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Article

Ethnomedicinal Uses of Plant Resources in the Machhapuchchhre Rural Municipality of Kaski District, Nepal

by
Mahendra Adhikari
1,2,
Rashmi Thapa
2,
Ripu Mardhan Kunwar
3,
Hari Prasad Devkota
4 and
Prakash Poudel
1,*
1
Department of Pharmacy, Novel Academy, Purbanchal University, Pokhara 33700, Nepal
2
School of Health and Allied Sciences, Pokhara University, Pokhara 33700, Nepal
3
Department of Geosciences, Florida Atlantic University, 777 Glades Road, Boca Raton, FL 33431, USA
4
Graduate School of Pharmaceutical Sciences, Kumamoto University, 5-1 Oe-honmachi, Chuo ku, Kumamoto 862-0973, Japan
*
Author to whom correspondence should be addressed.
Medicines 2019, 6(2), 69; https://0-doi-org.brum.beds.ac.uk/10.3390/medicines6020069
Submission received: 31 May 2019 / Revised: 20 June 2019 / Accepted: 22 June 2019 / Published: 23 June 2019
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Abstract

:
Background: Medicinal plants are being used by the majority of the population throughout the world for their primary health care needs. The reliance is also prevalent in Nepal, aided by its ethnic and biological diversity. This study aimed to catalogue the ethnomedicinal knowledge of plants used by local people of Machhapuchchhre Rural Municipality of Kaski district. Methods: Data were collected between February 2017 and April 2018 from eight different villages of the Kaski district by using semi-structured interviews, guided field works, focus group discussions, and in-depth interviews. The reported traditional uses were supported by local assistants, cataloguing vernacular names and crosschecking with the earlier published and gray literature. Results: A total of 105 medicinal plants, belonging to 58 families and 99 genera were documented to treat 70 different diseases and ailments. The highest numbers of plants (37) were used for gastrointestinal disorders and the lowest (4) were used for female genital disorders. Commonly used parts were underground portions (28 species) followed by fruits and seeds (25 species each). The most preferred dosage form was juice, used for 50 ailments, and the oral route was the most favored route of administration (77 species). The medicinal properties of 22 plant species were found hitherto unreported in the district. Conclusions: The study area was found to be rich in plant resources and the people have ample knowledge on the use of medicinal plants. Due to a lack of proper documentation, conservation, and cultivation practices, valuable plant species are at risk of extinction. Thus, appropriate conservation measures and scientific assessment of plant-lore in the district is immediately required.

1. Introduction

Traditional medicine has played a crucial role in healthcare system for a long time [1]. The World Health Organization (WHO) defines traditional medicine as the “Sum total of the knowledge, skills, and practices based on the theories, beliefs, and experiences indigenous to different cultures, whether explicable or not, used in the maintenance of health as well as in the prevention, diagnosis, improvement or treatment or physical and mental illness” [2]. Thus, traditional medicine is strongly bonded to nature and dependent on natural resources and culture [3,4]. Historically, plant and animal derived products were the only source of nearly all medicinal preparations [5]. Among them, medicinal plants have been the major source of crude drugs used in different traditional medicine systems throughout the world [6,7,8]. The discovery of the medicinal properties of plants came from long self-experiments, which took centuries for establishment [9]. Due to the lack of appropriate strategies for screening, the use of plant-derived products has diminished in the past two decades [5]. It is estimated that only 10% of the world’s biodiversity has been assessed for their medicinal properties [10]. However, the utilization and determination of their therapeutic potential have not been prioritized to foster the quality of livelihood [11]. In recent years, the application of emerging technology advances in biological activity screening and chemical analysis have increased the interest of researchers towards naturally derived compounds. Lots of active constituents are to be investigated, from both terrestrial and marine sources [5]. In this scenario, the extensive survey of traditionally used plants in their natural habitats will definitely contribute to the identification of medicinally important plants.
In Nepal, it is estimated that only 17% of people live in urban areas and have access to modern medicine and the rest of the population still depend on the traditional system of medicine for their basic health care needs [12,13,14,15,16]. Traditional healers and elderly people learned folklore through apprenticeships to treat common health disorders based on their ethnomedicinal knowledge [11,17]. However, such knowledge still remains unexplored scientifically [11,13]. Medicinal plant resources have been equally used in the traditional scholarly medical systems, including Ayurveda, Tibetan and Unani, and in folk medicine [18]. Nepal occupies only 0.9% of the world’s land area, but possesses nearly 7% of the total medicinal herbs of the world [19,20]. Over 2000 plant species have been used frequently in rural, remote, and suburban areas of Nepal [21,22]. The uses are associated with the 125 diverse ethnic groups of the country [23]. Some ethnic societies consist of their own healing systems [7,11] and knowledge is transferred orally through generations [7]. However, the local healing system is affected due to changes in lifestyles as a result of globalization, increasing population, land-use change, and global warming. The collection and use of plants substantial for local livelihood, primary health care, and pharmacology [24] has now been severely threatened due to local people’s changing perceptions and their context-specific socioeconomic and cultural transformations [25]. Thus, traditional medicine in rural and remote areas of Nepal has experienced a substantial change in the recent decades [26] and it has declined in the absence of proper documentation.
There are a handful of ethnomedicinal studies carried out in Kaski district [27,28,29,30,31], while none is from the rural and remote villages of the Machhapuchchhre rural municipality. The present study, therefore, aims to investigate and document the plant-based indigenous knowledge of local people and explore their traditional uses. We hypothesized that the rural and remote areas of Nepal are rich in medicinal plants and the inhabitants possess unique knowledge of plant use. We also hypothesized that the richness of plants and the knowledge heritage of the area are positively associated.

2. Materials and Methods

2.1. Study Area

Kaski district lies between 83°40’ east to 84°12’ east longitude and 28°06’ north to 28°36’ north latitude and between 450 m and 8091 m elevation above sea level. It comprises a diverse topography (hills, midhills, mountains, Himalaya) and the following five common bio-climates: Sub-tropical, temperate, temperate cold, alpine, and tundra. The average rainfall is about 2500 mm per annum and the maximum temperature is 34 °C during the summer (April–July). It is estimated that 46.4% of the total area of the district is occupied by four types of forest, including subtropical broadleaf forest, temperate forest, subalpine forest, and alpine forest [32].

2.2. Sampling

The present study was conducted in purposively selected eight remote and rural villages (Koleli, Lwang, Ghalel, Lumre, Sakhu, Siu, Sidhing, and Idikhola) of the Machhapuchchhre rural municipality of the Kaski district (Figure 1). The study villages lie in the Annapurna Conservation Area (ACA), the largest protected area of Nepal [33]. Being located inside the conservation area, the collection of medicinal plants is restricted. The villages are populated with 21,868 inhabitants from 5512 households. The major ethnic groups are Brahmin, Gurung, Kami, Magar, and Chhettri. The communicable language is Nepali but the local people prefer to speak their own dialect, like Gurung and Tamang [32]. Rice, wheat, maize, millet, mustard, potato, etc. are the major crops, while, buffalo, goat, chicken, and cow are the major livestock. Economically, people mostly rely on agriculture and occasional trading of grains, livestock, and cash crops like tea, broom grass, cardamom, Himalayan bamboo shoot, fiddle head fern, and medicinal plants [34]. Although both modern and traditional system of medicines are practiced in this area, there is very limited access to modern allopathic medicine having only one primary health center and seven health posts [32]. Therefore, local people rely on the persistent traditional system of medicine for their basic health care needs.

2.3. Data Collection and Analysis

The year-long fieldwork was carried between February 2017 and April 2018. A total of 6 field visits were made in each study site. The four main data collection strategies such as Semi-structured interviews, guided field surveys, focus group discussions, and in-depth interviews were used following Martin, 1995 [35]. Ethical approval and prior oral consent was obtained from the Institutional Review Committee (IRC), Pokhara University, Nepal, ACA office and the study participants. During the study, a total of 49 traditional healers including Dhami and Jhankri (11), Pujari (4), Vaidhya (3), and a local herbalist (27) were reached out for study and only 45 allowed us to interview further. Four traditional healers refused to respond to our work because they lamented that the methods of treatment shared among others is disgraceful. A semi-structured questionnaire was designed for the interviews. Among the respondents, 85% were male and 89% were above 50 years of age and 72% were literate. Concerning the ethnicity of participants, Brahmins were found to be dominant (53 %), followed by Gurung (16%), Lama and Tamang (18%), and Dalit (13%).
In situ interviews were taken at the homes of the participants. Questionnaires were explained in Nepali and local dialects. Questions used during the interview sought information including the socio-demographic description of the participants, the local names of plants, plant habitats, parts used, dosage forms, the route of crude drug administration, and disease and ailments treated by the plants. Before conducting extensive interviews, questionnaires were pre-tested with five informants and modified as required. Similarity, dissimilarity, and new indication of plants were confirmed by comparing with previous relevant data [6,7,11,12,13,22,27,28,30,31,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71].
The ethnomedicinal uses of plants for various diseases and ailments were analyzed following the International Classification of Primary Care (ICPC) and compared with the literature. The comparison analysis helped to sort out the novelty of the findings. The data were entered in Microsoft Office Excel 2010 to analyze the information regarding plant families, habits, parts used, dosage forms, routes of administration, and the number of ailments treated. Data were expressed in terms of number and percentage. Voucher specimens collected during forest walks were identified using the literature, local vernacular names, and experts’ knowledge. Herbarium voucher specimens were cross-identified at the National Herbarium and Plant Laboratories (KATH), Godawari, Lalitpur, Nepal and housed in Novel Academy Herbarium, Novel Academy, Pokhara, Nepal.

3. Results

3.1. Medicinal Plant Diversity and Uses

Altogether, 105 medicinal plants belonging to 56 families and 99 genera were recorded. Out of 56 families, Asteraceae and Poaceae were the most dominant families, each with 9 species, followed by Fabaceae and Solanaceae (7 species each), Lamiaceae (5 species), Rutaceae (4 species), Amaranthaceae, Apiaceae, and Rosaceae (each with 3 species). The remaining 47 families possessed less than 3 plant species each. The scientific name, family name, local name, and folk uses of the plants are summarized in Table 1.

3.2. Use of Plants for Primary Health Care

It was found that local people used 105 medicinal plants to treat 70 different types of diseases and ailments (Table 1). These diseases and ailments were grouped into 13 different categories (Table 2) based on the International Classification of Primary Care (ICPC) i.e., digestive (37 species), skin (27 species), respiratory (19 species), musculoskeletal (12 species), circulatory (11 species), endocrine, metabolic, and nutritional (10 species), pregnancy, childbearing, family planning (5 species), eye (4 species), urinary (4 species), neurological (3 species), ear (2 species), female genital system (1 species), and general and unspecified (35 species). The information regarding the use of plant species for specific categories of diseases and ailments is listed in Table 2. Similarly, the biomedical and emic use reports are presented in Table 3.

3.3. Plant Parts Used and Their Growth Forms

Almost all parts of the plants were used to prepare medicine (leaf, root, rhizome, tuber, bulb, pseudobulb, corm, stem, bark, pith, flower, fruit, seed, bud, shoot, and whole plant) however, the most common plant parts used were underground parts including the root, rhizome, tuber, bulb, pseudobulb, and corm (used in 28 species), followed by fruit and seed (25 species), leaf (23 species), stem, bark, and pith (21 species), whole plant (17 species), bud and shoot (8 species), and flower (4 species). Additionally, the data of growth forms of plants indicate that most of the people used herbs (40%), followed by trees (24%), shrubs (18%), grasses (8%), climbers (5%), ferns (3%), orchids (1%), and stoloniferous (1%). Information regarding the number of plant species of each growth form is demonstrated in Figure 2.

3.4. Dosage Forms and Routes of Administration

The study revealed that medicinal plants were mostly used in the decoction, juice, powder, paste, gel, latex, and pickled forms. Less frequently used formulations were roasted, vapor, boiled, and in traditional dishes like Puwa (plant powder cooked with rice flour in butter). Few plant species were also taken in chewable form. It was found that the most frequently used dosage form was juice (50 ailments), followed by paste (33 ailments), decoction (31 ailments), chewable (11 ailments), pickled (8 ailments), latex (7 ailments), gel (2 ailments), and other (17 ailments). Similarly, the oral route was found to be the most preferable route (77 plants) followed by the topical route (37 plants), the inhalation route (2 plants), and the aural route (2 plants). None of the plant preparations were taken through the parenteral route. The diagrammatic representation of the dosage form and their routes of administration are displayed in Figure 3 and Figure 4, respectively.

4. Discussion

4.1. Plants and Usefulness

Records of higher numbers of useful plant species from the plant families Poaceae, Asteraceae, and Fabaceae were already manifested in Nepal [82]. Poaceae, Asteraceae, and Fabaceae are the families with a large number of genera and species. It is often hypothesized that there exists a positive correlation between plant use/knowledge and plant density, diversity, and the habitat diversity [54,55]. If the area is biodiverse, the use of plants is heterogeneous and if the area is less diverse (abundant), the use of plants is homogenous [83]. The higher number of ethnomedicinal plants was found to be associated with the area rich in biodiversity.
It was found that the people of the Kaski district are rich in ethnomedicinal knowledge and mostly rely on plant-based remedies for common health problems like gastrointestinal disorders, respiratory disorders, musculoskeletal disorders, cardiovascular disorders, etc. The number of plants used to treat gastrointestinal disorders was found to be the highest (Figure 5), which is convergent to other studies considered when reviewing this study [22,37,39,41,48,53]. Most of the gastrointestinal problems were due to irregular dietary habit, poor hygiene, and contaminated food. Respiratory, diarrheal, and infectious diseases are also prevalent in Nepal and the country’s sociological and topographical complexities burden health and sanitation [84]. Life in rural areas is further complicated [56] because of the effacement of traditional knowledge. Due to a lack of health education, people live with poor hygiene are vulnerable to many diseases. Benign health issues were frequently undermined because of a lack of health education. Some of the skin diseases like photo dermatitis [85], were caused due to prolonged exposure to sunlight during working hours. People suffered from fungal infections in the hands and feet, due to exposure to soil. Many people had musculoskeletal disorders due to greater physical stress, sprains, and fractures.

4.2. Perspective of People Towards Ethnomedicine

We found that the elderly people and traditional healers were rich in ethnomedicinal knowledge and were more interested to conserve plants than younger people. Villagers believed in traditional healers, such as Dhami, Jhankri, and Pujari, as God’s messengers and with super healing powers. They believe that plants become more medicinal when processed spiritually and materially. The traditional healers primarily used local medicinal plants to treat diseases. Besides local plants, they also used other important natural products available in other parts of the country. They generally exchanged their grains (such as rice, maize, etc.) with herbal ingredients brought by the transhumants from the Himalayan region.
Some of the elderly people claimed that they have not taken any allopathic medicine in their lifetime. However, they were less conscious of documentation and were unwilling to share their knowledge with others. They believed that if such secrets and their inherent knowledge is shared, the method does not work. They did not have any formal written documents about the use of medicinal plants. Most of the people in this area were not alarmed by the possible extinction of their indigenous knowledge. Few participants even told that traditional healers were remembered in their needs but not rewarded in return. Studies showed that younger people have little knowledge about plants and were inclined to allopathic medicines. However, they were interested in the documentation of their forefather’s knowledge. Existing ethnomedicinal knowledge of these indigenous inhabitants has only been transmitted through the verbal prescription. This inherent and practical based knowledge is going to collapse soon, due to the declining interest of youngsters towards the value of traditional medicine and lack of specific plans and policies from the local government.

4.3. Plant Parts Used and Their Growth Form

Among the choice of plant parts, underground portions were found to be frequently used. Our finding bears a resemblance with much previous literature on the use of plant parts [22,40,43,45,46,48,50,51,57,58,59]. Regarding the preference of underground parts, the root was used in most of the cases, as it generally contains a greater amount of active principles, in comparison with other parts [60]. Like roots, leaves are also vulnerable parts of the plant and have a greater role in the plant defense system and possess higher concentrations of bioactive secondary metabolites [49,61,86]. This finding may be beneficial for choosing these parts for bioprospecting and bioactivity determination. However, improper and massive collections of roots may lead to complete destruction and decline of the plant from nature [62]. Herbs were found to be dominant growth form over others, being frequently used in Himalayan folk medicine and other countries [7,13,22,30,39,40,43,48,50,51,52,53,56,58,59,63,64,65,66,86]. The reason may be that our study site is located at a higher altitude, where trees are less abundant and other forms of plants are common [22]. It also may be due to the greater ease of collection, storage, transportation, and extraction of active compounds from herbs than other forms [51]. Herbs also contain higher amounts of secondary metabolites for their life strategies [67]. Herbs are relatively easy to cultivate, so they can easily fulfill the demand if needed in higher amounts [68]. Hence, our finding highlighted that the selection and use of herbs depend on factors like their phytochemical profile, their natural habitat, and their accessibility, partially supporting ecological apparency hypothesis.

4.4. Dosage Forms and Route of Administration

In this area, the juice was used most frequently, followed by paste, decoction, chewable, pickled, latex, and gel. This information resembles the data published by other studies carried out in Nepal and other countries [7,51,53,59]. The preference of juice may be due to the ease of preparation and its effectiveness [58]. It may also be due to the presence of a greater amount of active principles extracted in juice than other dosage forms [66]. It was also found that most of the herbal plants were used with hot water. Some plants were used along with milk, ghee, and honey. For example, flour of O. sativa and powder of B. ciliata were prepared in a ghee base, both for oral and local application, for backache and inflammation.
Most of the dosage forms were freshly prepared when needed. For example, a fresh paste of G. hirta leaves and latex of M. pustulata was applied around boils for faster healing purposes. A single plant can be used to treat many disorders. Examples of such plants included A. bidentata, A. sativum, A. sessilis, B. ciliata, C. verutum, C. esculenta, D. diandra, J. curcas, L. cubeba, M. arboreus, M. jalapa, O. tenuiflorum, O. sativa, R. arboreum, R. ellipticus, R. nepalensis, S. melongena, T. latifolia, Z. armatum, and Z. officinale. Plants were also used in combined forms. People said that paste and juice of C. asiatica and C. dactylon are used together for typhoid. Similarly, people confirmed that the paste of three plants, A. sativum, Z. armatum, and Z. officinale, is useful for treating snakebites by the expulsion of venom from the snakebite. The increased effect of the plants used together may be due to their synergistic effect. This increased bioactivity of the combined plants opens the door for the identification of compounds with similar mechanism of action. While comparing the choice of routes of drug administration, the oral route was found to be the most preferable route in this study area. The data from other studies also showed that people favor the oral route for medications [22,41,48,51,56,59,61,64].

4.5. Comparison of the Reported Uses

We found that there are 47 plant species that have similar uses to treat 42 different ailments. A. bidentata was used in typhoid, tonsillitis, and toothache in this area. However, the same plant was found to be useful in the treatment of urinary disorder and indigestion in the Kavrepalanchok district [7] and asthma in Macchegaun, Kathmandu [36]. Another plant, A. calva, was used for dermatological disorders in the Rupandehi district of western Nepal [69]. However, this plant is used for gastrointestinal disorders like an intestinal worm, gastritis, and flatulence in the Kaski district. The rhizome of A. calamus was used in respiratory disorders like cough, chest pain, and asthma in our study area, which was also practiced in different regions of Nepal, like Rasuwa [13], Rupandehi [44,53], Humla [22], Macchegaun [36], Makawanpur [40], Gulmi [63], Dolpa [46], Nawalparasi [49], and Ghandruk [31]. The bulb of A. sativum fried in mustard oil was applied to treat earaches in Pakistan [70]. Similarly, its oil and fresh bulbs are used to cure skin rashes and blood pressure in the Kavrepalanchok district [7]. The decoction of this plant is taken for gastritis, flatulence, diarrhea, and dysentery in our study area and the paste of bulb is applied topically for snake bites. We found that people used the juice of A. vera for burns and boils. However, the same plant is used for diabetes in the Panchase village of the Kaski district [28], fever and cough in the Makawanpur district of Nepal [40], menstruation cramps, intestinal worms, and constipation in the Badgaun village of the Gulmi district [63], and rheumatism, constipation, and backache in Pakistan [56]. The importance of this plant for burns and boils in our area coincides with the accounts reported in Panchase, Kaski [28], Machhegaun, Kathmandu [36], and the Rudraprayag district of neighboring country India [66].
The inhabitants of Dekhatbuli of Kanchanpur districts used a paste of A. sessilis to treat wounds, venereal diseases, menstrual disorder, fever, and bloody dysentery [11]. The same plant has been reported for scabies in Rupandehi, Nepal [69] and bleeding, cuts, and wounds in Machhapuchchhre, Kaski, and Gulmi, Nepal [63]. Few previous studies showed leaves of B. pinnatum are beneficial for wounds, boils, skin burn, and are also applied to remove pus from the ear and vagina in Rupandehi, Nepal [69] and the plant is used to relieve ear pain in the Kaski district. Local people have been using the apical bud of C. verutum to treat sore throat and epistaxis like in Jajarkot district of Nepal [42,71]. Also this plant is used to treat urinary troubles in our study area which has same application in Karnali and Badagaun of the Gulmi district [63,71]. The practice of using the juice of the root of this plant for typhoid fever and diabetes is unique in our study. In the Mankawanpur district, the whole plant of D. bipinnata was used to correct thirst, fever, libido, asthma, and jaundice [40]. However, the paste of this plant is useful for tooth aches in our study area, which is justified by one study performed in Badagaun of the Gulmi district [63].
The root of A. bidentata contains phytosterols like sitosterol and sigma sterol, which have antibacterial activity, useful for toothaches [87]. The usefulness of this plant for typhoid and tonsillitis is also supported by the antibacterial activity of its ethanolic extract [88]. The plant A. calva is used for anthelmintic activity. This activity is justified by the lethality property of this extract against malarial and filarial vector [89]. A study showed that A. calamus possesses compounds like papaverine, with a dual inhibitor of the calcium channel and phosphodiesterase in the hexane fraction, and the anticholinergic compound rolipram, which has a phosphodiesterase-4 inhibitor in the ethyl acetate fraction [90]. In addition, one study showed that the anti-asthmatic activity of this plant is devoid of side effects [91]. A decoction of A. sativum is indigenously taken for gastrointestinal disorders like flatulence, diarrhea, dysentery, and gastritis in our study area. This medicinal property is justified by its reported anti H. pylori activity [92,93,94]. During the survey, we encountered the plant A. sessilis, which is beneficial for bleeding, cuts, and wounds. These properties can be verified by one study, where a chloroform extract of the leaves showed significant wound healing activity [95]. Though the antipyretic activity of this plant is not yet reported, our research findings will open a door for screening for its antipyretic property. The leaves extract of B. purpurea contain flavonoids and tannins, which exhibit antiulcer activity in rats. This result provides the effectiveness of this plant for the prevention and treatments of gastric ulcers [96]. Additionally, the antimicrobial protein isolated from the seeds of this plant justifies its beneficial effects in gastritis [97]. Folk use of stem and root juice of B. aristata for typhoid fever, jaundice, and diarrhea is supported by its reported antibacterial activity against Salmonella typhi and its hepatoprotective and anti-diarrheal activity, respectively [98,99,100,101,102,103]. One in vivo experiment showed that the same plant contains an excess amount of berberine, an alkaloid responsible for hepatoprotective effects by lowering hepatotoxicity, oxidative and nitrosamine stress, TNF-α, and iNOS levels. The inflammatory modulatory effect of this plant in the liver favors its effectiveness in the treatment of jaundice [104]. Experiments performed by Somania et al. [105] showed that an ethanolic extract of A. racemosus reduced blood glucose level in streptozotocin-induced diabetic rats. Hence, the reported use of this plant in the treatment of diabetes is justified.
C. asiatica is indigenously used to cure typhoid fever, cough, tonsillitis, and gastritis in this study area. The purport of indigenous uses of this plant was substantiated by its pharmacological activities (antibacterial, antiulcer, anti-allergic, anti-spasmodic, antitussive, antiviral, and anti-inflammatory activity) shown by compounds like apigenin, luteolin, α-pinene, and β-pinene [106]. Furthermore, the beneficial effect of C. asiatica is justified by its anti-ulcer activity shown in animal models [107]. The reported osteoporotic activity of the ethanolic extract and isolated compound coelogin from C. cristata justify its traditional use for backache, fractures, and sprains [108]. Its traditional dish, called Puwa, is made from the powder of its pseudobulb and is found to be very popular among the villagers for these musculoskeletal disorders. D. carota is indigenously used to treat jaundice and blindness in this study area. This indigenous use is proved by its antioxidant, hepatoprotective, and intraocular pressure reducing effect [109,110,111,112]. Similarly, F. vulgare has greater uses for musculoskeletal problems, like fractures and bone weakness. This medicinal potency is also validated by its osteogenesis inducing effect in human mesenchymal cells and its inhibitory effect on osteoclast differentiation and ovariectomy induced bone loss [113,114]. Traditional use of J. curcas in gingivitis, tonsillitis, and sore throat is proved by its positive in vitro antibacterial property against various susceptible bacteria [115,116]. The usefulness of J. regia for fungal infection is scientifically confirmed by its fungistatic effect in previous studies [117]. Trigonelline, a potent alkaloid found in M. jalapa, has a β cell protective effect with a good antioxidative potential [118]. This finding supports the clinical use of this plant for diabetes. Additionally, the effectiveness of this plant in the prevention and treatment of diabetes is supported by another hypoglycemic study performed by Zhou et al. [119] in streptozotocin-induced diabetic rats. Experiments performed by Sasa et al. [120] showed that the hypotensive effect of M. charantia is due to momordin, a saponin present in this plant. This compound has the potential to activate the peroxisome-proliferator activated-receptor (PPAR) delta gene in humans. The activation of this gene is responsible for the formation of high-density lipoproteins (HDL), which leads to a decrease in cardiovascular disorders like atherosclerosis and associated hypertension.
In our study area, M. alba is extensively used to reduce toothache. This anti-caries activity is proved by two experiments performed by Lokegaonkar et al. [121] and Islam et al. [122], wherein they found that both the plant extract and the isolated compound 1-deoxynojirimycin worked against Streptococcus mutans, a bacterium responsible for causing dental plaque and tooth decay. Similarly, the antibacterial property of this plant against oral pathogens is supported by the isolation of potent antibacterial flavonoids like cyclocommunol (Cy, 1), morusin (Mi, 3), kuwanon G, and kuwanon E (Ku, 4) [123,124]. Hence, the ethnomedicinal use of this plant for toothaches is also pharmacologically validated.
In the Kaski district, O. corniculata is used to correct gastritis. This beneficial effect is scientifically proved by its gastroprotective effect on experimentally induced gastric ulceration in Wistar rats [125]. P. guajava has been used to reduce blood pressure in our study area, which is justified by its bioactive compounds like guiajaverin and quercetin having anti-hypertensive property [126]. The ethnomedicinal value of R. ellipticus juice for cuts and wounds in many parts of our study area is favored by its wound healing effect in animal experiments [127]. We found that a decoction and cooked leaves of R. nepalensis is used for constipation and its paste is utilized for fungal infections. Literature also showed that the methanolic root extract of this plant has a purgative action in rats and also possesses antifungal activities [125,128]. S. officinarum juice contains polyphenolic flavonoids and possesses good antioxidant activity [129]. In addition, this plant is reported to have a hepatoprotective effect, which justifies its ethnomedicinal values for jaundice [130]. Similarly, the ethnomedicinal use of U. parviflora for jaundice is proved by its hepatoprotective potential in carbon tetrachloride challenged experimental rats [131]. W. fruticosa contains some antimicrobial terpenes like 2-methoxy-4-(2-propenyl) phenol, 2,6-octadien-1-ol,3,7-dimethyl-(E)-2,6-octadienal, 5-methyl-2-(1-methylethyl) phenol, 3,7 dimethylcyclohexanol, cyclohexanol, and 2-methylene-5-(1-methylethenyl), which may be responsible for the local remedies of this plant for diarrhea and dysentery [132]. An aqueous extract of the Z. armatum seed was reported to be active against worm infestation caused by Haemonchus contortus, which validates its application for intestinal worm in our study area [133]. Locally, flour of Z. mays is used to reduce blood glucose level. Previous studies proved that phenolic compounds isolated from Z. mays are effective in reducing complications associated with diabetes mellitus. Hence, the antidiabetic property of this plant in our study area is validated [134]. Z. officinale contains gingerol as an active ingredient, which possesses cholinergic M3 and 5-HT3 receptor blocking effects, thereby decreasing gastric emptying time and leading to the prevention of nausea and vomiting [135]. The presence of gingerol, an antiemetic compound, justifies the traditional use of this plant to for the relief of nausea and vomiting.
From the above comparisons of ethnomedicinal uses of medicinal plants with their previous reported uses, it is found that there is a strong variation in their uses within Nepal and other parts of the world. Additionally, the medicinal uses of some plants were newly discovered in our study area and were not encountered in other studies. Such heterogeneity of ethnomedicinal uses of these plants may be due to the predominance in the geographical location and the difference in vegetation. In addition, we found that some of the plants included in our study were already reported for their biological activities and phytochemical constituents. These reported activities and phytochemical constituents are similar to the claimed medicinal uses in this region, which reliability justifies the reported uses. Thus, the ethnomedicinal plant species, which are scientifically validated, are recommended for further studies for advanced pharmacological screening and drug development.

4.6. The Novelty of the Work and Future Prospects

Acharya and Acharya [27] recorded 18 medicinal plants, belonging to 17 families, for treating livestock diseases in Machhapuchchhre (formerly Sardikhola village), in the Kaski district. Similarly, another study, conducted by Bhattarai et al. [28] in Panchase, Kaski, reported 45 plant species belonging to 32 families that treat 34 different ailments. Ethnobotanical study conducted by Adhikari and Fisher [31] reported 54 local plant species from the Ghandruk village located inside ACA. Kunwar [30] also reported 66 plant species from Bhadaure Tamagi of the Kaski district. Among all these reported medicinal plants in this study area, 81 of them were reported in the book “Plants and People of Nepal” [136]. Surprisingly, from this survey we were able to document 83 plant species being used to treat 53 different diseases and ailments for the first time. Among them, 22 medicinal plants appeared to have new ethnomedicinal values. These plants include A. adenophora, A. bicolor, B. malabarica, C. cristata, D. macrocapnos, D. racemosus, D. belophylla, E. acuminata, G. hirta, H. lanceolata, M. pustulata, M. chisia, M. arboreus, N. cataria, P. calophylla, P. peruviana, S. fasciculata, S. annuum, S. pseudocapsicum, S. torvum, T. latifolia, and U. parviflora. Thus, we can claim that Machhapuchchhre Rural Municipality of the Kaski district is highly rich in medicinal plant resources. This unexplored ethnomedicinal knowledge pool of this area should be well documented, validated, and promoted for the socioeconomic and health benefits of the local people. Phytochemial profile and biological activities of newly encountered plants are yet unknown. This opens the door for researchers to perform phytochemical and pharmacological studies for the discovery of novel bioactive constituents.

5. Conclusions

The present study revealed that the Machhapuchchhre Rural Municipality of the Kaski district in Nepal is rich in plant resources that are traditionally used as medicines. The people of this area have been using a variety of plants for treating different diseases and ailments. They have abundant indigenous knowledge about plant collection, dosage form preparation, and their utilization. A total of 105 medicinal plants, belonging to 58 families and 99 genera, which treat 70 different diseases and ailments, were documented. The medicinal values of 22 different plant species were recorded for the first time in the district. The medicinal properties of the plants were justified by comparing them with relevant literature published from different parts of the world. The positive correlation between the traditional uses of the reported plants and their experimentally proven pharmacological activities was established.
To recapitulate, this study provides authentic data regarding the ethnomedicinal uses of the local flora of this rural region and will draw the attention of pharmacognosists, pharmacologists, phytochemists, and traditional healers for conducting further research to find therapeutically active natural products. We recommend that the claimed medicinal plants of this area should be protected using appropriate conservation measures and that a scientific assessment of the plant-lore in the district is urgently needed.

Author Contributions

M.A. carried out field survey, collected ethnomedicinal data, processed voucher specimen, and wrote first draft of manuscript. R.T. carried out field survey, analyzed data, and contributed in manuscript writing. H.P.D. and R.M.K. provided the technical support during the manuscript writing and guided the ethnobotanical and ethnomedicinal prospects of the research findings. P.P. designed whole study, supervised the project work, and finalized the manuscript and write up processes. All authors read and agreed for submission of this manuscript.

Funding

This research received no external funding.

Acknowledgments

Authors are very grateful to local people of Machhapuchchhre Rural Municipality, Kaski district, Nepal for their active participation and sharing their knowledge during field survey. We are also thankful to National Herbarium and Plant Laboratories, Lalitpur for the identification of plant specimens and Annapurna Conservation Area Project (ACAP), headquarter, Pokhara for giving the permission to conduct research in Annapurna Conservation Area.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Map of the study area (Machhapuchchhre Rural Municipality) in the Kaski district of Nepal.
Figure 1. Map of the study area (Machhapuchchhre Rural Municipality) in the Kaski district of Nepal.
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Figure 2. Growth form of the plant species used by the local people.
Figure 2. Growth form of the plant species used by the local people.
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Figure 3. Dosage forms of medication in the treatment of different diseases and ailments by the local people.
Figure 3. Dosage forms of medication in the treatment of different diseases and ailments by the local people.
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Figure 4. Routes of administration and the number of plants used by the local people.
Figure 4. Routes of administration and the number of plants used by the local people.
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Figure 5. Comparison of the medicinal value of plants in the present study with previous studies in the Kaski district.
Figure 5. Comparison of the medicinal value of plants in the present study with previous studies in the Kaski district.
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Table
Table 1. Enumeration of medicinal plant species used with their parts used, preparation form, local names, family names, mode of application and ailments treated.
Table 1. Enumeration of medicinal plant species used with their parts used, preparation form, local names, family names, mode of application and ailments treated.
S.N. Botanical Name
Voucher Number		Family Local NameHabitParts UsedPreparation Mode of Application Ailments Treated/ UsesPrevious Uses Reported References
1.Abelmoschus manihot var. pungens Hochr.
NAH-25		MalvaceaeKapasiHerbRootDecoction and juiceOralFever [72]
2.Achyranthes bidentata Bl.
NAH-75		AmaranthaceaeDatiwanHerbRootJuiceOral Typhoid, Tonsillitis, Urine retention[7,36,39,40,59]
StemPowderChewingToothache
3.Acmella calva (DC.) R.K. Jansen
NAH-50		AsteraceaeMarathi HerbFruitPickleOralIntestinal worm, Gastritis, Flatulence[69]
4.Acorus calamus L.
NAH-35		AcoraceaeBojhoHerbRhizomeChewable (rhizome)OralCough, Chest pain, Asthma[13,22,31,36,40,44,46,47,49,52,53,57,58,63,69,71,73]
5.Ageratina adenophora (Spreng.) R. M. King & H. Rob.
NAH-52		AsteraceaeBanmara Shrub LeafJuiceTopicalBleeding, Cuts and Wounds None
6.Aleuritopteris bicolor (Roxb.) Fraser-Jenk.
NAH-55		Pteridaceae DankernuFernWhole plantJuice Oral Diarrhea, Dysentery, GastritisNone
7.Allium sativum L.
NAH-112		AmaryllidaceaeLasun HerbBulbDecoction OralGastritis, Flatulence, Diarrhea, Dysentery[6,7,59,65,70]
BulbPasteTopicalSnakebite
8.Aloe vera (L.) Burm.f.
NAH-60		Xanthorrhoeaceae GheukumariHerbLeafGel Topical Burns, Boils[28,36,40,44,66,70]
9.Alternanthera sessilis (L.) R. Br. Ex DC.
NAH-133		AmaranthaceaeBhiringi JharHerbLeafJuiceTopical Bleeding [11,44,52,69]
LeafJuice and pasteTopical Cuts and Wounds
10.Anaphalis triplinervis (Sims) Sims ex C.B. Clarke
NAH-120		AsteraceaeBuki fulHerb Whole plantJuiceOralPost-partum hemorrhage[41,60,74,75]
11.Artemisia dubia L. ex B. D. Jacks.
NAH-110		AsteraceaeTite patiHerbLeafJuice and pasteTopicalScabies [11,36,46,50,57,74,76]
12.Asparagus racemosus Willd.
NAH-109		AsperagaceaeKurilo/ SatawariShrubWhole plantJuice and decoctionOralHypertension, Diabetes mellitus[13,27,30,31,36,39,40,41,44,47,48,49,53,57,59,63,71,77,78]
13.Azadirachta indica A. Juss
NAH-121		MeliaceaeNeemTreeBarkJuiceOralFever, Skin disorders [11,28,36,38,39,40,44,49,52,53,76,79]
14.Bauhinia malabarica Roxb.
NAH-67		FabaceaeTankiTreeBark and rootJuice and decoctionOralTyphoid, tonsillitisNone
15.Bauhinia purpurea L.
NAH-01		FabaceaeKoiraloTreeBark DecoctionOralGastritis [36,69]
16.Berberis aristata DC.
NAH-124		BerberidaceaeChutro ShrubBark and rootJuice OralTyphoid, Fever, Diarrhea, Jaundice[6,13,22,30,31,36,40,41,42,46,50,51,52,57,60,63,69,71,73,74,75,77,80]
17.Bergenia ciliata (Haw.) Sternb.
NAH-36		Saxifragaceae PakhanbedHerb RhizomePaste TopicalSprain, Fracture[7,13,22,36,37,40,42,50,51,52,56,57,59,60,63,66,70,73,74,75,76,77,78,79,80]
RhizomePowder along with rice flour in gheeOralBody ache, Backache
18.Betula alnoides Buch.-Ham.ex D. Don
NAH-22		Betulaceae Saur TreeBarkJuiceOralFever, Backache[7,63,73,78]
19.Bryophyllum pinnatum (Lam.) Oken
NAH-14		Crassulaceae Ajambari Herb FlowerJuiceAural Earache [69,79]
20.Centella asiatica (L.) Urb.
NAH-104		Apiaceae Ghod tapreHerbWhole plantPaste and juiceOralTyphoid, Cough, Tonsillitis, Gastritis[11,27,30,31,36,39,41,42,44,46,47,49,53,57,58,59,63,69,71,79]
21.Chenopodium album L.
NAH-12		Amaranthaceae Bethe Herb Leaf and fruitJuice and decoctionOralGastritis, Flatulence, Stomachache [22,36,38,53,57,65]
22.Cinnamomum tamala (Buch.-Ham.) T. Nees & Eberm
NAH-107		LauraceaeTejpat/ DalchiniTreeLeafDecoctionOralFever, Stomachache, Gastritis[31,36,39,40,47,50,57,58,63,73,80]
23.Cirsium verutum (D. Don) Spreng.
NAH-70		AsteraceaeThakailo/Thakali kandaHerbBud and rootChewable (bud and root)OralSore throat, Nose bleeding[30,42,45,57,63,76]
RootJuice OralTyphoid, Diabetes mellitus
24.Cissampelos pareira L.
NAH-71		MenispermacaeThulo Batul pateClimberWhole plantDecoctionOralPostpartum hemorrhage [11,28,36,41,44,47,52,57,59,69,74,80]
25.Citrus medica L.
NAH-11		Rutaceae BimiroTree Root and fruitJuiceOralIntestinal worms[80]
26.Citrus aurantiifolia (Christm.) Swingle
NAH-93		RutaceaeKagati Tree FruitJuice, juice with honeyOralThirst, Jaundice, Anorexia, Pimple, Skin disorders[7,39,58,59]
27.Citrus limon (L.) Osbeck
NAH-59		RutaceaeNibuwa Tree FruitJuiceOralFood poisoning, Blood purification[11,39,48,53,65,66,76]
28.Coelogyne cristata Lindl.
NAH-122		OrchidaceaeKadamOrchid PseudobulbPowder mixed with cooked rice flour in butter (Puwa)OralBackache, Fracture, Sprain None
29.Coffea Arabica L.
NAH-63		RubiaceaeKafi Shrub Fruit DecoctionOralLethargy, Headache[64]
30.Colocasia esculenta (L.) Schott
NAH-20		Araceae Karkalo Herb Stem LatexTopicalSnakebite [30,40,53]
Whole plant and rootDecoction and vegetable curryOralConstipation
31.Cucurbita pepo L.
NAH-26		Cucurbitaceae FarsiHerb FruitBoiledfruitOralJaundice, Gastritis [22,64,66]
32.Curcuma longa L.
NAH-111		ZingiberaceaeBesar/HaledoHerbRhizomeDecoctionOralFever, Sore throat, Sinusitis, Common cold[31,38,52,53,58,59,75,80]
33.Cuscuta reflexa Roxb.
NAH-92		ConvolvulaceaeAakase beliHerb Whole plantJuice OralJaundice [11,22,31,39,40,41,43,44,47,49,51,52,53,59,63]
34.Cyathea spinulosa Wall. ex Hook.
NAH-32		Cyatheaceae Chattre Fern Soft pithDecoction prepared in gheeOralFracture, Body ache[30]
35.Cynodon dactylon (L.) Pers.
NAH-74		PoaceaeDubo Grass Whole plantJuiceOralDiarrhea, Dysentery, Intestinal worm, Flatulence [6,11,39,44,45,49,51,53,57,58,63,70,73,80]
36.Dactylicapnos macrocapnos (Prain) Hutch.
NAH-16		Papaveraceae Bichkane JharClimber Whole plantSqueezed JuiceTopicalCorneal scar None
37.Daucus carota L.
NAH-72		ApiaceaeGajar Herb RhizomeChewable (rhizome)OralJaundice, Blindness[39,56,65]
38.Desmostachya bipinnata (L.) Stapf.
NAH-04		Poaceae KushGrassRootPaste Topical Toothache [40,63]
39.Dinetus racemosus (Roxb.) Buch.-Ham. ex Sweet
NAH-62		ConvolvulaceaeBadimalClimber RhizomeDecoctionOralPost-partum hemorrhageNone
40.Dioscorea belophylla (Prain) Voight ex Haines
NAH-07		Dioscoreaceae Ban TarulClimber TuberBoiled tuberOralConstipation None
41.Drepanostachyum falcatum (Nees) Keng f.
NAH-34		PoaceaeNigaloGrass Stem Dust outside the stemTopical Tinea pedis[7,30]
42.Drymaria diandra Blume
NAH-138		CaryophyllaceaeAbijalo HerbWhole plantPaste and juiceOralGastritis, Flatulence, Nausea, Vomiting[28,39,51,52,53,58,63,78,80]
Stem vaporInhalationSinusitis
43.Eclipta prostrata (L.) L.
NAH-61		AsteraceaeBhiringeHerbLeafJuiceTopicalBleeding, Wound[11,27,47,52,53,69,78]
44.Eleusine coracana (L.) Gaertn.
NAH-30		Poaceae KodoGrass FruitCooked flour Oral Cough [69]
45.Emilia sonchifolia (L.) DC. ex DC.
NAH-10		AsteraceaeSalha ko jharHerb Whole plantJuiceTopicalBleeding, Cuts and Wounds[11]
46.Engelhardia spicata Lesch. ex Blume
NAH-77		JuglandaceaeMauwa Tree BudPasteTopicalTinea pedis[28,39,58,80]
47.Erythrina stricta Roxb.
NAH-23		FabaceaeFadelo Tree BarkJuice and decoctionOralTyphoid, Sore throat[78]
48.Eurya acuminata DC.
NAH-118		PentaphylacaceaeJhyanu ShrubBudJuiceOralTyphoid, Tonsillitis, Sore throatNone
49.Ficus religiosa L.
NAH-56		MoraceaePipal TreeLeafJuiceTopical Cuts and Wounds [11,36,38,40,49,57,63,66,69]
50.Foeniculum vulgare Mill.
NAH-99		ApiaceaeSonpHerb FruitPowder mixed with cooked rice flour in butter (Puwa)OralBone weakness, Fracture[56,64,81]
51.Gonostegia hirta (Blume ex Hassk.) Miq.
NAH-08		Urticaceae AaternuHerb LeafPaste Topical BoilsNone
52.Hoya lanceolata Wall. ex D. Don
NAH-09		Asclepiadaceae ThirjoShrub Whole plantJuiceOralBody acheNone
53.Imperata cylindrica (L.) Raeusch.
NAH-45		PoaceaeSiru Grass RootJuiceOralTyphoid[22,38,57,63]
54.Jatropha curcas L.
NAH-38		Euphorbiaceae SajiwanTree Leaf and stem Juice and pasteGarglingGingivitis, Tonsillitis, Sore throat[11,36,44,47,57,63]
LatexTopicalFungal infection
55.Juglans regia L.
NAH-27		Juglandaceae Okhar TreePeels of fruitPasteTopical Tinea pedis, Fungal infection[13,31,37,46,47,58,60,63,71,74,75,77]
56.Linum usitatissimum L.
NAH-88		LinaceaeAatasi Herb SeedRoastOralLethargy, Intestinal worms[53]
57.Litsea cubeba (Lour.) Pers.
NAH-40		LauraceaeSiltimur TreeSeedDecoction and spice OralGastritis, Flatulence, Indigestion, Gastric troubles[31,40]
BarkPaste TopicalCuts and Wounds, Fracture
58.Lycopersicon esculentum Mill.
NAH-57		SolanaceaeGolveda Herb FruitJuiceOralBurns, Boils [39,65,80]
59.Lyonia ovalifolia (Wall.) Drude
NAH-94		EricaceaeThauneTree BudPasteTopicalScabies [36,39,41,58,59,63]
60.Macaranga pustulata King ex Hook.f.
NAH-19		Euphorbiaceae MallatoTree Stem LatexTopical BoilsNone
61.Maesa chisia Buch. Ham. ex. D. Don
NAH-02		PrimulaceaeBilauneShrub Fruit and RootJuice and pasteTopical Scabies None
62.Mahonia napaulensis DC.
NAH-142		BerberidaceaeBhutro/ Jamane mandroShrub StemLatex Topical Conjunctivitis [30,40,51,59,63]
63.Malvaviscus arboreus Cav.
NAH-47		Malvaceae Barhamase ful/khursani fulShrubRootJuice and decoctionOralFever None
64.Mirabilis jalapa L.
NAH-49		Nyctaginaceae Seto malatiShrub RootPasteTopical Inflammation[69]
Rhizome Chewable, Juice and decoctionOralDiabetes mellitus, Gastritis, Flatulence, Body ache
65.Mentha arvensis L.
NAH-85		LamiaceaeBabari Herb FlowerJuice and decoction OralThirst [36,49,63,80]
66.Mentha spicata L.
NAH-86		LamiaceaePudina Herb Whole plantJuice, Paste and pickleOralDiarrhea, Dysentery, Urine retention, Stomachache, indigestion[7,11,22,30,44,47,53,57,59,63,73,81]
67.Momordica charantia L.
NAH-28		CucurbitaceaeTite karelaHerb FruitJuice, decoction, and boiled fruitOralHypertension[11,52,66]
68.Morus alba L.
NAH-119		MoraceaeKiu kafalTree BarkJuice and pasteTopicalToothache[66,76,81]
69.Musa x paradisiaca L.
NAH-06		Musaceae KeraStoloniferous plant Corm Juice and decoctionOralThirst, Fever [11,31,53,80]
70.Myrica esculenta Buch.-Ham. ex D. Don
NAH-18		Myricaceae Ban KafalTree Bark Chewable (bark)OralDiabetes mellitus, Toothache [13,28,51,58,78,80]
71.Nepeta cataria L.
NAH-83		LamiaceaeCharpate Herb Leaf, whole plantJuiceTopicalCuts and Wounds, Bleeding None
72.Nephrolepsis cordifolia (L.) C. Presl
NAH-39		Nephrolepidaceae Pani amalaFernTuberJuice Oral Jaundice, Diabetes mellitus, Hematuria [11,12,30,36,78]
73.Nicotiana tobacum L.
NAH-80		SolanaceaeSurti/Kacho paatHerb LeafPaste and expressed juiceTopicalInfected wounds, Pediculosis [49,71,78]
74.Ocimum tenuiflorum L.
NAH-102		LamiaceaeTulsiShrub Leaf and whole plantDecoction and juiceOralHeart failure, Flu, cardiac stimulant[49,52,53,63,78]
75.Oryza sativa L.
NAH-48		Poaceae DhanGrassFruitDecoction Oral Inflammation[7]
Roasted fruitOral Cough
76.Oxalis corniculata L.
NAH-58		OxalidaceaeChari amiloHerb Whole plantDecoction and juiceOralFlatulence, Gastritis, Diarrhea, Dysentery, Fever, Common cold, Typhoid[11,36,44,45,48,49,57,58,59,63,64,71,80]
77.Periploca calophylla (Wight) Falc.
NAH-31		Apocynaceae Chautajor Shrub Leaf and stemPowder mixed with cooked rice flour in butter (Puwa)OralBody ache, Backache None
78.Physalis peruviana L.
NAH-13		Solanaceae IsamgolHerb FruitDecoctionOralFever, ThirstNone
79.Pogostemon benghalensis (Brum.f.) Kuntze
NAH-134		LamiaceaeRudiloShrub LeafJuiceOralSore throat, Typhoid[11,40,49,63,78]
80.Potentilla lineata Trev.
NAH-69		RosaceaeBajradanti HerbLeaf and root Juice TopicalToothache[58]
81.Prunus persica (L.) Batsch
NAH-100		RosaceaeAaruTree Bark and leafDecoctionOralTyphoid, Sore throat[11,49,58,65,66,70]
82.Psidium guajava L.
NAH-43		Myrtaceae Belauti/AambaTreeBud and barkJuice OralDiarrhea, Dysentery, Hypertension[7,11,31,39,45,49,58,59,63,66,78,80]
83.Rhododendron arboreum Sm.
NAH-108		EricaceaeLaali GuransTree Flower Chewable(flower petal) Oral Throat obstruction[22,30,31,36,37,39,40,42,47,51,59,63,65,73,74,78,80]
JuiceOral Diarrhea, Dysentery, Dry cough due to allergy
84.Rubus ellipticus Sm.
NAH-117		RosaceaeAinselu ShrubBud and rootsJuiceOralDiabetes mellitus[22,28,30,31,36,39,40,45,51,58,59,63,80]
Buds and leafJuiceTopical Cutsand Wounds
85.Rumex nepalensis Spreng.
NAH-115		PolygonacaeHalhaleHerbWhole plant Juice and pasteTopicalDislocated bone, Fracture, Sprain, Eye troubles [22,30,36,41,42,45,46,51,53,56,58,60,63,64,71,74,75,80]
LeafDecoction and cooked leaves OralConstipation
Leaf PasteTopicalFungal infection, Skin disorders
RootJuice OralDiarrhea
86.Saccharum officinarum L.
NAH-29		Poaceae UkhuGrass StemJuice OralJaundice [7]
87.Saurauia fasciculata Wall.
NAH-42		Actinidiaceae GobanTreeBark Juice Oral Thirst, Postpartum hemorrhage, FeverNone
88.Schima wallichii Choisy
NAH-78		TheaceaeChilaune Tree Bark Latex Topical Bleeding, Cuts and Wounds [31,36,49,63,78,80]
89.Solanum annuum C.V. Morton
NAH-51		Solanaceae KhursaniHerb FruitFried in oilTopicalSnakebite, ScabiesNone
90.Solanum melongena L.
NAH-46		SolanaceaeBhantaHerbUnripe fruitDecoctionOral Fever [7]
BudPaste TopicalBurns, Boils
91.Solanum pseudocapsicum L.
NAH-03		Solanaceae Tite beeShrub FruitJuiceTopicalHeadache, Toothache None
92.Solanum torvum Sw.
NAH-95		SolanaceaeKantakari (Thulo Bihi)Shrub FruitSmokeInhalation Toothache None
93.Stephania japonica (Thunb.) Miers
NAH-82		MenispermacaeChillo badulpateClimber LeafDecoction OralPostpartum hemorrhage [31]
94.Swertia chirayita L.
NAH-113		GentianaceaeChiraaitoHerb LeafJuice and decoctionOralFever, Headache, Common cold, Gastritis, Constipation[22,28,39,40,41,47,50,51,57,63,66,78]
95.Tectaria coadunata (J. Sm.) C. Chr.
NAH-41		Dryopteridaceae Kalo kuthurkeFernRoot Juice Oral Diarrhea, Dysentery[28]
96.Thysanolaena latifolia (Roxb. ex Hornem) Honda
NAH-21		PoaceaeAmrisoGrass RootPasteTopicalBreast engorgement None
DecoctionOralFever
97.Trigonella foenum-graceum L.
NAH-143		FabaceaeMethiHerb FruitSoup of roasted fruitOralCommon cold, Cough [22,39,52,56]
98.Urtica parviflora Roxb.
NAH-79		UrticaceaeSisnoShrub Leaf and BudJuice and decoction Oral Blindness, Jaundice, Urine retention None
99.Viburnum mullaha Buch.-Ham. ex D. Don
NAH-89		Adoxaceae MoloTree FruitJuiceOral Poisoning [30]
100.Viola canescens Wall.
NAH-24		Violaceae Aankhle jharHerb LeafPasteTopicalGout, Joint pain [58,70]
101.Woodfordia fruticosa (L.) Kurz
NAH-17		Lythraceae Dhairo Shrub FlowerJuiceOral Diarrhea, Dysentery[11,44,47,49,57,59,63,70,78,79]
102.Zanthoxylum armatum DC.
NAH-144		RutaceaeAakhe Timur ShrubFruitJuice and pasteTopicalSnakebite, Scabies[13,30,31,36,37,40,42,46,47,50,51,57,59,60,63,70,71,73,76,78,80]
Juice and decoction OralGastritis, Intestinal worms, Toothache, Poisoning
103.Zea mays L.
NAH-15		Poaceae MakaiGrassSeed FlourOral Diabetes mellitus [6,7,56,65,66]
104.Zingiber officinale Roscoe
NAH-64		ZingiberaceaeAduwa HerbRhizomePasteTopicalSnakebite[6,11,22,49,50,52,58,73]
Decoction OralVomiting, Stomachache, Common cold
105.Ziziphus mauritiana Lam.
NAH-44		Rhamnaceae Bayer TreeSeedPowderChewingChickenpox, Measles[6,11,30,47,49,53,57,63,65,66]
Table
Table 2. List of plant species used for specific categories of diseases and ailments.
Table 2. List of plant species used for specific categories of diseases and ailments.
Disease and Ailment CategoriesName of PlantsNo of Plants
MusculoskeletalB. ciliata, B. alnoides, C. cristata, C. spinulosa, F. vulgare, H. lanceolata, L. cubeba, M. jalapa, O. sativa, P. calophylla, R. nepalensis, V. canescens12
Digestive A. bidentata, A. calva, A. bicolor, A. sativum, B. purpurea, B. aristata, C. asiatica, C. album, C. tamala, C. medica, C. aurantifolia, C. esculenta, C. pepo, C. dactylon, D. carota, D. bipinnata, D. bulbophylla, D. diandra, J. curcas, L. usitatissimum, L. cubeba, M. jalapa, M. spicata, N. cordifolia, O. corniculata, P. guajava, R. arboreum, R. nepalensis, S. officinarum, S. pseudocapsicum, S. torvum, S. chirayita, T. coadunata, U. parviflora, W. fruticosa, Z. armatum, Z. officinale37
EyeD. carota, M. napaulensis, R. nepalensis, U. parviflora4
Ear B. pinnatum, M. arboreus2
CirculatoryA. adenophora, A. sessilis, A. racemosus, C. verutum, C. limon, E. prostrata, E. sonchifolia, M. charantia, N. cataria, O. tenuiflorum, P guagava11
Neurological C. arabica, S. pseudocapsicum, S. chirayita3
RespiratoryA. bidentata, A. calamus, B. malabarica, C. asiatica, C. verutum, C. longa, D. diandra, E. coracana, E. stricta, E. acuminata, J. curcas, O. sativa, O. corniculata, P. benghalensis, P. persica, R. arboreum, S. chirayita, T. foenum-graceum, Z. officinale19
Urinary SystemA. bidentata, M. spicata, N. cordifolia, U. parviflora4
Skin A. adenophora, A. vera, A. sessilis, A. dubia, A. indica, C. aurantifolia, D. falcatum, E. prostrata, E. sonchifolia, E. spicata, F. religiosa, G. hirta, J. curcas, J. regia, L. cubeba, L. esculentum, L. ovalifolia, M. pustulata, M. chisia, N. cataria, N. tobacum, R. ellipticus, R. nepalensis, S. wallichii, S. annuum, S. melongena, Z. armatum27
Endocrine, Metabolic and NutritionalA. racemosus, C. verutum, C. aurantifolia, M. jalapa, M. esculenta, N. cordifolia, P. peruviana, R. ellipticus, V. canescens, Z. mays10
Pregnancy, Childbearing, Family PlanningA. triplinervis, C. pareira, D. racemosus, S. fasciculata, S. japonica5
Female Genital System (including Breast)T. latifola1
General and UnspecifiedA. manihot, A. bidentata, A. calamus, A. sativum, A. indica, B. malabarica, B. aristata, B. alnoides, C. asiatica, C. tamala, C. verutum, C. limon, C. arabica, C. esculenta, C. longa, E. stricta, E. acuminata, I. cylindrica, L. usitatissimum, M. arboreus, M. x paradisiacal, O. tenuiflorum, O. corniculata, P. peruviana, P. benghalensis, P. persica, S. fasciculata, S. annuum, S. melongena, S. chirayita, T. latifola, V. mullaha, Z. armatum, Z. officinale, Z. mauritiana35
Table
Table 3. Categories of diseases and ailments based on body system, along with their biomedical and emic use reports.
Table 3. Categories of diseases and ailments based on body system, along with their biomedical and emic use reports.
Ailments CategoriesBiomedical TermsLocal Terms (Emic Use Reports)
General and UnspecifiedChest painChati dukheko
ChickenpoxTheula
FeverJworo aayeko
FluBela Bela dekhaparne rughakoki, joro
Food poisoningKhana ma bish pareko
Lethargy Aalasya vayeko, alchi lageko
MeaslesDadura
SnakebiteSarpa le tokeko
TyphoidKukhat pareko
DigestiveAnorexiaKhana ruchi nahune/ bhok nalagne/ aman hune
ConstipationKabjiyet hune/ pet safa nahune/ disha garda garo hune
DiarrheaPakhala lageko/ cherpate chaleko/ pani jasto patalo disha aaune
DysenteryAaun pareko
EmesisBanta garaune
FlatulencePet ma hawa variyeko/ bayu gola le pet dukhne
Gastric troublesPet ko gadbadi/ pet dhadiyeko
GastritisGastric vayeko/ mukh ma amilo pani aaune/ chati polne
GingivitisGija sunniyeko
IndigestionApach/ khana apach hune
Intestinal worms infestation Pet ma juka pareko
JaundicePahele rog/ jaundice vayeko
NauseaBanta hola jasto hune/wakwak lagne
StomachachePet dukheko
Throat obstructionGhanti ma adkeko, ghanti ma kei kura aljeko
ToothacheDant dukheko/ dant kirale khayeko
VomitingBanta hune/ ulti hune
EyeBlindnessAandho hune
ConjunctivitisAankha pakne rog
Corneal scarAankha ma phulo parne
Eye troublesAankha ka samasyaharu
EarEaracheKan dukheko
CirculatoryBleeding Dherai ragat bagne
Blood purificationRagat safa garne
Heart failureMutu fail hune/ hridayaghat
HypertensionUchha raktachap, blood pressure badeko
MusculoskeletalBackacheDhad dhukeko/ kammar dukheko
BodyacheJyan dukheko
Bone weaknessHaddi ko kamjori
Dislocated boneHaddi bhachiyera thau sareko
FractureHaddi futeko/bhachiyeko
InflammationSunniyeko
Joint painJorni ko dukhai
SprainMarkeko
NeurologicalHeadacheTauko dukheko
RespiratoryAsthmaDam vayeko/ sas ferna garo hune rog
Common coldRugha khoki lagne
CoughKhoki lageko/ kaso lageko
Dry cough due to allergyAllergy le garda hune sukka khoki
Nose bleedingNaak bata ragat bagne
SinusitisPinas bhayeko
Sore throatGhanti basne
TonsillitisGhanti dukheko
SkinBoilsPilo
BurnsPoleko/ dadeko
CutsKateko
Fungal infectionsSarir ma daj aaune
Infected woundsGhau pakeko
PediculosisSarirma jumra parne
PimpleDandifor aayeko
ScabiesLuto/ suke luto aayeko
Skin disordersChala ko samasya/ chala ko rog/ charma rog
Tinea pedis/ ring wormKash ma daj aayeko
WoundsGhau lageko
Endocrine, Metabolic and NutritionalDiabetes mellitusChini rog, Madhumeha
GoutBath rog
ThirstKharo hune
Urinary SystemHematuriaPisab ma ragat dekhine
Urine retentionPisab banda vayeko
Pregnancy, Childbearing, Family PlanningPost-partum hemorrhageSutkeri veyepachi dherai ragat bagne/ khanaro hune
Female Genital System (including Breast)Breast engorgementStan ma thunelo aayeko

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Adhikari, M.; Thapa, R.; Kunwar, R.M.; Devkota, H.P.; Poudel, P. Ethnomedicinal Uses of Plant Resources in the Machhapuchchhre Rural Municipality of Kaski District, Nepal. Medicines 2019, 6, 69. https://0-doi-org.brum.beds.ac.uk/10.3390/medicines6020069

AMA Style

Adhikari M, Thapa R, Kunwar RM, Devkota HP, Poudel P. Ethnomedicinal Uses of Plant Resources in the Machhapuchchhre Rural Municipality of Kaski District, Nepal. Medicines. 2019; 6(2):69. https://0-doi-org.brum.beds.ac.uk/10.3390/medicines6020069

Chicago/Turabian Style

Adhikari, Mahendra, Rashmi Thapa, Ripu Mardhan Kunwar, Hari Prasad Devkota, and Prakash Poudel. 2019. "Ethnomedicinal Uses of Plant Resources in the Machhapuchchhre Rural Municipality of Kaski District, Nepal" Medicines 6, no. 2: 69. https://0-doi-org.brum.beds.ac.uk/10.3390/medicines6020069

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