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Amarkand: A comprehensive review on its ethnopharmacology, nutritional aspects, and taxonomy
Abstract
In India, the term “Amarkand” is commonly used for around 30 different plant species belonging to genus Eulophia (Orchidaceae). This single local name Amarkand to different taxonomical species creates uncertainty about its ethnomedical and nutritional claims. In the present article, we have reviewed available literature regarding ethnopharmacology, phytochemistry, taxonomy, nutritional, and pharmacological studies of different Amarkand species. The literature was searched using Google Scholar, PubMed, Scopus, and Web of Science databases. Some textbooks and reference books were also used to collect information about traditional and ethnopharmacological records. Amarkand species have been used as a remedy for the treatment of various diseases such as diarrhea, stomach pain, rheumatoid arthritis, cancer, asthma, bronchitis, sexual impotency, tuberculosis, and so on. Nutritionally, Amarkand is considered as an excellent food for children and convalescents. Recent studies confirm antioxidant, anti-inflammatory, anti-diarrheal, and so forth activities to Amarkand species. These species are reported to possess various phytoconstituents such as flavonoids, terpenoids, and phenanthrene derivatives. The present review will help to understand overall ethnopharmacology, nutritional aspects, and taxonomy of Amarkand species.
INTRODUCTION
Traditional medicines with therapeutic utility have been used since antiquity and are still contributing a significant role in the primary health-care system. It is estimated that 70-80% of the world’s population relies on traditional herbal medicines for their primary health care [1]. Parallel to traditional medicines, several ethnobotanical medicinal plants have also been validated for their therapeutic efficacy with the help of modern scientific tests. Some of these ethnobotanical plants are receiving merits as both food and medicine [2], and Amarkand is one of the best examples of this.
The word Amarkand is composed of two different words “Amar” means immortal and “kand” stands for tubers. The word Amarkand is commonly used for 30 closely related plant species from genus Eulophia (Orchidaceae) and for one species from the genus Dioscorea (Dioscorea bulbifera, family: Dioscoreaceae). Since ancient times, Amarkand is believed to be an excellent health-promoting agent. Rizhomes/tubers of Amarkand are routinely consumed by the tribal parts of India as food as well as a therapeutic entity for better health and longevity [2-4]. In Ayurvedic medicine, Amarkand is generally prescribed as expectorant, anabolic, tonic, diuretic, astringent, digestive, and soft purgative [5]. Moreover, the usefulness of these species for the treatment of ear discharge, blood clotting, joint edema, and debility has also been highlighted in some ancient texts [5]. However, this single local name, Amarkand to different taxonomical species creates confusion about its ethnomedical and nutritional claims. In the present article, we have reviewed the available literature regarding ancient therapeutic claims and recent chemical and pharmacological studies about Indian Eulophia species so as to link their ethnobotanical applications with recent scientific advances.
DISTRIBUTION
Genus Eulophia is highly diverse, occurs in a wide range of habitats, and belongs to family Orchidaceae. This plant produces two shoots, reproductive and vegetative, from their underground tubers. The genus Eulophia has a wide distribution and comprises over 230 species, which are widespread from tropical and Southern Africa, Madagascar and from neotropics to throughout tropical and subtropical parts of Asia and Australia. Among these, one species occurs in tropical America. In India, this genus is particularly distributed in tropical Himalaya and Deccan peninsula region. There are almost 723 records under Eulophia in International Plant Name Index. However, 500 are synonyms and many of them are ornamental [6]. Web of Science and Scopus showed about 247 and 80 documents, respectively, under the keyword “Eulophia” till October 2015.
Around 28 species are recorded from all over India, out of these, 20 species have medicinal importance. The medicinal properties of these species are documented in Table 1 [7-13]. Eulophia species are used for several therapeutic purposes in different parts of India [14]. Amarkand is the most prevailing name to all Eulophia species in India, however, these species are also known by several vernacular names such as Balakand, Manakand, Munjatak, Amrita (Sanskrit), Ambarkand, Salam (Hindi), Budbar (Bengali), Salab (Gujrati), Amarkand, and Salibmisri (Marathi).
Table 1
MORPHOLOGY
Species under genus Eulophia are terrestrial herbs, autotrophic, or rarely heteromycotrophic [Figure 1a]. Perennating organs may be pseudobulbs or tuber like. These pseudobulbs are subterranean or born above ground, corm like, tuberous or rhizomatous, usually with several nodes and slender or thick fibrous roots at the base. Eulophia develops a chain of underground tubers [Figure 1b]. Leaves appear at or after anthesis, which are thin but tough, narrow, and grass like or lanceolate and plicate and are one to many, basal and having petiole-like leaf base, sometimes overlapping and forming a pseudostem. Some species lack green leaves and are saprophytic. The inflorescence is erect, lateral, racemose or rarely paniculate, laxly to sub-densely many flowered or occasionally reduced to a solitary flower. Eulophia species are mostly identified by their flowers. Two types of flowers occur within Eulophia. In the first type, the sepals and petals are similar in size, shape, and color while in the other, sepals are smaller than petals and often recurved. In both types, the lip extends into a spur which can be very diverse in shape [6,15].
ANATOMICAL STUDIES
Infrageneric classification of Eulophia R. Br. ex Lindl. was carried out based on methods of classical taxonomy, particularly the examination of generative and vegetative characters, followed by their comparison based on the data obtained from molecular studies and scanning electron microscopy [6]. Study on Eulophia andamanensis Rchb. f. found that 0.1% colchicine is effective to induce mutations to increase flower size [16]. E. graminae Lindl. was also studied for its unique storage structure of the rhizome, brief juvenile stage, in vitro flowering and autogamous mating system, which explains its strong colonization ability [17]. An anatomical study has been carried out on Eulophia alta to investigate the pollination biology, breeding system, nectar production, and floral scent composition of the plant. This study clearly showed that flowers of E. alta were self-compatible, partially autogamous and effectively pollinated by five bee species. The nectar sugar content was reported to be highest on the third day after flower opening. Floral fragrance analyzes revealed 42 compounds, of which monoterpenes and benzoids are predominant [18]. Studies on asymbiotic and symbiotic seed germination of the same plant revealed that the symbiotic seed culture is a more efficient way of propagation [19]. An optimized method was devised for asymbiotic in vitro seed germination, seedling development, and field establishment of Eulophia nuda [20], a similar study was carried out with E. culleni [21].
MYCORRHIZAL STUDY
Eulophia zollingeri (Rchb.f.) J J Sm. was tested for its mycorrhizal specificity along with mycorrhizal association pattern, which was examined using DNS-based fungal identification. Results revealed that it exclusively associates with the group of fungi belonging to P. candolleana group and provide evidence that mycoheterotrophic plants can achieve wide distributions, even though they have high mycorrhizal specificity, if its fungal partner is widely distributed [22]. Yan-Qiu et al. [23] identified the presence of endophytic fungi in the fresh roots of Eulophia flava Lindl. Total of 52 fungal strains of 17 genera were isolated from fresh root samples of plants growing in sugarcane fields and on the mountain. Rhizoctonia and Fusarium were the dominant endophytes in these specimens.
TAXONOMICAL AMBIGUITY
Genus Eulophia was formally described by John Lindley in 1823. In India, species from this genus were identified in the early 19th century. Amarkand is well known to Indians since Vedic period, as a medicinal and food species. However, until today, no authentic information is available with respect to the exact species of Eulophia which are termed as Amarkand in ancient texts. The existing botanical name was assigned to Indian Eulophia species in the 19th century, but these species do not match with the description of Amarkand in ancient texts. In addition, most of the species of Eulophia are morphologically closely similar. Initially, E. nuda Lindl. was identified as Amarkand [24]. It was later revealed that Eulophia ochreata Lindl. possesses higher medicinal and food value than E. nuda Lindl. [25,26]. Recently, it has been found that two newly described species of Eulophia have much better pharmacological activities than the earlier species. However, until today, no authentic information is available with respect to the exact species of Eulophia which could be considered as Amarkand.
TRADITIONAL AND ETHNOBOTANICAL USES
In Ayurvedic medicine, Amarkand is generally prescribed as expectorant, anabolic, tonic, diuretic, astringent, digestive, and soft purgative, and also recommended for the treatment of ear discharge, blood clotting, joint edema, and debility [5]. In addition, it is also considered as a general tonic to promote strength and alleviates all the three “doshas” [27]. These are also used in stomatitis, purulent cough; and in the heart problems, dyscrasia, and scrofulous diseases of the neck; bronchitis, blood diseases, and as a vermifuge [28].
Different Eulophia species have been extensively used in the traditional system of medicines in many countries [29,30]. In India, several ethnopharmacological uses/application have been reported for different species of Eulophia in different parts of the country, which are summarized in Table 2.
Table 2
NUTRITIONAL STUDIES
Some of the Eulophia species have been studied for their nutritional properties. E. campestris Wall. is available as a salep (flour of starch) in Indian markets, as food for children and convalescents [50].
Balance between nutrients and anti-nutrients were studied in E. ochreata Lindl. It was found that tubers had low values of all free carbohydrates and had a low content of anti-nutrients such as phytic acid and trypsin inhibitors [51]. The proximate composition and mineral constituents indicated that these tubers are a good source of plant fibers, proteins, and carbohydrates [52].
Proximate analysis and minerals composition studies of tubers are also reported from India. Tubers of this wild edible plant are affluent of all nutrients such as starch, free sugars, oils, proteins, antioxidant phenols, and also a good source of almost all elements. Elemental profile of the same plant was checked using flame photometer and atomic absorption spectroscopy which revealed the presence of microelements such as iron and zinc in considerable amount. Jagtap et al. [26] studied the nutritive values of E. ochreata Lindl. (Amarkand) tubers with reference to its total protein content, fat content, reducing sugars, total carbohydrates, and Vitamin C, and reported that the tubers contain all nutritional factors in moderate quantity, except the maximum content of lipids (9 mg/g) among all the plants under the study. Authors suggested that these tubers could have potential worth in the diets of poor rural communities of India [53].
PHYTOCHEMISTRY
Medicinal plants produce thousands of patho-physiologically active principles that have been exploited over the years in the treatment of various ailments [54]. The qualitative and quantitative estimation of the phytochemical constituents of the medicinal plant is considered to be an important step in the herbal drug standardization [55]. Progress in phytochemistry has been aided enormously by the development of rapid and accurate methods of screening plants for particular bioactive chemicals.
Methanolic extracts of tubers of E. epidendrea (JKoen) Schltr. showed the presence of several classes of phytochemicals such as flavonoids, reducing sugars, cyanogenic glycosides terpenoids, and tannins [56]. Thin-layer chromatography (TLC) studies of the isolated fractions from leaves and tubers indicated the presence of flavonoids, sterols, and terpenoids [Table 3] [57].
Table 3
Bhandari et al. [58] have detected the presence of phenanthrene nudol (2, 7-dihydroxy-3, 4-dimethoxyphenanthrene) in the fresh tubers of E. nuda Lindl. In the subsequent study, another six phenanthrene derivatives were also isolated from the same plant tubers [Table 2] [24]. Among these derivatives, the therapeutic potential was largely attributed to 9, 10-dihydro-2, 5-dimethoxyphenanthrene-1, 7-diol. Kshirsagar et al. [14] validated the ethnobotanical rejuvenating claim of E. ochreata Lindl. by studying its antioxidant activity. Two radical scavenging molecules were isolated from dichloromethane and ethyl acetate extracts of tubers of E. ochreata Lindl. [Table 2].
RECENT PHARMACOLOGICAL STUDIES
Pharmacology is the science of drug action on biological systems. Pharmacological characters can provide a better understanding of active principles in plants and their mode of action. Pharmacological trials are needed to investigate the unexploited potential of plants.
Tubers of E. campestris Wall. are well known for its binding properties [23]. Ghule et al. [59] pointed out that large quantity of mucilage from tubers of this plant is used as binding agent in tablet formulation. This mucilage produces a sticky film of hydration on the surface of prepared tablets, which ultimately reduces drug release rate. Thick jelly of this mucilage is also reported to be highly nutritious [60]. Glycation inhibitory activity of salep (E. campestris Wall.) extract was assessed by trichloroacetic acid treatment. In this study, the formation of glycated products/AGEs was decreased at the highest concentration of salep, i.e., at 25 mg/ml [10]. Mucilage isolated from tubers of E. herbacea Lindl. has a potential as a suspending agent. It has a low rate of sedimentation, high viscosity, weak acidic pH and is easily re-dispersible. Thus, it can also be used as pharmaceutical adjuvant [61].
Methanol extract of tubers of E. epidendrea (JKoen) Schltr could significantly inhibit castor oil-induced diarrhea in rats, which was assessed by reduction in the frequency of defecation and the wetness of the fecal droppings compared to untreated control rats. The extract also significantly inhibited intestinal fluid accumulation (enteropooling). In addition, the extract appears to act on all parts of the intestine. Thus, it inhibited the propulsive movement of the intestinal contents in the charcoal meal treated model. These finding suggested that the methanol extract of the tubers of E. epidendrea (JKoen) Schltr may have an anti-diarrheal effect. This study validates the use of this plant as a non-specific anti-diarrheal agent in folk medicine [62].
The crude drug in the powder form prepared from tubers of E. nuda Lindl. has aphrodisiac potential [63]. Phenanthrene compounds, such as 1-phenanthrenecarboxylic acid, 1, 2, 3, 4, 4a, 9, 10, 10a-octahydro-1, 4a-dimethyl-, methyl ester, were isolated from Eulophia herbacea were found to have anticancer potential [64]. Pure compounds such as phenanthrene derivative, 9, 10-dihydro-2, 5-dimethoxyphenanthrene-1, 7-diol isolated from fresh tubers of E. nuda Lindl. showed good anti-proliferative activity against human breast cancer cell lines MCF-7 and MDA-MB-231 at concentration of 1000 μg/ml [42]. The same compound was isolated from tubers of E. ochreata Lindl. in the pure form and was analyzed for its anti-inflammatory activity using cell line and carrageenan-induced rat paw edema model. The compound inhibited the release of several pro-inflammatory mediators, particularly cytokines and could be a promising anti-inflammatory agent [65].
Similarly, anti-inflammatory and antioxidant activities were attributed to the methanolic extract of tubers of E. ochreata Lindl [25]. Moreover, different solvent extracts of this tuber were found to have potent antibacterial activity against Bacillus subtilis, Staphylococcus Aureus, and Escherichia coli [66]. Tubers are also reported to have promising antioxidant, antiglycation, and alpha-amylase inhibitory activity and may have potential in the treatment and management of the Type II diabetes [67]. Recently, we have studied seven Amarkand species for its phytochemical profile, polyphenolic content, and free radical scavenging activity and found that D. bulbifera and E. ochreata had the highest antioxidant potential [66,68]. Similarly, tubers of E. ochreata and bulbils of D. bulbifera have shown a high anti-fatigue potential among different Amarkand species [69]. Among different Eulophia species, E. ochreata has the highest score for biological activities [34].
PATENT
An Indian patent filed by Upadhyay et al. [70] focused on novel derivatives of phenanthrene, Eulophiol from Eulophia species, and its potential application in inhibition of immune stimulation involving Toll-like receptor ligands, especially TLR-4.
FUTURE PROSPECTIVES AND CONCLUSIONS
In India, traditional herbal medicines have a long history of practice and still are heavily practiced in rural and tribal populations. Around 2500 plants, out of 18,000 recorded plant species, are in medicinal use in the country [71]. Besides this, tribal communities of India have their own treasure of ethnomedicines based on their ecological and sociocultural background [72]. Most of the ethnomedicines have huge merits as potential medicines and functional foods [73]. However, single local name to different taxonomical species creates confusion about ethnomedical and nutritional efficacies. Therefore, there is need to identify exact and most bioactive ethnobotanical species, as well as validation of their ethnopharmacological and nutritional claims on the modern scientific ground.
Amarkand is a good example of having a strong background of regional ethnopharmacological and food uses. However, these species are not gaining expected regional and global attention due to the lack of scientific records about their biological and pharmacological activities. The ethnobotanical claims from the present review need to be subjected to pharmaco-chemical evaluation, which will help to discover true potential species of Amarkand. In addition, validation, standardization, and isolation of active ingredients from different Amarkand species are also important for their commercial exploitation.
Footnotes
Source of Support: Nil
Conflict of Interest: None declared.
REFERENCES
Articles from Journal of Intercultural Ethnopharmacology are provided here courtesy of SAGEYA
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