1991.
Pandey GS, Chunekar KC, editors. Bhavaprakasha Nighantu. Varanasi: Chaukhambha Bharati Academy; 2009.
Sastri KN. Charaka Samhita. Vol. 1, 2. Varanasi: Chaukhambha Sanskrit Sansthan; 1962.
Naithani HB, Sahni KC. Forest Flora of Goa. 1st
ed. Dehradun: International Books Distributors; 1997.
Prajapati ND, Purohit SS, Sharma AK, Kumar T. A Handbook of Medicinal Plants: A Complete Source Book. Jodhpur: Agrobios (India) Publisher; 2007.
Council of Scientific and Industrial Research. The Wealth of India, A Dictionary of Indian Raw Materials and Industrial Products. New Delhi: NISCAIR Press Publishers; 2006.
Biju Pattnaik Medicinal Plants Garden Research Centre. Odisha Review. Jeypore: Biju Pattnaik Medicinal Plants Garden Research Centre; 2005.
Council of Scientific and Industrial Research. The Wealth of India: Raw Materials. Vol. 1. New Delhi: Council of Scientific and Industrial Research Publishers; 1985.
Singh SP, Lal P. Effect of different spacing treatments on yield from Anthocephalus chinensis
plantations. Indian For 1982;108:734-40.
Kapil A, Koul IB, Suri OP. Antihepatotoxic effects of chlorogenic acid from Anthocephalus cadamba
. Phytother Res 1995;9:189-93.
Council of Scientific and Industrial Research. The Wealth of India: Raw Materials. Vol. 1. New Delhi: Publication and Information Directorate, Council of Scientific and Industrial Research; 1992.
Gunasekhran R, Divyakant A. Anthelmintic activity of leaf alcoholic extract of Neolamarckia cadamba
(Roxb) Bosser. J Nat Prod 2006;22:11-3.
Patel D, Kumar V. Pharmacognostical studies of Neolamarckia cadamba
(Roxb.) Bosser leaf. Int J Green Pharm 2008;1:26-7.
Umachigi SP, Kumar GS, Jayaveera K, Kishore KD, Ashok KC, Dhanapal R. Antimicrobial, wound healing and antioxidant activities of Anthocephalus cadamba
. Afr J Tradit Complement Altern Med 2007;4:481-7.
Banerji N. Structure of two new saponins from stem bark of Anthocephalus cadamba
MIQ. J Indian Chem Soc 1978;55:275-8.
Brown RT, Chapple CL. Anthocephalus
alkaloids: Cadamine and isocadamine. Tetrahedron Lett 1976;19:629-30.
Bijalwan A, Manmohan JR. A potential fast growing tree for agroforestry and carbon sequestration in India: Anthocephalus cadamba
(Roxb.) Miq. Am J Agric For 2014;26:296-301.
Li J, Zhang D, Ouyang K, Chen X. The complete chloroplast genome of the miracle tree Neolamarckia cadamba
and its comparison in Rubiaceae
family. Biotechnol Biotechnol Equip 2018;325:1087-97.
Devgan M, Bhatia L, Kumar H. Anthocephalus cadamba
: A comprehensive review. Res J Pharm Tech 2012;5:1478-83.
Dhotre R, Maheboob S, Kare M. Phytochemical screening of Anthocephalus cadamba
(Roxb.) Miq. bark. Int J Res Pharm Pharm Sci 2018;3:228-30.
Dubey A, Nayak SS, Goupale DC. Anthocephalus cadamba
: A review. Pharmacogn J 2011;2:71-6.
Krisnawati H, Kallio M, Kanninen M. Anthocephalus cadamba
Miq. Ecology, Silviculture and Productivity. Bogor, Indonesia: Center for International Forestry Research; 2011.
Sudrajat DJ, Siregar IZ, Khumaida N, Siregar UJ, Mansur I. Genetic diversity in White Jabon (Anthocephalus cadamba
(Roxb.) Miq.) based on AFLP markers. Asia Pac J Mol Biol Biotechnol 2015;22:224-31.
Kirtikar KR, Basu BD. Indian Medicinal Plants. 2nd
ed. India: Lalit Mohan Basu Publishers; 1999.
Ministry of Ayush, Government of India. The Ayurvedic Pharmacopoeia of India. 1st
ed. New Delhi: Controller of Publication; 1999.
Patel DA, Patel YK, Shah PB. Pharmacognostical study of Neolamarckaia cadamba
(Roxb.) Bosser bark. Int Res J Pharm 2012;3:120-1.
Patel D, Kumar V. Pharmacognostical studies of Neolamarckia cadamba
(Roxb.) Bosser Leaf. Int J Green Pharm 2008;2:26-7. [Full text]
Gupta DC, Dalal MR. Meloidogyne javanica
associated with Kadam (Anthocephalus cadamba
Roxb. Pesticides 1973;7:29.
Gibson IA, Nylund J. Sudden death, a disease of Cadam (Anthocephalus cadamba
(Roxb.) Miq.). Commonw For Rev 1976;55:219-27.
Acharyya S, Padhy S, Dash SK. Pharmacognostic studies on the root of Anthocephalus cadamba
(Roxb.) Miq. Pharmacogn J 2018;10:973-8.
Pal DC, Jain SK. Tribal Medicine. New Delhi: Naya Prakash; 2000.
Kiritikar KR, Basu BD. Indian Medicinal Plants 2nd
ed. Vol 1. India: Lalit Mohan Basu; 1933.
Bhandary MJ, Chandrashekar KR, Kaveriappa KM. Medical ethnobotany of the Siddis of Uttara Kannada district, Karnataka, India. J Ethnopharmacol 1995;47:149-58.
Ambujakshi HR, Antony ST, Kanchana Y, Patel R, Thakkar H, Shyamnanda. Analgesic activity of Anthocephalus cadamba
leaf extract. J Pharm Res 2009;2:1279-80.
Majumdar A. Home Remedies in Ayurveda. 1st
ed. Delhi: Amar Granth Publication; 2002.
Naryan S, Bhumarkar H. A review on pharmacological activity of Anthocephalus cadamba
. World J Pharm Res 2018;7:383-94.
Slkar IV, Kakkar KK, Chakre OJ. Glossary of Indian Medicinal Plants with Active Principles. Part 1. New Delhi: CSIR Publishers; 1992.
Kumar B, Chaudhary SP, Singh AK. Kadamba in Ayurveda-Critical Review. Int J Pharm Arch 2015;4:45-9.
Kumar V. Medicinal Properties of Anthocephalus indicus
(Kadam): An Indigenous Medicinal Plant. Era's J Med Res 2017;4:7-11.
Bussa SK, Pinnapareddy J. Antidiabetic activity of stem bark of Neolamarckia cadamba
in alloxan induced diabetic rats. Int J Pharm Tech 2010;2:314-24.
Gurjar H, Jain SK, Irchhaiya R, Nandanwar R, Sahu VK, Saraf H. Hypoglycemic effects of methanolic extract of Anthocephalus cadamba
bark in alloxan induced diabetic rats. Int J Pharm Sci Res 2010;1:79-83.
Acharyya S, Dash DK, Mondal S, Dash SK. Studies on glucose lowering efficacy of the Anthocephalus cadamba
root. Int J Pharm Bio Sci 2010;1:1-9.
Sanadhya IU, Bhot M, Varghese J, Chandra N. Antidiabetic activity of leaves of Anthocephalus indicus
A. Rich., in alloxan induced diabetic rats. Int J Phytomed 2012;4:511-8.
Ahmed F, Rahman S, Ahmed N, Hossain M, Biswas A, Sarkar S, et al
. Evaluation of Neolamarckia cadamba
(Roxb.) Bosser leaf extract on glucose tolerance in glucose-induced hyperglycemic mice. Afr J Tradit Complement Altern Med 2011;8:79-81.
Alam MA, Subhan N, Chowdhury SA, Awal MA, Mostofa M, Rashid MA, et al
. Anthocephalus cadamba
extract shows hypoglycemic effect and eases oxidative stress in alloxan-induced diabetic rats. Braz J Pharmacogn 2011;21:155-64.
Kumar V, Khan MM, Khanna AK, Singh R, Singh S, Chander R, et al
. Lipid lowering activity of Anthocephalus indicus
root in hyperlipidemic rats. Evid Based Complement Altern Med 2010;7:317-22.
Chandrashekar KS, Prasanna KS. Antomicrobial activity of Anthocephalus cadamba
Linn. J Chem Pharma Res 2009;1:268-70.
Fatima N, Ahmad MK, Ansari JA, Khan HJ, Rastogi N, Srivastava SK, et al
. Antiproliferative and antioxidant studies of Anthocephalus cadamba
(Roxb.) Miq. bark. Ind J Pharm Sci 2016;78:525-31.
Ganjewala D, Tomar N, Gupta AK. Phytochemical composition and antioxidant properties of methanol extracts of leaves and fruits of Neolamarckia cadamba
(Roxb.). J Biol Act Prod Nat 2013;3:232-40.
Alam MA, Ghani A, Subhan N, Rahman MM, Haque MS, Majumder MM, et al
. Antioxidant and membrane stabilizing properties of the flowering tops of Anthocephalus cadamba
. Nat Prod Communications 2008;3:65-70.
Khandelwal V, Bhatia AK, Goel A. Antimicrobial and antioxidant efficacy of aqueous extract of Anthocephalus cadamba
leaves. J Pure Appl Microbiol 2016;10:209-16.
Chandel M, Sharma U, Kumar N, Singh B, Kaur S. Antioxidant activity and identification of bioactive compounds from leaves of Anthocephalus cadamba
by ultra-performance liquid chromatography/electrospray ionization quadrupole time of flight mass spectrometry. Asian Pac J Trop Med 2012;5:977-85.
Chandel M, Kaur S, Kumar S. Studies on the genoprotective/antioxidant potential of methanol extract of Anthocephalus cadamba
(Roxb.) Miq. J Med Plants Res 2011;5:4764-70.
DonPaul AM, Weerakoon SR, Somaratne S. Antioxidant properties of leaf, twig and calli extracts of Neolamarckia cadamba
(Roxb.) Bosser in Sri Lanka. Res J Med Plants 2016;10:314-9.
Dolai N, Karmakar I, Suresh Kumar RB, Kar B, Bala A, Haldar PK. Evaluation of antitumor activity andin vivo
antioxidant status of Anthocephalus cadamba
on Ehrlich ascites carcinoma treated mice. J Ethnopharmacol 2012;142:865-70.
Kamal AT, Chowdhury KA, Masud MR, Islam A, Khan EA, Areeful MH, et al
. Study of cytotoxic, thrombolytic and anthelmintic activity of extract of Neolamarckia cadamba
(Roxb.) leave. Eur Med Plants 2015;10:1-9.
Chandel M, Kumar M, Sharma U, Kumar N, Singh B, Kaur S. Isolation and characterization of flavanols from Anthocephalus cadamba
and evaluation of their antioxidant, antigenotoxic, cytotoxic and COX-2 inhibitory activities. Braz J Pharmacogn 2016;26:474-83.
Brazilian Journal of Pharmacognosy. Cytotoxic effect of Anthocephalus cadamba
Miq. leaves on human cancer cell lines. Pharmacogn J 2013;5:127-9.
Dolai N, Islam A, Haldar PK. Methanolic extract of Anthocephalus cadamba
induces apoptosis in Ehrlich ascites carcinoma cells in experimental mice. Indian J Pharmacol 2016;48:445-9.
] [Full text]
Abu MS, Parvin S, Abdul MK. Antimicrobial and preliminary cytotoxic effects of ethanol extract and its fractions of Anthocephalus cadamba
(Roxb.) Miq stem bark. Int J Pharm Life Sci 2014;5:4038-44.
Mishra DP, Khan MA, Yadav DK, Rawat AK, Singh RK, Ahamad T, et al
. Monoterpene indole alkaloids from Anthocephalus cadamba
fruits exhibiting anticancer activity in human lung cancer cell line H1299. Chem Sel 2018;3:8468-72.
Saisruthi K, Sreedevi A. Amelioration of cisplatin-induced nephrotoxicity by roots of Anthocephalus cadamba
. Biomed Pharmacol J 2017;10:1433-9.
Jyotsana, Nagpal KL. Restorative effect of cadamba
fruit extract on arsenic-induced nephrotoxicity in albino mice. J Adv Sch Res All Educ 2017;14:408-14.
Mandal S, Dash GK, Acharya A, Sharma, HP. Studies on diuretic and laxative activity of bark extract of Neolamarckia cadamba
(Roxb.) Bosser. Drug Invent Today 2009;1:78-80.
Prathibhakumari PV, Prasad G. Pharmacological investigation on the diuretic activity of the aqueous fruit extract of Neolamarckia cadamba
(Roxb) Bosser. J Pharm Res 2014;8:130-5.
Malothu R, Mathala N, Adarsh G, Rao MD. Hepatoprotective activity and anti-oxidant activity of Anthocephalus indicus
in ethanol induced hepatotoxicity in albino Wistar rats. Int J Phytopharmacol 2012;3:245-8.
Swarnkar R, Jain SK, Niranjan PS, Niranjan SK. Pharmacological investigation of leaves of Anthocephalus cadamba
(Roxb) for hepatoprotective activity. J Res Dev Pharm Life Sci 2016;5:2410-3.
Dolai N, Kumari U, Islam A, Haldar PK. Inhibitory effects of Anthocephalus cadamba
stem bark fractions intercede anti-inflammatory and carbon tetrachloride induced hepatotoxicity in rats. Orient Pharm Exp Med 2015;15:123-34.
Kumar V, Mahdi F, Chander R, Singh R, Mahdi AA, Khanna AK, et al
. Hypolipidemic and antioxidant activity of Anthocephalus indicus
(Kadam) root extract. Indian J Biochem Biophys 2010;47:104-9.
Kumar V, Singh S, Khanna AK, Khan MM, Chander R, Mahdi F, et al
. ypolipidemic activity of Anthocephalus indicus
(kadam) in hyperlipidemic rats. Med Chem Res 2008;17:152-8.
Swetha C, Narasimha V. Comparative clinical study of Kadamba (Anthocephalus cadamba
(Roxb.) Miq) bark and leaf in Medoroga. Ann Int J Res AYUSH All Syst 2019;6:2095-101.
Bachhav RS, Buchake VV, Saudagar RB. Analgesic and anti-inflammatory activities of Anthocephalus cadamba
Roxb. leaves in Wistar rats. Res J Pharm Technol 2009;2:164-7.
Verma R, Chaudhary F, Kumar J. Evaluation of anti-inflammatory, analgesic and antipyretic properties of Neolamarckia cadamba
on Wistar albino rats. J Pharmacol Clin Res 2019;7:1-5.
Chandrashekar KS, Borthakur A, Prasanna KS. Anti-inflammatory effect of the methanol extract from Anthocephalus cadamba
stem bark in animal models. Int J Plant Biol 2010;1:30-2.
Mondal S, Dash GK, Acharyya S. Analgesic, Anti-inflammatory and antipyretic studies of Neolamarckia cadamba
barks. J Pharm Res 2009;2:1133-6.
Kumar AN, Jeyalalitha T, Murugan K, Madhiyazhagan P. Bioefficacy of plant mediated gold nanoparticles and Anthocephalus cadamba
on filarial vector, Culex quinque fasciatus
). Parasitol Res 2013;112:1053-63.
Jeyalalitha T, Murugan K, Umayavalli M, Sivapriya V. FTIR analysis and the effect of leaf extract of Anthocephalus cadamba
and biosynthesiszed gold nanoparticles of Cymbopogancitratus
on the Growth and Development of Culex quinquifasciatus
). Int J Recent Sci Res 2016;7:11965-70.
Nagakannan P, Shivasharan BD, Veerapur VP, Thippeswamy BS. Sedative and antiepileptic effects of Anthocephalus cadamba
Roxb. in mice and rats. Indian J Pharmacol 2011;43:699-702.
] [Full text]
Prathibhakumari PV, Prasad G. Inhibition of CaOx crystals by Neolamarckia cadamba
: Anin vivo
approach. Trends Biosci 2018;11:2356-73.
Khandelwal V, Choudhary PK, Goel A, Bhatia AK, Gururaj K, Gupta S, Singh SV. Immunomodulatory activity of Neolamarckia cadamba
(Roxb.) Bosser with reference to IL-2 induction. Indian J Tradit Know 2018;17:451-9.
Lakhmale SP, Acharya R, Yewatkar N. Ethanomedicinal claims on antivenom activity of certain fruit and seed drugs – A review. Ayurpharm Int J Ayur Alli Sci 2012;1:21-9.
Inaparthi VK, Babu PN, Prasad K, Nagaraju B, Prasanthi K, Srinivasa. Evaluation of anti-ulcer andin vitro
antioxidant activities of aqueous and methanolic extracts of Neolamarckia cadamba
leaves and bark in Wistar albino rats. Intl J Pharm Sci Res 2014;5:1852-8.
Gunasekaran R, Senthilkumar KL, Gopalkrishnan S. Anthelmintic activity of bark of Neolamarckia cadamba
. Indian J Nat Prod 2006;22:11-3.
Mondal S, Ramana H, Suresh P. Anthelmintic activity of Neolamarckia cadamba
barks. Hygeia J Drugs Med 2011;3:16-8.
Srikar DV, Krishna PR, Sunitha R, Manoharbabu S. Evaluation of antihelminthic activity of leaves extract of methanolic and aqueous extracts of Neolamarckia cadamba
leaves. Int J Pharm Chem Res 2017;3:446-51.
Hassan MA, Ferdous A, Chowdhury R, Khan RA. Evaluation of analgesic, anthelmintic and cytotoxic potential activity of barks of Anthocephalus cadamba
. Int J Innov Pharm Sci Res 2013;1:99-107.
Acharyya S, Rathore DS, Kumar HKS, Panda N. Screening of Anthocephalus cadamba
(Roxb.) Miq., for antimicrobial and anthelmintic activities. Int J Res Pharm Biomed Sci 2011;2:297-300.
Nayan S, Mishra CK, Priyadarshini D, Pradhan KK, Ghosh M, Pattnaik A. Wound healing activity of gel formulated leaves extract of Neolamarckia cadamba
(Roxb) Bosser. Indian J Pharm Educ Res 2019;53 Suppl 2:S416-22.
Pandey A, Negi PS. Phytochemical composition,in vitro
antioxidant activity and antibacterial mechanisms of Neolamarckia cadamba
fruits extracts. Nat Prod Res 2018;32:1189-92.
Datar H, Datar A. Antimicrobial activity of Anthocephalus cadamba
Roxb., against food pathogens. Int J Curr Pharm Res 2016;8:13-8.
Mishra RP, Siddique L. Antibacterial properties of Anthocephalus cadamba
fruits. Asian J Plant Sci Res 2011;1:1-7.
Kirtiwar S, Gharpure S, Balaprasad A. Effect of nutrient media on antibacterial activity of silver nanoparticles synthesized using Neolamarckia cadamba
. J Nanosci Nanotechnol 2019;19:1923-33.
Chandrashekar KS, Prasanna KS. Antimicrobial activity of Anthocephalus cadamba
Linn. J Chem Pharm Res 2009;1:268-70.
Zahan T, Khatun L, Siddika A, Nime MJ, Habib MR, Aziz MA, et al
. Evaluation of antioxidant, cytotoxic and antimicrobial potentials of Anthocephalus cadamba
(Roxb.) leaves. J Pharm Chem Biol Sci 2019;7:157-63.
Rajesh T, Venkatanagaraju E, Goli D, Basha SJ. Evaluation of antimicrobial activity of different herbal plant extracts. Int J Pharm Sci Res 2012;4:67-73.
Jain S, Arora A.In vitro
antimicrobial evaluation of Anthocephalus cadamba
, Butea monosperma
, Diospyrous melanoxylon
and Ficus glomerata
bark extract against certain bacteria. IOSR J Pharma 2018;8:35-40.
Lobo VC, Phatak A, Chandra N. Acute toxicity studies of some Indian medicinal plants. Pharmacogn J 2010;2:207-10.
Mondal S, Dash GK, Samanta A, Bhunia SN. Toxicity study of few medicinal plants from flora of Orissa used by folklore against various diseases. J Pharm Res 2009;2:1746-50.
Gupta AK, Ganjewala D. Geranyl acetate esterase (GAE) inhibitory activity of Neolamarckia cadamba
fruit extract. Acta Biol Szeged 2015;59:59-63.
Pemmaraju D, Appidi T, Minhas G, Singh SP, Khan N, Pal M, et al
. Chlorophyll rich biomolecular fraction of A. cadamba
loaded into polymeric nanosystem coupled with Photothermal Therapy: A synergistic approach for cancer theranostics. Int J Biol Macromol 2018;110:383-91.
Ouyang K, Li J, Zhao X, Que Q, Li P, Huang H, et al
. Transcriptomic analysis of multipurpose timber yielding tree Neolamarckia cadamba
during xylogenesis using RNA-Seq. PLoS One 2016;11:e0159407.
Rahman SS, Muhammad N, Hassan NH, Ismail H, Abdullah N, Yahya MF, et al
. Development of Neolamarckia cadamba
(kelempayan) tissue culture techniques for sustainable supply of planting materials for commercial plantation. J Teknol Sci Eng 2015;77:159-63.
Joshi A, Mathur N.In vitro
propagation and conservation of Anthocephalus cadamba
through apical bud and nodal explants – A valuable medicinal plant. CIB Tech J Biotechnol 2015;4:8-18.
Sanadhya I. Enhanced production of alkaloid, a bioactive compound inin vitro
culture system of Anthocephalus indicus
A. Rich. J Int Acad Res Multidiscip 2014;2:683-94.
Indu S, Vijaya L, Meeta B, Jossy V, Naresh C. Production of flavonoids in callus culture of Anthocephalus indicus
A. Rich. Asian J Plant Sci 2013;12:40-5.
Raja PB, Qureshi AK, Rahim AA, Osman H, Awang K. Neolamarckia cadamba
alkaloids as eco-friendly corrosion inhibitors for mild steel in 1M HCl media. Corros Sci 2013;69:292-301.
Sahu N, Mahato S, Banerji N, Cakravarti R. Cadambagenic acid. A new triterpenic acid from Anthocephalus cadamba
Miq. Indian J Chem 1974;12:284-6.
Banerji N. New saponins from stem bark of Anthocephalus cadamba
Miq. Indian J Chem B 1977;15:654-5.
Brown RT, Fraser SB. Anthocephalus
alkaloids, cadambine and 3a-dihydrocadambine. Tetrahedron Lett 1974;15:1957-9.
Brown RT, Fraser SB, Banerji J. Heartwood of cadamba
contains glucoalkaloids of isodihydrocadambien. Tetrahedron Lett 1974;29:3335-8.
Richard T, Brown BB, Chapple LC. Anthocephalus
alkaloids: Cadamine and isocadamine. Tetrahedron Lett 1976;19:1629-30.
Brown RT, Fraser SB, Chapple LC. Anthocephalus
alkaloids: 3 ß-dihydrocadambine and 3 ß-isodihydrocadambine. Tetrahedron Lett 1976;17:2723-4.
Sahu NP, Koike K, Jia Z, Achari B, Banerjee S, Nikido T. Structure of two novel triterpenoid saponins from A. cadamba
. Magn Reson Chem 1999;37:837-42.
Liu L, Di Y, Zhang Q, Fang X, Zhu F, Chen D, et al
. Aminocadambines A and B, two novel indole alkaloids from Neolamarckia cadamba
. Tetrahedron Lett 2010;51:5670-73.
Brown RT, Duckworth DM, Santos CA. Biogenetically patterned synthesis of cadambine. Tetrahedron Lett 1991;32:1987-90.
Takayama H, Tsutsumi S, Kitajima M, Santiarworn D, Liawruangrath B, Aimi N. Gluco-indole alkaloids from Nauclea cadamba
in Thailand and transformation of 3 alpha-dihydrocadambine into the indolopyridine alkaloid, 16-carbomethoxynaufoline. Chem Pharm Bull (Tokyo) 2003;51:232-3.3.
Sahu NP, Koike K, Jia Z, Banerjee S, Mandal NB, NIkaido T. Triterpene glycosides from the bark of Anthocephalus cadamba
. J Chem Res 2000;2000:22-3.
Szabó LF. Rigorous biogenetic network for a group of indole alkaloids derived from strictosidine. Molecules 2008;13:1875-96.
Gupta OC. A complex polysaccharide from the seeds of Anthocephalus indicus
. Carbohydr Res 1980;83:85-92.
Zayed MZ, Ahmed FB, Ho W, Pang S. GC-MS analysis of phytochemical constituents in leaf extracts of Neolamarckia cadamba
) from Malaysia. Int J Pharm Pharm Sci 2014;6:123-7.
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6]
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5], [Table 6], [Table 7]